real life safety - one star is all you need
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ÂTRANSCRIPT
ALL-ENCOMPASSING SAFETY CONCEPT
INTELLIGENT DRIVE AND AUTONOMOUS DRIVING
THE ROAD TO ACCIDENT FREE TRAFFIC
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Daimler Communications
70546 Stuttgart, Germany
www.daimler.com – www.daimler.mobi
Mercedes-Benz – A Daimler Brand
REAL LIFE SAFETY
One Star Is All You Need
32
44 BASIC FUNCTIONS Precautionary safety measures
48 NEW FUNCTIONS Focus on following traffic
50 INTERVIEW Prof Rodolfo Schöneburg, Michael Fehring, Karl-Heinz Baumann, the original brains behind PRE-SAFE®
56 DEMONSTRATOR Realistic impression
58 DID YOU KNOW Facts, figures and curiosities
62 CHILD SEATS Small passengers, great need for protection
66 AIRBAGS Blow up
76 SEAT BELT Number one lifesaver
82 DID YOU KNOW Facts, figures and curiosities
PRE-SAFE® 42 RESTRAINT SYSTEMS 60
CONTENTS
The integral concept of
Mercedes-Benz safety
development is to avoid
accidents and to mitigate
consequences. The company
calls this Real Life Safety.
This book gives insight
into the broad range of safety
innovations, test procedures
and development tools of
Mercedes-Benz – yesterday,
today and tomorrow.
10 NETWORKED SENSOR SYSTEM 360° all-round vision
16 INTERVIEW Dr Michael Hafner, Head of driver assistance systems
18 DEVELOPMENT TOOLS State-of-the-art methodology
28 ACCIDENT RESEARCH Reality is the yardstick
34 BÉLA BARÉNYI The father of safety
36 EXPERIMENTAL SAFETY VEHICLES Experience the future
40 DID YOU KNOW Facts, figures and curiosities
BASICS 8
REAL LIFE SAFETY
54
86 ABS/ESP® Controlled vehicle dynamics
96 BAS PLUS Recognising danger, supporting the driver
100 LANE KEEPING AND BLIND SPOT On the right track
104 COLLISION PREVENTION ASSIST Prevention of rear-end collisions
106 TRAFFIC SIGN RECOGNITION Orientation in the traffic sign jungle
108 PARKING Automatic entry into parking spaces
110 DRIVING ACADEMY Driver training for every level
114 DID YOU KNOW Facts, figures and curiosities
118 NIGHT VIEW ASSIST Better vision when driving at night
122 HEAD-UP DISPLAY Information in the driver’s field of vision
124 HEADLAMPS Intelligent Light Systems and lighting history
132 RESEARCH Customer Research Center
136 ATTENTION ASSIST Preventing fatigue
138 STOP&GO PILOT More comfort in tailbacks
142 MAGIC BODY CONTROL The world’s first suspension system with “eyes”
146 DID YOU KNOW Facts, figures and curiosities
150 TEST PROCEDURES Organised destruction
164 DUMMIES They suffer for us
170 POST-SAFE Rapid rescue
174 DID YOU KNOW Facts, figures and curiosities
178 CAR-TO-X COMMUNICATION Vehicles in a dialogue
182 AUTONOMOUS DRIVING The self-driving car
186 INTERVIEW Prof Ralf G. Herrtwich, Daimler advance development
188 DID YOU KNOW Facts, figures and curiosities
ASSISTANTS 84 DRIVER FITNESS 116 CRASH TESTING 148 OUTLOOK 176
6 EDITORIAL
190 KEY MILESTONES
195 IMPRINT
CONTENTSREAL LIFE SAFETY
6 7
active and passive safety technology has worked
together in synergy.
And more than ten years after the introduction
of PRE-SAFE®, we are now going a step further:
intelligent assistance systems analyse complex
situations and use improved environmental sensor
systems to recognise potentially dangerous traffic
situations even more efficiently. This can prevent
accidents, or considerably mitigate their possible
consequences. We call the intelligent networking
of sensors and systems for a new dimension in
motoring “Mercedes-Benz Intelligent Drive”. With
Intelligent Drive we are systematically following
our path towards accident-free driving. Because
for us at Mercedes-Benz, Intelligent Drive is also
the entry-point into the era of autonomous driving.
In addition, the intelligent networking of vehicles
with each other, and with the infrastructure,
has the potential to improve general traffic
safety even further.
Our intention with this magazine is to
give you an overview of the safety philosophy
at Mercedes-Benz – from the early basics to
constantly improved development tools, and
right up to trailblazing innovations in all
safety-related areas. I wish you an
enjoyable read.
Thomas Weber
MERCEDES-BENZ INTELLIGENT DRIVE ONE STAR IS ALL YOU NEED
Safety has always been a core competence of
Mercedes-Benz. This is witnessed by the
numerous technical innovations with which
we have continued to set standards in both Active
and Passive Safety since the invention of the auto-
mobile in 1886. At the same time Daimler AG is
meeting a higher responsibility. We see safety as
a comprehensive system that serves all.
Every car driver knows and uses the milestones
achieved by this ongoing effort: from the rigid
passenger cell (patented in 1951 and first intro-
duced into series production in the Mercedes-Benz
W 111 series in 1959) to ABS (introduced in the
W 116-series S-Class in 1978), the airbag (intro-
duced in the W 126-series S-Class in 1981, initially
for the driver) and the Electronic Stability Pro-
gramme ESP® (presented in a C 140-series S-Class
Coupé in 1995). ABS and ESP® today are the stand-
ard for all passenger cars registered in Europe.
The innovative solutions in each of the brand’s
new models show that for the future too, vehicle
safety is one of the most important concerns
for Mercedes-Benz engineers. And this applies
right across all vehicle classes: examples include
COLLISION PREVENTION ASSIST, which was
introduced as standard with the new compact-class
DEAR READERS,generation in 2011, or the Stop&Go Pilot first
offered in the S- and E-Class and now also
available for the new C-Class.
In 1966 our safety experts Béla Barényi and
Hans Scherenberg formulated the distinction
between Active and Passive Safety. Thanks to the
integral safety concept of Mercedes-Benz, both
areas now interlock seamlessly. Because in 2002 a
new era in vehicle safety dawned in the Mercedes-
Benz S-Class with PRE-SAFE®: for the first time
technology was able to recognise an impending
collision in advance, and prepare both vehicle
and occupants for a possible impact. Since then,
Prof Dr Thomas Weber is a Member of
the Board of Management of Daimler AG
and responsible for Group Research and
Mercedes-Benz Cars Development
Every drive in a Mercedes-Benz
is “Intelligent Drive” in numerous
situations on the road. An overview
of the different systems:
1 COLLISION PREVENTION ASSIST (PLUS)
2 DISTRONIC PLUS with Steering Assist and Stop&Go Pilot
3 BAS PLUS with Cross-Traffic Assist
4 PRE-SAFE® Brake with Pedestrian Detection
5 PRE-SAFE® PLUS
6 PRE-SAFE®
7 Active Lane Keeping Assist
8 Active Blind Spot Assist
9 Adaptive Highbeam Assist Plus
10 Night View Assist Plus
11 Active Parking Assist with PARKTRONIC
12 360° Camera
13 Traffic Sign Assist
14 ATTENTION ASSIST
15 Intelligent Light System
16 LED Headlamps
17 Crosswind Assist
18 ESP®/ABS/BAS
19 4MATIC
98 98
INTELLIGENT DRIVE IS
BASED ON SENSORS THAT MONI-
TOR THE SURROUNDINGS, ADVANCED
TOOLS TO SUPPORT DEVELOPMENT AND ACCIDENT RESEARCH
FOR ANALYSING ACTUAL EVENTS. MEAN-
WHILE, RESEARCH VEHI-CLES PROVIDE A GLIMPSE INTO THE
FUTURE.
BASI
CS
ALL-ROUND VIEWThe eyes of a CHAMELEON move independently
of each other. This gives a field of vision of
342 degrees and a blind spot of just 18 degrees.
These creatures can see sharply – and in
colour – up to one kilometre away.
Phot
o: P
er-G
unna
r O
stby
/Get
ty Im
ages
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NETWORKED SENSOR SYSTEM
360° ALL-ROUND VISION
THANKS TO TWO “CAMERA EYES”, THE NEW STEREO CAMERA HAS A THREE-DIMENSIONAL
VIEW OF THE AREA UP TO ABOUT 50 METRES IN FRONT OF THE VEHICLE AND, IN THE FORM OF
“6D VISION”, CAN DETECT THE POSITION AND MOVEMENT OF OBJECTS. THE SYSTEM MONITORS
THE SURROUNDINGS AHEAD OF THE VEHICLE OVER A RANGE OF UP TO 500 METRES. THIS
DATA IS COMBINED WITH DATA FROM RADAR AND ULTRASONIC SENSORS.
NETWOR
360° ALL-ROUN
BASICS SENSOR FUSION
Multi Mode Radar80 m range / opening angle 16° and 30 m range / opening angle 80°
Stereo Multi-Purpose Camera500 m range, with 3D capability over a range of 50 m / opening angle 45°
Long Range Radar With Mid-Range Scan200 m range / opening angle 18° 60 m range / opening angle 60°
Short Range Radar0.2 m - 30 m range / opening angle 80°
Near / Far Infrared Camera160 m range / opening angle 20°
Ultrasonic Sensors1.2 m / 4.5 m range
RADAR, STEREO CAMERA AND ULTRA-SONIC SYSTEMS More sensors – more protection
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BASICS SENSOR FUSION
EYES AND EARS Sensor system in detail
A wide range of sensors give the latest vehicles from Mercedes-Benz eyes and ears. In the S-Class, examples include:RADAR
2 x short-range radars at the front (30 m, 80°)1 x long-range radar at the front (200 m, 18°) with medium-range detection (60 m, 60°)2 x short-range radars on the sides at the rear (30 m, 80°)1 x multi-mode radar at the rear (30 m, 80° and 80 m, 16°)
STEREOCAMERA Stereo Multi-Purpose Camera (SMPC) located behind the windscreen in the vicinity of the rear-view mirror (range 500 m, incl. 3D capability for approx. 50 m, 45°)
12 ULTRASONIC SENSORS 4 each at the front/rear + 2 each on the left/right in the front and rear bumpers)
4 CAMERAS AS PART OF A 360° CAMERA SYSTEM 1 each at the front in the radiator grille/behind in the handle recess/bottom of the exterior mirror housings, vertical angle of approx. 130°, horizontal > 180°, resolution 1 MP (1280-800 pixels)
crossways ahead and also pedestrians, and calculating their path. The camera’s two “eyes” provide it with a three-dimensional view of the area up to approx. 50 metres in front of the
Radar sensors: the transmitting
and receiving modules for the various
radar sensors are concealed in the
bumpers and radiator grille
EYES AND EARS Sensor system in detail
A wide range of sensors give the latest vehicles from Mercedes-Benz eyes and ears. In the S-Class, examples include:
Highly sophisticated sensors and accord-ingly networked
algorithms provide the foun-dation for innovative new
functions. As part of “sensor fusion”, DISTRONIC PLUS with Steering Assist, BAS PLUS and PRE-SAFE ® Brake all employ the same stereo camera and multi-stage ra-dar sensors.
Mercedes-Benz is making a major leap forward with the introduction of the Stereo Multi-Purpose Cam-era (SMPC), or stereo camera for short. Just like the Multi-Purpose Camera
(MPC) fitted previously, it is positioned behind the windscreen in the vicinity of the rear-view mirror. It has an aperture angle of 45° and is capable of spatially detecting objects moving
“Mercedes-Benz Intelligent
Drive”: the helpers in the
background make common
use of the sensors. Vehicles
equipped with Night View
Assist Plus additionally have
a Short Range Infrared Cam-
era in the windshield and a
Long Range Infrared Camera
in the front grille
INTELLIGENT DRIVE Sensors enhance capabilities of assist systems
Stereo camera: the car’s eyes
are fitted as high as possible in the
vicinity of the rear-view mirror
Short Range Radar
Long Range Radar
Multi Mode Radar
Ultrasonic Sensors
Steering Angle Sensor
Rain Sensor
RS
US
C
US
US US
US
US
US
US
US
US
US
US
US SS
US
SS
RS
SR
SR
SR
SR
LR
MR
SR
LR
MR
C
CC
SC
Stereo Multi-Purpose Camera
Camera
SC
C
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BASICS SENSOR FUSION
MAKING THE “SEEING” CAR A REALITY Eight years of development
The first prototypes featuring technology to detect crossing traffic emerged back in 2005. This was followed by eight years of intensive development activities in the lab, on test sites and on the road. Series production commenced with the launches of the E-Class and S-Class in 2013. From March, the new assistance sys-tems will become available in the executive segment for the first time, with the new C-Class. Michael Schumacher himself shared his wealth of experience by providing input on the final calibration drives.
2005 test drive: prototype for detecting crossing traffic in a Mercedes-Benz E-Class (model series 211) with stereo camera above the screen
Lab testing: hardware-in-the-loop test station for component testing
vehicle. This system is able to monitor the overall situa-tion ahead over a range of up to 500 metres. In this way, the new camera supplies data that is processed fur-ther by various systems.
Based on the location (3D) of a detected object, the ste-reo camera also provides additional information for active safety systems: it is possible to determine a direction of movement for
every single pixel on the horizontal, vertical and lon-gitudinal axis. It is clear from this six-dimensional
(6D) recognition whether the object is moving and where to. When combined with object classification based on
common features, this stereo camera technique enhances confidence that full brake application by the vehicle is possible in the event that the driver fails to respond to an object’s presence. Thanks to such system accuracy, the stereo camera is able to cal-culate the location of impact for a potential collision and use the remaining time available as effectively as possible, in order to take
precautions. In the process, the stereo camera provides support across the entire speed range.
Because the stereo cam-era system may also deter-mine potential evasive manoeuvres for the vehicle within its field of vision, it is even possible for a colli-sion warning or automatic braking to be initiated soon-er if no means of evasion is available. This can be benefi-
cial. Gaining a few hundred milliseconds for full brake application might make the difference between light and much more serious injuries.
Intelligent algorithms evaluate this information in order to detect and carry out spatial classification of vehi-cles that are driving ahead, oncoming or crossing, as well as pedestrians and a variety of traffic signs and road markings within a large field of vision.
Whereas the stereo cam-era’s lenses act as the car’s eyes, the radar sensors are its ears, so to speak, and provide additional data. The
system of radar sensors com-prises two short-range radar sensors in the front bumper with a range of 30 m and a beam angle of 80°, which are complemented by a long-range radar (200 m, 18°) including medium-range detection (60 m, 60°). The data from the camera and radars is amalgamated in a control unit in order to pro-vide the system-specific data for the various functions.
An extensive system of additional sensors is able to keep an eye on the current driving state and the driv-er’s reactions. If the sensors detect a hazardous situation, they are able to feed the al-gorithms for all manner of assistance systems with data in order to provide just the right support for the specific situation. ■
RADAR SENSORS ACT AS THE CAR’S EARS
CAMERA CAPTURES MOVEMENT OF OBJECTS IN SPACE
1716
BASICS INTERVIEW
Since the beginning of this year Dr Michael Hafner (43) heads the unit for the Development of Driver Assistance Systems and Active Safety. Holding a doctorate in engineering, his previous
areas of activity included the associated field of brake control and suspension systems, control technology and neuronal networks.
DR MICHAEL HAFNER
“ONE STEP AHEAD”A CONVERSATION WITH THE HEAD OF DRIVER ASSISTANCE SYSTEMS
It was in 2013 that Mercedes-Benz achieved the last quantum leap in the field of assistance systems, thanks to improved sensors and sensor fusion. Only a few years ago, the idea that a car could have all-round vision would have been dismissed as utopian. Does this mean that assistance systems have reached their technical limits, or where do you still see potential for the future?Dr Hafner: It is quite right that the introduction of the stereo camera and fusion of the data from various sensors were decisive steps on which we spent a good eight years of development time – and which now give us a clear advantage over our competitors. Our task for the future is to refine the sensor signals and algo-rithms used by the assis-tance systems to support the driver. We also want to ensure that these systems are available on the broadest possible basis across all our model series.
You have already done this successfully with the introduction of COLLISION PREVENTION ASSIST as standard in the B-Class three years ago. Dr Hafner: Yes, that was an important breakthrough. And with COLLISION
PREVENTION ASSIST PLUS we are taking another major step, as we can now initiate autonomous braking in cer-tain situations if the driver fails to react to the warning when an accident threatens. We are also proud of the fact that it has been less than a year before the assistance systems from the S- and E-Class have also become available in the C-Class.
Are there already accident statistics available that confirm the extra safety provided by the radar-based collision warning system COLLISION PREVENTION ASSIST in the A-, B- and CLA-Class?Dr Hafner: Since the intro-duction of autonomous emer-gency braking functions with DISTRONIC PLUS, we know that around one third fewer rear-end collisions have been recorded and that the impact severity was reduced in just under two thirds of cases. Incidentally, there are also fewer cases of vehicles equipped with this being impacted from the rear, as timely braking allows more reaction time for following traffic.
The more numerous and complex assistance sys-tems become, the less car drivers understand their functions and operating
principles in detail. Do we need more explanatory symbols, for example the coffee cup in the case of ATTENTION ASSIST?Dr Hafner: Not necessarily. Very good assistance sys-tems normally work in the background, or support drivers unobtrusively with-out taking control. What is important is that the assistants provide support when they are needed. We show this with symbols or small graphics when they do, so that the driver is able to identify the assistance system that is intervening. Customers wishing to learn about their functions in more detail can do so by referring to the owner’s manual, which f.i. in the case of the S-Class is also available on-screen in digital form. And of course maga-zines such as this also help to explain the systems.
With SIM-City, Mercedes-Benz has a dedicated test site for the testing of assis-tance systems. Does this sometimes lead to crashes, or are these completely prevented by tools such as the driving robot, the bal-loon car that simulates rear-end collisions or the radar-reflecting padding for lateral proximity?Dr Hafner: At Mercedes-Benz we not only attach the greatest importance to safe-ty in our vehicles, but also
during their development. We really do use driving robots to perform dangerous manoeuvres, or we resort to our driving simulator, one of the most modern in the world.
What part do suppliers play during the development of assistance systems? How can the advantage over competitors be sustained?Dr Hafner: Mercedes-Benz works together closely and confidentially with suppli-ers, especially where the hardware is concerned. How-ever we keep the key know-how with respect to data fusion, the functional as-pects of our systems and their integration into the vehicle in-house. We are therefore confident that we can also remain at least one step ahead of our com-petitors in the future.
Which assistance system do you appreciate and use most yourself?Dr Hafner: Personally I find the new DISTRONIC PLUS with Steering Assist to be a very convenient help, espe-cially in tailbacks thanks to the Stop&Go Pilot. I also like the fact that the PRE-SAFE ® braking functions are al-ways on standby in the background, although they will hopefully never be needed. ■
The eyes of his cars: Dr Hafner and the stereoscopic
camera, shown here for
demonstration above the same
item installed in the car
1918
BASICS DEVELOPMENT TOOLS
STATE-OF-THE-ART METHODOLOGY
INNOVATIVE TOOLSAS CARL BENZ FORESAW IN 1925, “THE LOVE OF INVENTION NEVER CEASES”.
THE COMPANY’S FOUNDER WOULD ALSO HAVE BEEN A FAN OF THE INNOVATIVE
METHODS THAT MERCEDES-BENZ USES TODAY IN DEVELOPING SAFETY.
VIRTUAL ROAD TEST Simulator testing
Realistically simulating highly dynamic manoeuvres such as changing lane is a particular challenge, along with conducting intensive research into driver and vehicle behaviour on the road. This is where the new driving simulator in Sindelfingen comes in, which has been in action since 2010. The simulator cell is a hexapod mounted on six rail-based move-able supports. Inside there is a complete car, as well as a 360° projection screen. The unit moves electrically at a maximum speed of ten metres per second (36 km/h) and up to twelve metres in a lateral direction so that it is even possible to simulate crossing two lanes.
Mercedes-Benz’s pio-neering spirit of invention contin-
ues. In the year 2000, the brand harnessed much of its technological expertise at the Mercedes Technology
Center (MTC) in Sindelfin-gen, Germany. Research, development, design, plan-ning, and production are closely integrated. “Interac-tion between the various areas couldn’t be more inten-sive or closer. This allows us to reduce development times
and significantly increase the maturity of our prod-ucts,” explains Prof Dr Thomas Weber, member of the Board of Management of Daimler AG.
Many of the approximate-ly 10,000 designers are con-cerned with safety – tradi-
State of the art: the simulator in Sindelfingen has a 360° screen, a fast electric drive system and provides twelve metres of lateral or longitudinal movement
A realistic driving experience: the simulator allows new assistance systems to be evaluated using ordinary drivers Pioneering: the first of Mercedes-Benz’s simulators,
photographed without projection dome (Berlin, 1985)
2120
1989: the E-Class W 124
with 25,000 finite elements
1994: by the time of the E-Class W 210,
the computer could handle 75,000 elements
2008: simulation provides insights into
everything that happens during a crash
tionally a key area of compe-tence for the inventor of the automobile. For decades, Sindelfingen was also where Béla Barényi, the “father of passive safety in auto-mobiles”, worked (see page 34). Ideas that the visionary
engineer outlined on paper at that time because of the vastly increased complexity today require elaborate test facilities and methods of calculation to advance them.
It is not just many funda-mental aspects of the safe automobile that were devel-
oped and brought to series production by Mercedes-Benz. Many methods and de-velopment tools can also be attributed to the company.
As part of the process, Mercedes-Benz always fo-cuses on the customer. From the early 1970s onwards, customers have been invited to the test track so that the car maker can observe how they handle the car: “We play a game: ‘Always expect the unexpected’. All people have to do is drive in a straight line at 60 km/h. And to respond. To children playing or unobservant pedestrians. Who suddenly shoot out across the road in the form of dummies. We are interested in what happens
NON-DESTRUCTIVE CRASHING Detailed computer simulations
Crash tests are increasingly performed on computer. Starting in the mid-1980s with rough models, this approach now provides detailed insights into exactly what happens when a car deforms in an accident. The polygon mesh for the virtual vehicle structure is now comprised of more than two million tiny rec-tangles and triangles. Every year, more than 50,000 virtual crash tests are carried out, tying up one of the world’s biggest IT networks: it takes 5000 pro-cessors one day to complete the 320,000 million calculations that make up a virtual crash.
“ALWAYS EXPECT THE UNEXPECTED” OVER 40 YEARS AGO
2003: in excess of two million elements supply an accurate
portrayal of crash processes. Engineers are able to view every detail
accurate to the millisecond and to adjust the design accordingly
BASICS DEVELOPMENT TOOLS
2322
next. This is what we meas-ure. Each driver is accompa-nied by a range of measur-ing equipment to record their reactions: do they steer or brake first? Do they floor the accelerator or wrench the vehicle away? We also measure how the vehicle responds to the driver and
whether it tail-skids, slides or fishtails (not dangerous in the test environment). That is how we ascertain the way in which people consistently respond to certain situations when driving. We have to take this into account when designing our cars in order to compensate for human error. Our way of building
cars demands this.” This is how an advertisement described the process at the time.
Since 1985 trials with test subjects have also been con-ducted indoors. That is when Mercedes-Benz opened the first driving simulator – de-veloped in-house because, although flight simulators existed at that time, there were none for cars. The new driving simulator at the MTC in Sindelfingen has been operational since 2010. Its purpose remains the same. Normal car drivers are able to approach the physical limits of driving performance with absolutely no danger, providing engi-neers with invaluable find-ings on the acceptance and operation of new safety sys-tems. At the same time, en-gineers are able to test the
BASICS DEVELOPMENT TOOLS
VIRTUAL DUMMY Biomechanical human model
Virtual human models provide a clearer picture of what happens to a vehicle’s occupants in an accident than crash test dummies. “All the crucial biological features of humans – joints, muscles, tendons, ligaments, bones – can only be simulated in very rough terms with dummies,” explains Dr Hakan Ipek, a safety engineer. “Some seated positions, such as when a rear passenger is dozing and the belt does not pass over the pelvis in the correct manner, simply cannot be recreated with a dummy.”
THE VEHICLE MUST ASSIST EVEN AN ERRING DRIVER
Transparent car: when projected,
three-dimensional digital mock-ups
allow engineers to analyse how all
details and components interact
Transparent bodies: on the virtual human
computer model, biomechanical properties
are simulated in detail to examine the loads
that occur during the virtual crash test
VIRTUAL DUMMYBiomechanical human model
Virtual human models provide a clearer picture of what happens to a vehicle’s occupants in an accident than crash test dummies. “humans – joints, muscles, tendons, ligaments, bones – can only be simulated in very rough terms with dummies,” explains Dr Hakan Ipek, a safety engineer. “positions, such as when a rear passenger is dozing and the belt does not pass over the pelvis in the correct manner, simply cannot be recreated with a dummy.”
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systems and components of future models at all phases of development. Another highly advanced test station at the MTC is the “ride simu-lator”. Programmed with vehicle data and road sur-faces from real test tracks,
the ride simulator allows engineers to “drive” a new Mercedes-Benz model on the test station at even very early stages of a project.
Early testing also helps with conceiving the digital prototype. All the car’s com-ponents are segmented into a polygon mesh to create a virtual vehicle structure. This is comprised of more than two million tiny rectan-gles and triangles. As a re-sult, much more precise and detailed deformation analy-sis is possible than in the 1980s when Daimler-Benz engineers started to work on the vision of virtual crash
BASICS DEVELOPMENT TOOLS
AUTO PILOT AT THE WHEEL Automatically driven test vehicles
Mercedes-Benz was the first manufacturer to use auto pilots on closed test facilities to perform safety-critical manoeuvres, which could not be reproduced with precision by humans. “Auto-mated driving” supports the development, testing and validation of assistance systems, as well as testing airbags for misfiring, for example. This makes it possible to carry out tests at critical limits safely and without endangering developers. The test vehi-cles are series production vehicles fitted with robots to operate the steering system, accelerator and brake.
IT TOOK 30 YEARS TO THE VIRTUAL CRASH TEST
Repeated accuracy: if a vehicle
drives a pre-planned course
multiple times, the exact routes
followed differ by less than
two centimetres over all cycles
No driver: the route and manoeuvre are programmed in
while robots perform steering, braking and accelerating operations
Contact with no adverse consequences: engineers at Mercedes-Benz use the soft crash target to test assistance systems
2726
testing. At that time ele-ments were substantially larger at 25 millimetres. Back then it took a good five days for the mainframe com-puter to perform the calcu-lation for a crash test simula-tion. These days, there may be just a day between out-putting and inputting ex-traordinarily complex data.
Even the crash test dum-my (see page 164) – a sym-bol of scientific crash testing for 50 years – is slowly approaching retirement. For around 15 years now, Mercedes-Benz has been applying virtual biomechan-ics. Virtual human models simulate the body’s internal structures. In the analytical model, the body consists of approximately 1400 differ-ent materials featuring vary-ing biomechanical proper-ties. For a full simulation, the model will one day con-sist of millions of finite ele-ments. At present there are only about 100,000. Medical and forensic findings are being incorporated all the time to refine the model.
No matter how sophisti-cated methods of simulation and calculation become, tests involving real vehicles remain essential. Such test-ing includes the crash tests
that Mercedes-Benz has been systematically carry-ing out for over 50 years, and which are described in more detail in this brochure from page 148 onwards.
It may also refer to opera-tional tests at Sim-City, a
special test facility in Sin-delfingen for testing assis-tance systems. Here too, Mercedes-Benz engineers have done pioneering work: the company was the first manufacturer to deploy driv-ing robots. They allow devel-opers to reproduce manoeu-vres without putting anyone in danger. Human judge-ment continues to be a criti-cal factor, though, and real testing with real cars and re-al testers remains core to the development process. ■
BASICS DEVELOPMENT TOOLS
ORGANISED DESTRUCTION Crash testing at Daimler since 1959
The first impact tests carried out by Mercedes-Benz as early as the late 1950s were spectacular: winches or hot-water rockets were used to propel the cars. Crash tests still form the basis of safety development at Mercedes-Benz. These days, however, vehicles are accelerated by means of a high-tech cable pulley system. Every year some 500 impact tests of this kind are carried out at the development centre in Sindelfingen. Altogether, new Mercedes-Benz passenger cars must pass almost four dozen different crash tests, many of which are not a legal obligation.
DRIVING ROBOTS AS TEST DRIVERS IN SIM-CITY
Roof-drop test: every
Mercedes-Benz model must
survive a roll-over simulation.
This test is not a legal obligation
Corkscrew: roll-over after driving over a special ramp
Rocket sled accident: the engine did not detach from the test vehicle
Soft landing for dummies: the current A-Class during a crash test
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BASICS ACCIDENT RESEARCH
Wednesday, 29 Jan-uary 1969 was a cold, grey win-
ter’s day. At the Interior Min-istry of the state of Baden- Württemberg, government officials and police commis-sioners came together with representatives from the then Daimler-Benz AG for a conference lasting several hours. On the agenda was
an extraordinary request by the automotive manufac-turer: a request for police support during the recon-struction and analysis of traffic accidents involving Mercedes-Benz models.
In this way the develop-ment engineers sought to obtain findings from real accidents and use them for the further improvement of occupant safety. Daimler- Benz had already gained
some initial experience in this field two years earlier, during a six-month pilot test: from January to June 1967, employees of the company worked together with police personnel to examine seri-ous traffic accidents occur-ring in the Böblingen area and on the No. 8 motorway.
During the conference at the ministry, the company sought to put this research project on a broader and
SYSTEMATIC ANALYSIS
REALITY IS THE YARDSTICKFOR 45 YEARS THE ACCIDENT RESEARCHERS AT MERCEDES-BENZ
HAVE GATHERED INFORMATION ABOUT THE NATURE AND COURSE OF
ACCIDENTS, THE DEFORMATION BEHAVIOUR OF BODY STRUCTURES
AND THE CAUSES OF INJURIES. THEIR FINDINGS ARE INCORPORATED
INTO THE DESIGN OF NEW MODELS, AND PROVIDE A BASIS FOR THE
DEVELOPMENT OF REALISTIC TEST PROCEDURES AND STANDARDS.
“THERE WAS VIRTUALLY NO DAMAGE IN THE INTERIOR.”
“IN ANY OTHER CAR I WOULD PROBABLY NOT BE ALIVE TODAY.”
On 9 April 2008 PETER ITEN driving a Mercedes M-Class survived
a mass pile-up involving 73 vehicles between Lausanne and Vevey
On 20 August 2010 JANA BERGNER in her CLS-Class
was overrun by a six-tonne tractor
Like detectives, accident researchers like
Roland Krajewski for example establish how well
the occupants were protected by the airbags
80 to 100 times each year the accident researchers at
Mercedes-Benz are called out to examine serious collisions
3130
BASICS ACCIDENT RESEARCH
“IT’S VERY IMPRESSIVE WHEN YOU SEE THE
MERCEDES-BENZ DRIVER GET OUT OF HIS VEHICLE BY HIMSELF AFTER A CRASH LIKE THAT.”
DAVID HEINKELE, Böblingen fire service
“I AM CONVINCED THAT MERCEDES-BENZ SAVED
MY LIFE.”
On 10 June 2008 BERND VAN HUSEN suffered
only bruises in his C-Class when colliding
with a car travelling the wrong way on the A81
above all permanent basis. It succeeded: the heads of the relevant police depart-ments once again indicated their willingness to cooper-ate. An express letter in-forming other official bodies and requesting assistance was sent out immediately. On 29 April 1969 the acci-dent research project re-ceived the official go-ahead. Once a number of details had been clarified, the Inte-rior Ministry using case ref-erence number III 5304/126 decreed that in future, the police stations would inform the car manufacturer by telephone when accidents occurred, and that the repre-sentatives of the company
were able to view the acci-dent files and were permit-ted to question the officers involved about the incident. The reason given: “The Inte-rior Ministry supports the in-house research activities by Daimler-Benz AG, as they are of general importance for traffic safety.”
Thanks to good coopera-tion with official bodies and police stations, the area covered by Mercedes-Benz accident research was in-creased several times over the following years. Today it extends from Baden-Baden to Ulm, from Mannheim to Freiburg and from Tauber-bischofsheim to Freuden-stadt – a radius of around 200 kilometres from Sin-delfingen.
Some 45 years of Mer-cedes-Benz accident re-search means 45 years of painstaking investigation and data collation. Nowadays the accident researchers are out and about around 80 to 100 times each year to subject serious collisions to their scientific gaze. Since the formation of the accident
research department, they have examined and recon-structed over 4,200 traffic accidents.
The work of the research-ers usually begins at the accident scene: How did the accident come about? In what positions were the vehicles after the impact? Are there tyre or skid
marks? How severely was the bodywork deformed? Were the airbag(s) and belt tensioner(s) deployed? Is there anything unusual in the interior of the Mercedes-Benz model involved in the accident? What injuries were sustained by the occupants? Which driver assistance sys-tems would have helped to
SERIOUS ACCIDENTS WITHIN A RADIUS OF 200 KILOMETRES
DETAILED ANALYSIS Modern assistance systems reduce the risk of injury.
In 2009 it was once again demonstrated that Mercedes-Benz drivers are safer on the road with modern assistance systems. This was the result of a study by Mercedes-Benz accident researchers based on GIDAS accident data and a replacement parts survey. Vehicles on the road both with and without a sys-tem were included. The results were clear: DISTRONIC PLUS with BAS PLUS and PRE-SAFE ® Brake reduces the risk of being seriously injured or killed in the impacting vehicle by 35 per-cent during a frontal collision.
Severely injured and dead
Lightly injured
0Reduction of injury risk in percent
-10-20-30-40
-35
-20
Source: GIDASStudy period 2003-2007
Dozens of photos, sketches, measurements and data obtained at the scene
help during the systematic reconstruction of a collision
3332
BASICS ACCIDENT RESEARCH
“THERE IS SOMETHING TO BE LEARNED FROM EVERY ACCIDENT.”
“THE MORE INFORMATION WE HAVE, THE BETTER WE CAN PUT
THE PUZZLE TOGETHER.”
UWE NAGEL, accident researcher
at Mercedes-Benz for over 20 years
DIRK OCKEL, Head of Accident Research at Mercedes-Benz
prevent the accident or miti-gate its severity?
Question after question, the answers to which are electronically recorded using a tablet PC. Plus doz-ens of photos, laser scans, sketches and injury reports. When all the information is finally to hand, the collision is systematically recon-structed. The researchers are assisted in this by spe-cialist software which con-verts the collected data and measurements into moving images. As part of the pro-cess, the computer compares for example the length of the tyre or skid marks at the
scene with the engineering and dynamic data of the Mercedes-Benz model in-volved in the accident, and reconstructs what happened
as it occurred. On the screen the specialists are then able to establish how the car moved before, during and after the impact.
Finally the results are compared with data from other accidents, so that over time the engineers are able
to obtain a precise picture of typical injuries, and find-ings for the development of new, even more effective protective systems. With the help of a so-called prospec-tive efficiency analysis, the accident researchers are also able to ascertain what the consequences of an accident would have been if a particu-lar safety feature had been on board. Accident research is an important component of the safety philosophy “Re-al Life Safety” – namely tak-ing the lead from real acci-dents, not only from labora-tory tests alone. ■
Alle Informationen über den
Crash werden gespeichert und
später für die Computersimulation
des Unfallhergangs genutzt
AROUND 80 PAGES OF ACCIDENT DATA AND MANY PHOTOS
Early investigations: even before systematic accident research took off, Mercedes-Benz engineers
took a critical look at cars involved in accidents – here a Mercedes-Benz 300
All the information about the crash is saved – in this case by the Head of Accident Analysis, Heiko Bürkle – and used later to reconstruct what happened
34 35
BASICS BÉLA BARÉNYI
Lasting legacy: Mercedes-
Benz design engineer Béla
Barényi invented the safety
body with rigid occupant cell
and defined crumple zones.
Patented in 1951, this was
implemented in the 1959
Mercedes-Benz 220 SE
Béla Barényi had groundbreaking ideas early on: during his
studies in the 1920s, he worked on a concept for a modern automobile with a tubular backbone chassis and air-cooled, horizontally opposed engine – as subse-quently realised by Porsche in the form of the Volkswa-
gen Beetle. From 1939 the engineer dedicated himself to improving passenger car bodies at Mercedes-Benz. This work resulted in a 1941 patent for an improved plat-form frame which, owing to its particular resistance against distortion, minimised “booming and shaking”.
From his studies of motor vehicles based on a cellular design, Barényi developed
the concept of a stiff passen-ger cell with crumple zones. Daimler-Benz implemented the patent filed in 1951 for the first time on model series W 111 (“Fintail”) of 1959. Crumple zones deform in an accident and absorb the kinetic energy from the collision in a controlled way. At the same time, a sturdy occupant cell protects the vehicle occupants. Since
that time, this structure has become an established part of passenger vehicles worldwide.
Barényi’s “safety steering shaft for motor vehicles” also caught on. This technology was patented in 1963 and premièred as a complete safe ty steering system in the W 123 series of 1976, the predecessor to the E-Class. ■
An eye for detail: Barényi (centre) assesses a vehicle after a crash test.
He was Head of Advance Development at Daimler-Benz until 1974
BÉLA BARÉNYI
THE FATHER OF SAFETYVISIONARY ENGINEER BÉLA BARÉNYI (1907-1997) WORKED FOR DAIMLER FROM 1939 TO 1974. HE
INITIATED MORE THAN 2500 REGISTERED PATENTS, MANY OF THEM CONCERNED WITH THE PRINCIPLES
OF AUTOMOTIVE SAFETY. HE INVENTED THE SAFETY ZONE PROTECTED BY CRUMPLE ZONES.
3736
BASICS EXPERIMENTAL SAFETY VEHICLES
ESF 2009
EXPERIENCE THE FUTURETHE ESF OF 2009 IS MERCEDES-BENZ’S FIRST EXPERIMENTAL
SAFETY VEHICLE SINCE 1974. LIKE ITS HISTORIC PREDECESSORS, IT
BRINGS TOGETHER PIONEERING INNOVATIONS IN THE FIELD OF VEHICLE
SAFETY WITH INTUITIVE ACCESSIBILITY, MAKING PROGRESS COME
ALIVE. SOME OF ITS INNOVATIVE FEATURES, SUCH AS THE BELTBAG,
HAVE NOW ENTERED SERIES PRODUCTION AT MERCEDES-BENZ.
Inflatable metal structures, which give structural components greater stability
within fractions of a second, are one of the highlights of the ESF 2009
3938
BASICS EXPERIMENTAL SAFETY VEHICLES
The experimental ESF 2009 safety vehi-cle revealed what
Mercedes-Benz’s safety ex-perts were researching and working on five years ago. In some respects they were looking many years into the future. Meanwhile, some in-novative features have al-ready entered series produc-tion: in 2013 the beltbag made its début in the new S-Class, with Interactive Ve-hicle Communication (see page 178) likewise launch-ing that year. The next step in lighting technology fol-lows this year in the shape of Active Multibeam LED headlights (see page 128).
The ESF 2009 was devel-oped and built entirely at the test vehicle workshops in Sindelfingen. This ex-perimental safety vehicle based on the Mercedes S 400 HYBRID features more than a dozen safety innovations. The following five innova-tions are among the high-lights of the ESF 2009:
PRE-SAFE ® structure: the inflatable metal structures save weight or increase the stability of structural com-ponents. When at rest, the metal section is in a folded state to save space. If its pro-tective effect is required, a
gas generator builds up an internal pressure of 10 to 20 bar within fractions of a second, causing the section to unfold for significantly more stability.
Braking Bag: this auxilia-ry brake accommodated in the vehicle floor is a new type of component. If the sensors and control unit pre-dict that an impact is cer-tain, the “Braking Bag” is deployed just before the col-lision and supports the vehi-cle against the road surface with its friction coating. The vehicle’s brake dive increas-es the friction and helps to decelerate the vehicle before the impact occurs (see also page 73 of this magazine).
Interactive vehicle com-munication: the ESF 2009 is able to communicate directly with other vehicles, or via relay stations. Using ad-hoc networks and WLAN radio technology, it is able for ex-ample to receive and trans-mit warnings of bad weather or obstacles in the road.
PRE-SAFE ® Pulse: this further development of PRE-SAFE ® is able to reduce the forces acting on the torsos of the occupants during a later-al collision by around one third. It does this by moving them towards the centre of the vehicle by up to 50 milli-metres as a precautionary
measure by inflating air chambers in the seat cush-ions. A similar system is found in the latest S-Class: with PRE-SAFE ® Impulse, the driver and front passen-ger are pulled away from the direction of impact by their
seat belts at an early phase of the crash, before the re-sulting occupant decelera-tion sets in. Consequently the risk and severity of inju-ries in a frontal collision are reduced significantly.
Spotlight lighting func-tion: this partial LED main beam illuminates potential hazards. If the infrared cam-era of Night View Assist Plus detects pedestrians in the road, these can be briefly illuminated as if by a spot-light. This feature is now also a reality.
Mercedes-Benz is continu-ing a long-standing tradition with the ESF 2009: safety experts in Stuttgart built more than 30 experimental vehicles for the ESV Safety Conferences held from 1971 to 1975 and subjected them to crash tests to satisfy the ever-visionary safety re-quirements of Mercedes-Benz. Four of these experi-mental safety vehicles were presented to the public, and many of the revolutionary ideas such as ABS or the airbag first entered series production at Mercedes-Benz. ■
Based on the /8,
the ESF 5 (1971) was
equipped with driver’s
and front passenger’s
airbag and, for rear
passengers, two airbags
in the backrests of the
front seats
With ABS, driver’s
airbag, belt tensioners
and belt force limiters,
the ESF 24 (1974)
possessed modern
restraint systems. Based
on the S-Class (W 116)
To protect pedestrians and cyclists the front
and rear bumpers of the ESF 13 (1972) have foam
side sections and the door handles are rounded
The ESF 22 (1971) had a front-end
extension of 15 centimetres with hydraulic
impact absorbers. Its equipment included
four three-point belts, each with three force
limiters and a belt tensioner
OFTEN LOOKING MANY YEARS INTO THE FUTURE
MANY VISIONS HAVE BECOME SERIES REALITY
4140
BASICS FACTS, FIGURES AND CURIOSITIES
1,500 SIMULATIONSIn the year 2000, the 203 model series was one of the first cars for which crash test simulations played a serious part in development. More than 1500 simulations were carried out. The successor unveiled in 2007 was the first series production car in the world to be developed using the trend-setting digital prototype (DPT) method. This made it possible for all simulation methods to be pooled for the first time, and thus to create a completely virtual car. As well as the high speed of development, the decisive advantage that computer simulation has over real crash tests lies not only in the fact that the vehicles are not destroyed; even more important than that is the ability which engi-neers have to detect and follow what actually happens in an impact in great detail.
250,000 EUROSThe first dummies designed specifically for safety tests were used in the USA in 1949 to test ejector seats in jet fighters, and were later adopted by the automotive industry too. However, the first crash test dummies intended specifically for automotive safety research did not appear until the late 1960s. Since that time, dummies have become more and more sophisticated. The latest dummies cost up to 250,000 euros.
DID YOUKNOW?
300 KILOGRAMMESThe more than 30 experimental safety vehicles (German abbreviation ESF) built by Mercedes-Benz between 1971 and 1974 satisfied the require-ments of the US National Highway Traffic Safety Administration (image shows the ESF 21 following an offset impact). However, they had up to 300 kilograms of additional reinforce-ment on board and proved to be too heavy. A more realistic aim (reducing the impact speed against a rigid barrier from 80 to 65 km/h) and intensive further basic research were tangible outcomes of activities involving experi-mental safety vehicles.
60 STEERING WHEELSFrom the 1930s onwards, inventor Béla Barényi was pre-occupied by steering wheels and steering columns – the main cause of serious and fatal injuries among car drivers. He protected his findings with a series of patents. For a 1976 publication (“Wege zum ausgewogenen Alltagsauto von morgen” – Approaches to the well-balanced, everyday car of tomorrow), Barényi analysed 60 of the steering wheels available on the market and reached a harsh conclusion: “A good 90 percent of all steering wheels presently used in global car manufacturing are outright criminal instruments.” He goes on to say: “Appalling injuries arise from relatively harmless front-end collisions because the steering system can penetrate the vehicle interior… and measures known about for decades… have not been applied.”
4,200 ACCIDENTSAs early as 1969, Daimler started to systematically examine real accidents involving Mercedes-Benz passenger cars, with colleagues on the truck side following a year later. The researchers went out up to one hundred times a year to meticulously document and analyse accidents. This included looking at aerial photographs. The database now extends to more than 4200 road traffic accidents.
4342 4342 4342
NINE LIVESCATS are true survival experts: even if they fall from
considerable heights, their visual sense and fine balance go into
action instantly to make sure that they land on their paws
IN 2002 MERCEDES-BENZ BEGAN A NEW
ERA IN VEHICLE SAFETY WITH THE PRE-
VENTIVE OCCUPANT PROTECTION SYS-
TEM PRE-SAFE®. PRE-SAFE® IS
ABLE TO ACTIVATE PREVENTIVE SAFETY
MEASURES FOR CAR OCCUPANTS. THE
AIM IS TO PREPARE THE CAR AND ITS OC-
CUPANTS FOR AN IMPENDING IMPACT,
SO THAT IF IT OCCURS, THE SEAT BELTS
AND AIRBAGS CAN FULFILL THEIR PRO-
TECTIVE FUNCTION TO THE FULL.
PRE-
SAFE
PRE-
SAFE Ph
oto:
Her
bert
Spi
chti
nger
/Cor
bis
4544 4544
PRE-SAFE BASIC FUNCTIONS PRECAUTIONARY SAFETY MEASURES
CAR WITH PROTECTIVE REFLEXESPRE-SAFE ® ENTERED SERIES PRODUCTION AT MERCEDES-BENZ OVER TEN YEARS
AGO. THE PROTECTIVE MEASURES OF THE FIRST GENERATION: WHEN THE CAR
REGISTERS A CRITICAL DRIVING SITUATION WITH THE HELP OF THE ESP® SENSORS,
THE FRONT SEAT BELTS ARE TENSIONED AS A PRECAUTION, THE FRONT PASSENGER
SEAT WITH MEMORY PACKAGE (OPTION) IS MOVED TO A MORE FAVOURABLE
POSITION FOR AN IMPACT AND THE SLIDING SUNROOF IS AUTOMATICALLY CLOSED.
Arrows point to the basic functions of PRE-SAFE ®, in this case
using a C-Class (W 204) of 2006 as an example: The front seat belts
are tensioned as a precaution (red arrows), the side windows and sliding
sunroof are closed (blue) and the electrically adjustable front passenger
seat is brought into a more favourable position for a crash (orange).
4746
PRE-SAFE BASIC FUNCTIONS
Two thirds of all accidents are preceded by critical driving situations, according to analyses by Mercedes-Benz accident researchers
THE FOLLOWING ARE THE PREVENTIVE MEASURES INITIATED BY PRE-SAFE ®
PRE-SAFE ® in situations with critical longitudinal dynamics
PRE-SAFE ® in situations with critical lateral dynamics**
The driver and front passenger seat belts are tensioned
The side windows are closed, leaving only a small gap
The fore-and-aft setting and height plus the cushion and backrest angle of the front passenger seat* are brought into a more favourable position for an accident
The sunroof* is closed, leaving only a small gap
The bolsters in the seat cushions and backrests of the multicontour front seats* are inflated
*if fitted in the vehicle concerned **in addition to the emergency braking measures
Their sensors detect poten-tial critical driving situa-tions and send appropriate information to the electronic control units within milli-seconds.
When installed in combi-nation with DISTRONIC
PLUS, PRE-SAFE ® also uses the information provided by the short-range radar sen-sors in the front bumper to tension the front seat belts at the very last moment before an unavoidable collision, thus reducing the forces
exerted on the driver and front passenger during a crash. This PRE-SAFE ® func-tion is literally the “ultima ratio” of anticipatory occu-pant protection, since the impact occurs around 150 milliseconds later. ■
Over ten years after the world premiere of the preventive oc-
cupant protection system PRE-SAFE ® in the S-Class (W 220) in autumn 2002, PRE-SAFE ® is available in 16 model series throughout the model range of Mercedes-Benz Cars, from the A- to the S-Class, and can currently take preventive measures in up to 13 scenarios where accidents occur most. More than half of all Mercedes-Benz passenger cars deliv-ered worldwide in 2013 were equipped with PRE-SAFE ®
as standard. In the new S-Class, Mercedes-Benz has extended the PRE-SAFE ® system with new functions (see next double-page).
There are no statistics to show how many lives
PRE-SAFE ® has helped to save in the meantime, or how many injuries it has helped to prevent or mini-mise. However, analyses car-ried out by Mercedes-Benz accident research have
shown that more than two-thirds of all traffic accidents are preceded by critical driv-ing situations which enable conclusions to be drawn about risks or impending collisions. PRE-SAFE ® is therefore a significant ele-ment of the holistic safety concept by Mercedes-Benz known as “Real Life Safety”.
Analyses performed dur-ing crash tests show just how important and effective
anticipatory occupant pro-tection can be. Take seat belt tensioning, for example: because the precautionary measures mean that the driver and front passenger are held in their seats in the best possible position, and so do not move forward as much prior to the impact as a result of emergency brak-ing, the loads exerted are correspondingly reduced. These tests have shown that the head of a dummy is sub-jected to around 30 percent less stress, while Mercedes-Benz engineers have record-ed a reduction of around 40 percent in the neck area.
PRE-SAFE ® is able to acti-vate preventive safety meas-ures for car occupants. The aim is to prepare the car and its occupants for an impend-ing impact, so that if it oc-curs, the seat belts and air-bags can fulfill their protec-tive function to the full. PRE-SAFE ® protective meas-ures are reversible: if the accident is averted, the ad-vance tensioning of the seat belts is reversed automati-cally and the occupants are able to reset the positions of the seats and the sliding sunroof. The anticipatory occupant protection system is then immediately ready for action again.
PRE-SAFE ® is for example activated in the event of emergency or panic braking, severe oversteer or under-steer, critical steering ma-noeuvres or activation of Brake Assist. Early detection of an accident is possible because PRE-SAFE ® is net-worked with the Brake Assist and ESP ® systems.
AVAILABLE IN A TOTAL OF 16 MODELSERIES
THE HISTORY of PRE-SAFE ®:
2002 Introduction in the S-Class (W 220); functions: preventive tensioning of the front seat belts, better positioning of the power-adjustable front passenger seat, automatic closing of the sliding sunroof (optional)
2005 combination with Brake Assist PLUS; extended functions: automatic closing of the side windows, inflation of side bolsters on multicontour front seats (optional)
2006 PRE-SAFE ® activation by additional assist systems with radar technology
2011 Debut in the compact class (B-Class W 246)
2013 Introduction of new functions in the S-Class: PRE-SAFE ® PLUS and PRE-SAFE ® Impulse (see next double-page), networking with stereo camera
4948
PRE-SAFE NEW FUNCTIONS
vehicle’s brakes are “locked”. Immediately before impact, the PRE-SAFE ® anticipatory occupant protection meas-ures, especially the reversi-ble belt tensioners, are also deployed.
Keeping the vehicle firm-ly braked when another vehicle hits it from behind greatly reduces the risks to the occupants, such as that of whiplash injuries. At the same time, it serves to pro-tect other road users by re-stricting uncontrolled vehi-cle movements after the ini-tial impact that could lead to secondary collisions, such as being shunted into a vehicle in front or colliding with pedestrians or other road users at junctions.
Mercedes-Benz is extend-ing the front seat belt’s pro-tective function with the introduction of PRE-SAFE ® Impulse: at an early phase of the crash, before the result-
ing deceleration sets in, the front occupants are pulled away from the direction of impact and deeper into their seats by their seat belts. By the time the accident enters the phase when loads peak, the extra distance they are retracted by can be used
while dissipating energy in a controlled fashion thanks to additional force limiting in the belt buckle. Pre-accel-eration and force limitation allow the occupants to be temporarily isolated from the effects of the crash. Con-sequently the risk and sever-ity of injuries in a frontal collision are reduced signifi-cantly.
With PRE-SAFE ® Impulse, the seat belt strap can be retracted by pyrotechnical means at all three belt an-
chorage points, both in the pelvis and chest area, and released again with con-trolled force at the buckle and in the shoulder area. The fundamental difference compared to conventional belt tensioners is that the force for retracting the belt strap is maintained more consistently for a much longer time. The deployment logic fires the seat belt system’s belt tensioners pro-gressively depending on the seriousness of the acci-dent. In this way, the ten-sioning force can be adapted as required. The PRE-SAFE ® Impulse system is integrated into the seat’s structure and supplements the pyro-technical reel tensioner with a pyrotechnical buckle and anchor fitting tensioner including a central gas generator. ■
PRE-SAFE ® PLUS Occupant protection in case of impending rear-end collisions
If the danger of a collision persists, PRE-SAFE ® PLUS can support the driver by increasing the brake pressure. The vehicle’s brakes are “locked”, which also reduces the danger of secondary impacts
BRAKE LOCKING PREVENTS SECONDARY IMPACTS
PRE-SAFE® PLUS extends the familiar occupant protection
measures to include hazard-ous situations with following traffic. A radar sensor in the rear bumper monitors the traffic following behind the
car. If an impending rear-end collision is recognised, the driver of the vehicle following behind is warned by high-frequency (5 Hz) flashing of the rear hazard warning lamps (not for vehi-cles with country code USA/Canada). When the car is at a standstill and the driver
indicates a wish to remain stationary (for example by keeping the brake pedal depressed, activating the HOLD function or engaging transmission position “P”), PRE-SAFE ® PLUS provides support if the collision dan-ger persists by increasing the brake pressure. The
FOCUS ON FOLLOWING TRAFFIC
CAR WITH ALL-ROUND VISIONTHE NEW PRE-SAFE ® FUNCTIONS CAN HELP TO PREVENT
REAR-END COLLISIONS IN CITY TRAFFIC, DEFUSE DANGEROUS
SITUATIONS CAUSED BY TRAFFIC BEHIND AND ENHANCE
THE PROTECTION OFFERED BY THE SEAT BELTS.
Activation of PRE-SAFE ®Activation of rear hazard warning lights at a higher frequency
1
2
3
Rear collision is detected The vehicle is kept firmly braked
PRE-SAFE ® IMPULSE Temporary decoupling of occupants
PRE-SAFE ® Impulse: at an early phase of the crash, before the resulting deceleration sets in, the front occupants are pulled away from the direction of impact and deeper into their seats by their seat belts.
5150
PRE-SAFE INTERVIEW
Mercedes-Benz engineers Prof Rodolfo Schöneburg (54) and Karl-Heinz Baumann (62) were instrumental in
the development of PRE-SAFE® from the initial idea through to its readiness for series produc-tion. Prof Schöneburg is head of the Safety, Durability and Corrosion Protection Center at Mercedes-Benz Cars. In addition to his honor-ary professorship at the Dresden University of Applied Sciences, Prof Schöneburg also holds various other distinctions, including the re-nowned “Pathfinder Award” from American safety association the “Automotive Safety Council” and the “Gold Diesel Ring” from the German Association of Automotive Journalists (VdM). Mr Baumann worked for Mercedes-Benz for 35 years. The many innovations developed under his direction include the automatically extending roll-over bar on the SL from the R 129 model series, the ellipsoid bulkhead concept on the SLK from the R 170 model se-ries and the tridion safety cell on the smart. As Mr Baumann’s successor, Michael Fehring (48) heads the Passive Safety Concepts and Strate-gies department. Prior to this, he was f. i. pro-ject director for the ESF 2009 experimental safety vehicle, which incorporated numerous PRE-SAFE® innovations.
PROF RODOLFO SCHÖNEBURG, MICHAEL FEHRING, KARL-HEINZ BAUMANN
“USING VALUABLE TIME”A DISCUSSION WITH THE ORIGINAL BRAINS BEHIND PRE-SAFE®
Mr Baumann, is it true that your daughter had a biology book with a picture of a cat dropping to its feet? Or is it just a popular myth that this inspired you to evolve the idea of a car with reflexes – as the fundamental idea behind PRE-SAFE®?Baumann (laughs): Well, to be precise it was actually a Mickey Mouse comic book. I asked my daughter, who was eight at the time, how she would illus-
trate the fact that every living being reacts reflexively to sudden dangers. In response to which, she showed me her comic with a drawing of a cat. The comic still exists, by the way, and has even been exhibited on several occa-sions as part of Mercedes-Benz’s tour-ing exhibition “Prepare to be safe”.
How did you come up with the idea of also utilising the time prior to a crash
for safety measures - this being the radically new aspect of PRE-SAFE®?Schöneburg: As with so many Mercedes-Benz safety innovations, the decisive impulse that triggered the development of PRE-SAFE® was real-world crashes. These revealed that the symptoms of an impending accident are frequently manifested be-fore the actual collision. This means that valuable time used to be lost when the protection systems were only acti-vated once a collision had occurred.
Group portrait with dummies: Mercedes-Benz
safety experts Prof Rodolfo Schöneburg, Michael Fehring
and Karl-Heinz Baumann in the dummy laboratory
5352
PRE-SAFE INTERVIEW
PRE-SAFE® makes use of this time, from initial identification of a driving situation harbouring crash potential to an actual collision, in order to pro-vide the occupants with preventive protection.
In what sort of time dimensions are we talking here?Schöneburg: An accident occurs with-in around 100 milliseconds. If you drive into a wall at 50 km/h, for exam-ple, around 0.1 seconds elapse before the car comes to a standstill, i.e. within 100 milliseconds everything must be activated and the occupant must be contained by the seat belt and airbag. But when we use the pre-accident phase with PRE-SAFE® we have not just milliseconds of time, but seconds. This enables us to bring the backrests into an upright position and to tension the seat belts as well.
PRE-SAFE® was introduced into series production in the S-Class back in the autumn of 2002. When did you begin the development process?Schöneburg: When I joined Mercedes-Benz in 1999, I took a look at the various safety departments. The PRE-SAFE® concept was presented to me for the first time by Mr Baumann and his staff. In the same year we estab-lished a PRE-SAFE® steering commit-tee comprising staff from the two areas of Active Safety - that is, accident pre-vention - and Passive Safety. We held regular meetings to coordinate and push ahead with the development of the sensor systems and triggering algo-rithms while at the same time develop-ing the actuators in the vehicle, in par-ticular the reversible belt tensioners.Baumann: The really interesting aspect here was that the areas of Active and Passive Safety, which had been working relatively independently of one another for many years, came together to work on this innovation, with each area benefiting from the collaboration. Mercedes-Benz had once defined Active
and Passive Safety as separate areas, which was very important in specify-ing the respective tasks. It was equally logical for us to merge the twoin view of our integral safety strategy at a sub-sequent juncture.
What were the biggest obstacles in developing PRE-SAFE® to production readiness?Schöneburg: First of all, I think the greatest achievement was the idea itself. For many years there was a men-tal block on the subject of pre-crash. The general view was that it needed to be one hundred percent certain that an accident would occur before features such as the airbags could be activated. The mental leap was the insight that absolute certainty that an accident will happen will probably never be attaina-ble. That we need to work on the basis of the probability of an accident, and that we therefore need to concern our-selves with reversible systems, as there is always a possibility that it may be possible to avoid an impending acci-dent. I believe that was the essential innovation!
How were the PRE-SAFE® systems tested?Schöneburg: We carried out in-depth testing of PRE-SAFE® at test sites, in road traffic and in the simulator, of course. In order to optimise the sys-tem’s capacity to identify situations, during development of the second gen-eration, when we combined PRE-SAFE® with the information from DISTRONIC PLUS, the new technology was in-stalled together with additional meas-uring equipment in taxis, for example. In 2007 these vehicles covered over 400,000 kilometres in Stuttgart city traffic. Dense stop-and-go traffic, fast and frequent lane-changes plus vary-ing road surfaces with potholes and manhole covers provided ideal condi-
more is to be expected here. This per-ception is wrong – we have a whole host of ideas aimed at further improv-ing vehicle safety.Fehring: Take our ESF 2009 experi-mental safety vehicle, for example - this featured various PRE-SAFE® innovations which we are currently developing to production standard.
In concrete terms, what will the next PRE-SAFE® innovation be?Schöneburg: We are currently concen-trating on reducing the strain on the upper torso in a side-on collision.
Doesn’t that go by the name of PRE-SAFE® Pulse on the ESF 2009?Fehring: Exactly. We aim to reduce the strain on the upper torso by gently nudging the occupants towards the
centre of the vehicle as a preventive measure. This creates additional space for even more effective deployment of the side airbag.
Occupant preconditioning as a whole appears to be a major topic in the area of PRE-SAFE®?Fehring: Yes. The PRE-SAFE® belt ten-sioner, for example, can prevent occu-pants from moving too far forward in emergency braking or their torso from swaying too far to the side in the event of skidding as a result of belt slack. Tests with Mercedes-Benz passenger cars show that the belt tensioner is able to reduce substantially such uninten-tional displacement of occupants.Schöneburg: Another component is automatic seat priming. Our accident
research specialists have established that a very strongly inclined backrest or a seat cushion in a flat position can impair passenger retention in an acci-dent. This is often the case on the front passenger’s side. When the PRE-SAFE® sensors detect an impending collision, the seat cushion inclination is automat-ically increased on the front passen-ger’s side and the backrest is moved into a position enabling the airbag and seat belt to be deployed to maximum effect.
To date, the PRE-SAFE® systems have been reversible. Is it at all conceivable that non-reversible PRE-SAFE® ideas such as the PRE-SAFE® Structure on the ESF 2009, that is, inflatable metal structures, might be introduced into series production?
tions for us to verify the algorithm. Because a kerb close by or radar reflec-tions from tram rails must not lead to activation of the occupant protection systems, of course.
In contrast to the seat belt, is it right to say that PRE-SAFE® had no problems gaining acceptance among drivers right from the outset?Fehring: Absolutely, indeed acceptance tests in the driving simulator and on the road have shown that the PRE-SAFE® systems actually enhance the passengers’ feeling of safety. This is attributable to the way in which they are firmly held in place in the vehicle in critical situations. Another finding was that the test persons reacted with greater alertness in the various dangerous situations when the belts tightened.
Is it possible to put a figure on how many lives PRE-SAFE® has saved since it was introduced 12 years ago?Fehring: There are no statistics to show how many lives PRE-SAFE® has helped to save in the meantime, or how many injuries it has helped to prevent or min-imise. However, analyses carried out by our accident research team have shown that more than two-thirds of all traffic accidents are preceded by critical driv-ing situations which enable conclusions to be drawn about risks or impending collisions. Example crash tests conduct-ed in the course of the development process additionally showed that PRE-SAFE® can reduce the risk of serious injury in frontal impact circumstances by up to a quarter.
The PRE-SAFE® system in the new S-Class covers around a dozen acci-dent scenarios. Are any further PRE-SAFE® innovations conceivable?Schöneburg: Inside and outside of the company, the wealth of safety features that we have in our series production vehicles today may have given rise to the impression that not a great deal
“Mercedes-Benz aims to remain the trend-setter in the field of safety.” KARL-HEINZ BAUMANN
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PRE-SAFE INTERVIEW
Schöneburg: This is a difficult matter, because non-reversible systems only make sense when an accident can be forecast with 100 percent certainty. And sometimes it is still possible to prevent an accident in the final second. But we are working on it, and we see potential in the intelligent networking of sensors.
The vision of accident-free driving has become established as a buzzword. It no doubt serves to spur on the safety experts at Mercedes-Benz to keep making cars safer step by step. But isn’t it true to say that as long as people are involved in road traffic, mistakes will always be made and accidents will happen?Schöneburg: The vision of acci-dent-free driving has probably been around as long as the car itself has. And of course it provides an incentive to set ourselves ambitious targets. But if you look beyond the marketing ef-
forts, the vision of accident-free driving remains just that: a vision. Of course we continue to put every effort into further reducing the number of acci-dents as well as the severity of injuries incurred, using new safety technolo-gies and our own company accident research, but there’s no point in prom-ising the impossible. The simple fact is that people make mistakes – including and even especially when they’re be-hind the wheel of a car.
Thanks to new, affordable camera and sensor technology and sensor fusion, assistance systems have undergone an innovation push in recent months. In the light of the CO2 debate and cost pressures, is it not possible that the onus might shift away from passive safety, according to the motto “Now that accidents can be avoided so effectively with assistants we can do
with legal requirements, attaining top marks in ratings and continuing to re-inforce the “Real Life Safety” concept. The high level of importance which Mercedes-Benz will continue to attach to passive safety in future is also demonstrated by the construction of the new crash building, which will go into operation in 2016 – three times as large as the old building and equipped with three crash lanes as opposed to the current single lane, to enable test-ing of all types of crash configurations.
As with ABS or ESP®, other manufac-turers have since followed safety pio-neer Mercedes-Benz and developed preventive safety systems similar to PRE-SAFE®. Does that annoy you?Schöneburg: On the contrary. After all, this is ultimately to the benefit of all road users. Many safety innovations which were first introduced onto the
market by Mercedes-Benz are now also available from other automotive manu-facturers. An aspect that is particularly important to me is that PRE-SAFE® is not reserved exclusively for the top models from Mercedes-Benz, but is cur-rently available in a total of 16 series covering the entire model range, from the A- to the S-Class.Baumann: Mercedes-Benz aims to re-tain its trend-setting, trail-blazing role in the field of safety. If the other manu-facturers choose to follow this trail, I see this as an affirmation of our pioneering work.
Have you ever found yourselves in a critical situation in which PRE-SAFE® saved you from graver consequences?Schöneburg: Yes indeed. I vividly remember an incident while on winter test drives in Sweden. The colleague at the wheel veered of the glazed-over road. PRE-SAFE® was activated, and from the seat belt tensioners to the
window bags everything worked just fine. All passengers were protected very well.Fehring: Sure, in a critical braking situation on the motorway with my family. A truck suddenly pulled out on-to the overtaking lane and I had to re-duce my speed briskly. The reversible belt tensioners did a great job contain-ing my wife and myself. My children in the rear felt the forward displacement and the sudden stop more keenly in their seat belts, however. So there is certainly still potential for further improvements…
Mr Baumann, you have been in retirement since 2012. Do you still keep up with developments? Baumann: Absolutely. I am still in close contact with my Mercedes-Benz colleagues and continue to follow the topic of PRE-SAFE® and vehicle safety in general with great interest. ■
without structural reinforcements and restraint systems, saving weight and fuel in the process”?Schöneburg: No, I don’t fear any such “decontenting”. As Mr Fehring said, around two thirds of all traffic acci-dents are preceded by critical driving situations. Conversely, this means that a third of accidents are not foreseeable or arise so spontaneously that there is not sufficient time to avoid a collision. And it goes without saying that we must also cover these cases, with ro-bust or energy-absorbing body struc-tures and state-of-the-art restraint sys-tems. We must not forget that traffic accidents will go on happening into the foreseeable future, as for the time be-ing vehicles will continue to be operat-ed by human beings and it will take a long time for driver assistance systems and automated driving to penetrate the market. That is why Mercedes-Benz will be adhering in future to its safety strategy aimed at ensuring compliance
“PRE-SAFE® systems actually enhance passengers’ subjective feeling of safety.” MICHAEL FEHRING
“We still have plenty of ideas for further improving vehicle safety.” PROF RODOLFO SCHÖNEBURG
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PRE-SAFE DEMONSTRATOR
DEMO-TOUR around the world
In 2009 the prototype construction department at MBtech Group GmbH developed and built the PRE-SAFE ® Demonstrator on behalf of Mercedes-Benz accident research. Originally it simulated PRE-SAFE ® functions on the front passenger side. In 2013 the cabin was reconfigured so that the preventive protection measures are experienced in the rear of the new S-Class. The Demonstrator weighs a total of around 2.5 tonnes, and is designed to be easily loaded onto a vehicle by fork-lift truck. The unit has hydraulically extendable rollers to allow precise placement at the destination. The Demonstrator is used around the world – for example, it has been in Australia as part of the “Safety” roadshow and in Canada for the trial driving presentation of the new S-Class.
REALISTIC IMPRESSION
TAKEN FOR A RIDEFORTUNATELY MOST DRIVERS NEVER FIND THEMSELVES IN A SITUATION WHERE
THEY EXPERIENCE PRE-SAFE ®. THE PRE-SAFE ® DEMONSTRATOR CONVEYS
A REALISTIC IMPRESSION OF HOW THIS ANTICIPATORY SAFETY SYSTEM WORKS.
The simulator uses a linear motor to accel-erate the vehicle cabin
to up to 16 km/h within a distance of four metres. This corresponds to twice the earth’s gravity acceleration, i.e. twice freefall speed. After around 1.2 seconds the cabin impacts the specially designed hydraulic shock absorbers. In the interim the
occupants experience the effects of the PRE-SAFE ® functions at first hand, e.g. belt pretensioning, PRE-SAFE ® PLUS and the re-straining effect of the seat belts during the impact. They can also try out how the new belt buckle extender (see page 78) works.
The moving mass of the Demonstrator is 500 kg. This includes the cabin, which was created from a
real S-Class Saloon whose right-hand rear area includ-ing the seat were adopted. To keep the Demonstrator compact, the left side, the front of the passenger com-partment, the engine com-partment and the rear end from the C-pillar to the rear were removed. Specially designed plastic components close off the cabin at these points.
The linear drive of the PRE-SAFE ® Demonstrator, which is similar to that of the Transrapid train system,
has a power consumption of 10 kW, is freely program-mable and also works in the opposite direction. This ena-bles various acceleration pro-files, and also a rear-end col-lision, to be demonstrated. The cabin can also be rotat-ed by 30 degrees around its vertical axis on its sledge to simulate an oblique impact. If the cabin is rotated by 90 degrees, the drive system can be programmed to pro-duce to-and-fro motion that gives the impression of tak-ing corners at high speed. ■
The cabin of the PRE-SAFE ® Demonstrator can be accelerated to up to 16 km/h by the linear motor
VARIOUS TRIP PROFILES CAN BE PROGRAMMED
A trip in the rear of the new S-Class is simulated in the
current PRE-SAFE ® Demonstrator. It enables the effects of this
anticipatory safety system to be experienced at first hand
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PRE-SAFE FACTS, FIGURES AND CURIOSITIES
120 MILLISECONDSThe powerful electric motor needs hardly longer than the blink of an eye to tension the belt. Forward displacement of the passenger can be reduced by up to 150 millimetres by the rever-sible belt tensioner (photo), which was used for PRE-SAFE ® for the first time.
2010For its preventive occupant protection system PRE-SAFE ® , Mercedes-Benz was one of the first automobile manufacturers to receive the “Euro NCAP Advanced” award introduced in 2010 to supplement the five-star rating scheme. Euro NCAP gives this accolade to systems that provide a “scientifically proven safety benefit” but are not yet included when calculating the ratings.
14 KILOGRAMMESWhen the reversible belt tensioners are activated as a precaution by PRE-SAFE ®, the feeling for the driver and front passenger is as if a weight of approx. 14 kg has been hung from the belt strap. Incidentally, it is possible to ascertain how often the belt ten-sioners have been activated. This is because counters installed in the belt tensioners re-veal how often the belt has been tensioned. Two to four precautionary tensionings per 10,000 kilometres are seen as normal. But if a car with this mileage has already record-ed 300 or 400 tensioning processes, the Mercedes-Benz experts can be fairly sure that its owner has absolved at least one driver safety training course with it.
400,000 KILOMETRES In order to optimise the recognition of situations, the new technology with the necessary measuring equipment was in-stalled in taxis during the development phase when PRE-SAFE ® was enhanced with DISTRONIC PLUS. In 2007 these vehicles covered over 400,000 kilometres in Stutt-gart city traffic. Dense stop-and-go traffic, fast and frequent lane-changes plus varying road surfaces with potholes and manhole covers provided ideal conditions for the developers to verify the algorithm.
3.5 DEGREESOccupants sitting upright are more efficiently restrained by the belt, and will meet the airbag at a better angle and time when it deploys. In the 2003 S-Class PRE-SAFE ® uses the electric actuator motors to repo-sition the front passenger seat. Fore-and-aft adjustment takes place at a speed of 22 mil-limetres per second, and the backrest angle is altered by 3.5 degrees per second.
DID YOU KNOW?
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RESTRAINT SYSTEMS HELP TO REDUCE THE RISK
OF INJURY TO VEHICLE OCCUPANTS. AGE-COM-
PATIBLE CHILD SEATS IDEALLY PROTECT
YOUNG PASSENGERS. AIRBAGS ARE ABLE
TO ABSORB HEAD AND BODY IMPACT RELATIVELY
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SOFTLY. SEAT BELTS ARE ABLE TO PREVENT
OCCUPANTS FROM BEING SUBJECTED TO EXCES-
SIVE ACCELERATION RATES IN AN ACCIDENT, OR
IN EXTREME CASES EVEN BEING THROWN FROM
THE VEHICLE.
REST
RAIN
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SAI
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SYST
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MOBILE NURSERYBABY KANGAROOS are born early and finish their development in
the safety of their mother’s pouch. Only at around six months will
the young kangaroo venture out into the world, but immediately
withdraw back into the pouch at the slightest sign of danger
Phot
o: M
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TAILOR-MADE SOLUTIONS
SMALL PASSENGERS, GREAT NEED FOR PROTECTIONIN AN ACCIDENT, THE RISK OF INJURY TO IMPROPERLY
SECURED CHILDREN IS SEVEN TIMES HIGHER THAN IF THEY
ARE PROTECTED BY RESTRAINT SYSTEMS. THIS IS BECAUSE
THE USUAL INERTIA-REEL SEAT BELT IS NOT IDEAL FOR
CHILD PROTECTION IN A CAR. FOR ANATOMICAL REASONS,
VERY YOUNG PASSENGERS REQUIRE TAILOR-MADE RESTRAINT
SYSTEMS. CHILD SEATS NEED TO MEET VARYING REQUIREMENTS
DEPENDING ON AGE GROUP, SIZE AND BODYWEIGHT.
RESTRAINT SYSTEMS CHILD SEATSRESTRAINT SYSTEMS CHILD
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RESTRAINT SYSTEMS CHILD SEATS
head of a newborn child accounts for around one quarter of its bodyweight, but only 18 percent for an adult. The bone structure is also different.
The logical conclusion: children need restraint systems that are precisely tailored to their age group, size and weight. Mercedes-Benz offers an infant seat and removable child seat models for children of differ-ent sizes.
The legal requirements for child seats applicable in Europe are laid down in ECE regulation no. 44. This
divides the areas of applica-tion into groups (see table). In parallel with this, the first child seats following the new I-Size standard are expected to be available from 2014. One of the re-
quirements of this standard is side impact tests and tests with the more sensitive Q-dummies – both are al-ready included in the strin-gent in-house requirements at Mercedes-Benz. ■
CHILD SEAT RECOGNITION AND ISOFIX Preventing incorrect operation
If a child seat is mounted on the front passenger seat, the seat’s airbag must be deactivated. Many car manufacturers have systems using the ignition key for deactivation. There is a problem with this: manual reactivation of the front passenger airbag is often forgotten when removing the child seat, which can seriously endanger adults during an accident.Mercedes-Benz has considerably reduced the risk of such incorrect operation. Because since 1997, Mercedes-Benz models have been optionally or regularly equipped with automatic child seat recognition. An aerial integrated into the front passenger seat sends out signals. Individual child seat models in the Mercedes-Benz accessories range are equipped with transponders which recognise these signals and send back a response. The automatic child seat recognition system then deactivates the front passenger airbag. When the child seat is removed, the front passenger airbag is automatically reactivated. Even more flexibility is possible with the automatic child seat recognition of the new C-Class, which dispenses with a transponder and uses a weight-sensitive mat. This means that any child seat can be used. Installation errors with child seats are prevented by Isofix. This inter-nationally standardised attachment system - which is standard equipment for the outer rear seats of all Mercedes-Benz passenger car models - also optimises protection thanks to a fixed connection between the child seat and the vehicle.
To give the best protection to the vulnerable neck vertebrae of an infant,
infant seats are installed against the direction of travel
In addition to meeting legal requirements, Mercedes-Benz child seats
must pass in-house tests such as a frontal impact at 64 km/h
Children are the most vulnerable road users – and not only when
travelling by scooter, bicycle or on foot. Because kids who are not adequately secured as car passengers are in great danger if an accident occurs. Their risk of being seriously or fatally injured is seven times higher than for children who are protected by suitable restraint sys-tems. In Germany in 2012, 10,356 children and adoles-cents aged under 15 years
were injured in passenger cars involved in accidents, and 34 killed, according to figures from the Federal Statistical Office.
A study published by the technical inspection organi-sation Dekra in May 2013 came to a shocking conclu-sion: almost one in ten chil-dren in Germany are either unsecured or inadequately secured when in the car. For its study Dekra exam-ined the restraint systems for adults and children in around 20,000 vehicles throughout Germany.
The fact that an adult seat belt is not ideal for child protection is due to the pecu-liarities of a child’s anatomy. This is because adults and children not only differ in size and weight, but also in physiology and physical pro-portions. For example, the
A SUITABLE SEAT FOR EVERY AGE GROUP
The sensor system for the front passenger airbag
of the new C-Class is able to recognise any installed child
seat. The airbag is then automatically deactivated, and
reactivated when the child seat is removed
WHICH SEAT FOR WHOM?
ECE group Body weight Age
Group 0 up to 10 kg ca. 9 months
Group 0+ up to 13 kg ca. 18 months
Group I 9 to 18 kg ca. 8 months to 4 years
Group II 15 to 25 kg ca. 3 to 7 years
Group III 22 to 36 kg ca. 6 to 12 years
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RESTRAINT SYSTEMS AIRBAGS
HARD IMPACT, SOFT LANDING
BLOW UPTHE AIRBAG ENTERED SERIES PRODUCTION AT MERCEDES-BENZ OVER 30 YEARS AGO. SINCE
THEN THIS RESTRAINT SYSTEM HAS UNDERGONE CONTINUOUS IMPROVEMENTS: NEW
TYPES OF AIRBAG THAT ALSO PROTECT DURING SIDE IMPACTS, AS WELL AS ADAPTIVE SYSTEMS
THAT RESPOND ACCORDING TO THE SEVERITY OF AN ACCIDENT, WERE INTRODUCED.
In March 1981 Mercedes-Benz was the world’s first automobile manu-
facturer to present the air-bag and belt tensioner to the public as restraint systems in a series production car. With the debut of the 126- series S-Class, Mercedes-Benz began the gradual
introduction of the airbag as a Passive Safety feature into the entire passenger car range: by 1982 the airbag and belt tensioner were al-ready available as an option-al extra for all Mercedes-Benz passenger cars. By 1992 the driver airbag was standard equipment in all Mercedes-Benz models, the front passenger airbag fol-
lowed as a standard safety feature in 1994, and after-wards Mercedes-Benz real-ised numerous other applica-tions for airbag technology.
Research into the airbag began as early as 1966 at Mercedes-Benz, and practi-cal trials began in 1967. This was a response by the com-pany to the heavy increase in accident figures during
RESTRAINT SYSTEMS AIRBAGS
The driver airbag deploys
within a few milliseconds
during a severe frontal impact
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RESTRAINT SYSTEMS AIRBAGS
the 1960s. Research into the new restraint system was given a further impetus by a plan in the USA to prescribe an automatic occupant pro-tection system for every car from 1969 onwards. Airbags were seen as a very promis-ing technology with which new legal requirements could be met.
The principle of the air-bag that protects the driver and passengers in an acci-dent was already patented in the 1950s. The pioneers were above all the German Walter Linderer (patent no. DE 896312 of 6 October 1951) and the American John W. Hedrik (patent no. US 2649311 of 18 August 1953).
For more than ten years the “inflatable container in a folded state, which automati-cally inflates in cases of dan-ger” (Linderer’s description of his invention in the patent application) now became an object of research with the aim of achieving series pro-duction maturity. The work by Mercedes-Benz engineers and their colleagues em-ployed by other automotive brands and suppliers in the 1960s was initially just fun-
damental research. This is because technology with which the idea from the 1950s could be realised in a passenger car did not exist.
Especially the necessary sensors and gas generation continued to pose a serious challenge for the engineers. When American manufac-turers began to deliver the first test car fleets with com-pressed air operated airbags, which were conceived as an alternative to the seat belt, these restraint systems sometimes led to serious in-
juries and in a few cases even fatalities. For this rea-son the initially very urgent call for passenger cars to be equipped with airbags as standard in North Ameri-ca was postponed further and further. Meanwhile Mercedes-Benz in Stuttgart was working on an airbag technology that was differ-ent in many respects: the safety specialists at Mercedes-Benz put their faith in propellant charges
AIRBAG How the cushion works
Airbag: folded tightly and lubricated against conglutination by talcum powder, the airbag made out of Nylon texture is stowed within the steering wheel boss. The talcum powder by the way is responsible for the ”smoke“ seen after an airbag is activated
Gas generator: airbags use tablets made of sodium azide as propellant. After the ignition, they react to finally form nitrogen gas filling the airbag. Vent holes ensure a controlled deflation
Initiator: a current pulse sent by the control unit activates the electric match which in turn ignites the propellant. The initially hot gas (approx. 1,350° C) is cooled by the expansion to about 150° C
Signal from the control unit: airbags are activated by a central Airbag control unit (ACU). the unit gets its information by various sensors in the vehicle. The most important criteria measured is deceleration
THE MID-60S ALREADY SAW THE START OF AIRBAG TESTS
Patent: as early as 23 October 1971, the then
Daimler-Benz AG patented the airbag – as an
“impact protection device”. The mathematical
calculations followed much later
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RESTRAINT SYSTEMS AIRBAGS
to generate the gas, not gas stored under pressure. Neither was the airbag de-veloped as a stand-alone restraint system, but always as a component working together with the seat belt. This is expressed by the abbreviation SRS (Supple-mental Restraint System) used internationally for air-bags. By 1970 Mercedes-Benz was able to report the following about its crash test findings in a letter to a
German motoring magazine: “The effectiveness of the airbag system in conjunction with a lap belt and head-rest in both frontal and rear-end crashes can be described as good.”
From 1967, practical experiments began using chemicals to generate the gas, similar to the solid fuels used to power rockets. In contrast to gas-filled car-tridges, this form of propel-lant charge proved a reliable and fast gas generator. The resulting gas mixture con-sists mainly of nitrogen, and in fractions of a second in-flates the airbag made from a specially woven fabric to form a soft cushion that catches passengers as they
INTERACTION BETWEEN SEAT BELT AND AIRBAG
THE AIRBAGS in the new S-Class
The driver airbag (volume approx. 64 litres) is equipped with a two-stage gas genera-tor. Two performance stages can be activated depending on the detected vehicle de-celeration rates, with a time delay between ignition of the first and second stages.
As a special feature, the front passenger airbag (volume approx. 112 litres) has a pyrotechnically activat-ed adaptation stage in addi-tion to the two-stage gas gen-erator. The damping effect on the occupant during immer-sion into the airbag is strong-er or weaker as required, depending on seating position and level of inflation.
The thorax-pelvis side-bags for the driver and front passenger have a volume of 17 litres and are integrated into the front seat backrests.
In the USA the kneebag for the driver is standard equipment. In a frontal collision it is able to re-duce loads on the driver’s lower extremities, and is favourable for the overall body kinematics.
The sidebags in the rear with a volume of 12 litres are integrated into the bodyshell in the area of the rear interior side panels.
The windowbag (volume approx. 40 litres) is inflated by a gas generator located in the roof area behind the B-pillar in the event of a crash. The windowbag case is more robust thanks to the use of a new weaving technique (X-Tether technology): this makes for more taut inflation over a longer period.
If the S-Class is equipped with the Executive seat (reclining seat), the seat includes the innovative cushionbag as standard. The airbag is located un-der the seat cushion up-holstery of the Executive seat, but on top of the plastic seat shell. In the seat’s reclining position it prevents the occupant from sliding under the belt in the event of an accident (so-called submarining). This is because it raises the front section of the seat cushion upholstery.
The beltbag is an inflatable seat-belt strap that is able to reduce the risk of injury to passengers in the rear in a head-on collision by lessening the strain placed on the ribcage (for details see page 79).
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RESTRAINT SYSTEMS AIRBAGS
are flung forward by an impact.
The key findings from the early tests were incor-porated into patent no. DE 2152902 C 2, which the then Daimler-Benz AG filed on 23 October 1971. This patent application is a key document covering the entire airbag development process at Mercedes-Benz. This is because it already describes the operating prin-ciple of the new technology as it was to be realised in series production ten years later: Sensors register the particularly heavy decelera-tion that typically occurs
during impacts, and trigger the airbag mechanism. This fires a propellant charge (at the time using sodium azide, potassium nitrate and sand), which mainly turns into
gaseous nitrogen plus a little water and oxygen when it explodes. As the series of tests soon showed, the air-bag only really reaches its full performance potential in combination with the seat belt.
In 1992 the driver air -bag, and in 1994 the front passenger airbag, became standard equipment in every Mercedes-Benz passenger car. Because the airbag mod-ules were becoming increas-ingly smaller thanks to con-stant improvements by the engineers, they could also be placed in other locations in the vehicle to provide comprehensive protection even in lateral collisions: in 1993 Mercedes-Benz pre-sented the sidebag as a de-sign study, and in 1995 the sidebag was launched as an optional extra initially for the E-Class. From 1998 the
MORE AND MORE AIRBAGS COMING INTO USE
SLOWED DOWN Braking Bag
The Experimental Safety Vehicle ESF 2009 (see page 36 f.) demonstrates one spectacular example of how airbags might be used in the future: the “Braking Bag” concealed in the vehicle floor can become an auxiliary brake. If the sensors and control unit predict that an impact is certain, the “Braking Bag” is deployed just before the collision and supports the vehicle against the road surface with its friction coating. The brake dive of the vehicle increases the friction and has an additional braking effect up to the impact.
In 1998 Mercedes-Benz was the first automobile manufacturer to introduce the windowbag. Both the front and rear occupants benefit from this large-area head protection, as this study by Mercedes-Benz accident research shows. An analysis of real accidents shows that the windowbag considerably reduces the severity of injuries: the pro-portion of severe injuries and fatalities in side collisions is reduced from 55 % to 25 %.
THE WINDOWBAG as a protective curtain
To make sure that airbags only deploy in an accident,
and on no account by mistake, Mercedes-Benz intensively
test them with so-called misuse tests. Here is an SLS AMG
in a simulation of mounting a kerb
Comparison of injury severity at a side collision, belted passengers on impact side with and without window-bag
Fatalities
Severely Injured
Lightly Injured
Not Injured
No windowbag Windowbag activated
Percent
Source: DBCars, Dec. 2007
100
80
60
40
20
0
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RESTRAINT SYSTEMS AIRBAGS
windowbag became stand-ard equipment initially in the S-Class. In 2001 the head-thorax sidebag was in-troduced for the roadsters in the Mercedes-Benz SL-Class.
Adaptive front airbags had their debut in the W 220-series S-Class (1998). In the new S-Class genera-tion (2013) this restraint system configured according to accident severity is a ma-jor further development: the driver airbag is equipped with a two-stage gas genera-tor. Two performance stages can be activated depending on the detected vehicle de-celeration rates, with a time delay between ignition of
the first and second stages. As a special feature in addi-tion to the two-stage gas generator, the front passen-ger airbag has a pyrotechni-cally activated adaptation stage. The damping effect when the occupant is im-mersed in the airbag is stronger or weaker as re-quired, depending on seat-ing position and level of inflation. ■
ADAPTIVE AIRBAGS RESPOND TO THE IMPACT SEVERITY
Principle: using analogies in the structure of an egg and
the human body, Ferdinand Gaiser helps children
to understand the workings of the airbag and crash tests
YOUNG RESEARCHERS Traffic safety education
Over 30 years have passed since the world premiere of the airbag at Mercedes-Benz. Meanwhile the number of airbags installed in vehicles has constantly increased, and the advances in sensor sys-tems, gas generators and airbag covers have been immense. Yet nothing about the principle of the “Impact protection device for the occupants of a motor vehicle” (to quote the Daimler patent of 1971) itself has changed to this day. Head of crash testing Ferdinand Gaiser, who enjoys passing his passion for technology and his safety awareness on to children and adolescents, has developed a special “egg-protection system” that helps them to understand the principle of the airbag. At interac-tive technical shows or as part of school holiday programmes, he uses analogies in the structure of an egg and the human body to ex-plain to young people how airbags and crash tests work. At the same time Gaiser is making a contribu-tion to traffic safety education.
7776
RESTRAINT SYSTEMS SEAT BELT
NUMBER ONE LIFESAVER
A BOND FOR LIFETO THIS DAY THE SEAT BELT REMAINS ONE OF THE MOST IMPORTANT IN-CAR SAFETY
SYSTEMS, AS IT REDUCES THE LOADS ACTING ON THE WEARER DURING AN ACCIDENT.
BELT TENSIONERS AND BELT FORCE LIMITERS HAVE PERFECTED THIS PROTECTION.
seat belt, as a survey by the Federal Office for Roads and Traffic (BASt) for 2012 shows. There are only minor differences between rates of use for drivers, front passengers and other pas-
sengers, or for different road categories, and these have remained almost constant compared to the previous year.
An encouraging develop-ment, as passengers not
wearing a seat belt run a high risk of injury even at moderate inner-city road speeds: even during a fron-tal impact at 30 km/h, the acceleration forces acting on the occupants are so high
Most people now use their seat belt: at present around
98 percent of all car occu-pants in Germany wear their
Seat belt straps are manufactured
from up to 300 interwoven threads.
Each thread consists of over 100
extremely fine polyester filaments
Self-testing by brave Daimler engineers:
whether on the seat belt sledge …
… or in the vehicle, the belt is tested personally
if there is no dummy available
A layer of foam material simulates a winter jacket
in the belt tensioner test
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RESTRAINT SYSTEMS SEAT BELT
that they are unable to ab-sorb the impact with their arms. And an occupant with-out a fastened seat belt who suffers a collision with a fixed object at 50 km/h is subject to a force that corre-sponds to jumping from a fourth-floor window and falling twelve metres.
Rear seat passengers not wearing a seat belt can be-come projectiles in an acci-dent, as they are flung for-ward at 30 to 50 times their weight. This means that a 70 kg adult on a rear seat who is not strapped in builds up a load of around three tonnes during an impact at
50 km/h – the weight of a young elephant.
Seat belts fulfill two ma-jor functions: They prevent the occupants from being thrown from the car in an accident. They also help to
protect passengers from excessive rates of accelera-tion, and can prevent body areas from impacting vehi-cle components. In 1985 the German Patent Office nomi-nated the seat belt as one
of eight inventions that have brought most benefit to mankind in the last 100 years. Estimates suggest that seat belts have saved the lives of over one million people worldwide.
Seat belt straps are manu-factured from up to 300 interwoven threads. Each thread consists of over 100 extremely fine polyester fila-ments. These filaments have a thickness of 250 to 400 mi-crometres, and are therefore about twice as thick as a human hair. Around 30,000 metres of filament are used per metre of belt strap - re-sulting in an overall length
INFLATED Beltbag in the rear
Should the crash sensors detect a severe frontal impact, the airbag control unit triggers de-ployment and inflation of the beltbag. A gas generator then inflates the multi-layered belt strap with Velcro seams to near-ly three times its normal width. By better distributing the forces acting on the rear seat occupant, the beltbag reduces the risk of injury in a frontal collision.
RAISED Belt buckle extender
An electric motor automati-cally raises and retracts the belt buckle. This reduces any belt slack in the area of the pelvis and thorax, so that passengers are secured more firmly. Fastening the seat belt is also made easier. If PRE-SAFE ® is activated in critical driving situations, there is also reversible belt tensioning in the rear via the active belt buckle.
SERVED Belt feeders in the front
An active belt feeder (e.g. in the E-Class Coupé and Cabriolet) makes it easier to fasten the seat belt. As soon as the ignition key is turned to position 1 and the seat belt is not inserted in its buckle, an electric motor extends plastic sections out of the rear side panels and bring the belt into a convenient position. When the seat belt has been fastened, the feeder retracts again. The automatic belt feeders for the driver and front passenger can also be operated by a button in the centre console.
LIFE-SAVER FOR ONE MILLION PEOPLE
80 81
RESTRAINT SYSTEMS SEAT BELT
of around 450 kilometres per vehicle. A thermofixing process after weaving en-sures that the belt has cer-tain predefined properties, such as maximum elonga-tion. During thermofixing
the belt straps are heated to over 200 degrees Celsius, then cooled down. The dura-tion and tension are precise-ly specified.
The seat belt, which re-mains the main occupant protection component in modern cars, is already over 110 years old: Gustave Désiré Lebeau was the first to register a patent for it in Paris on 11.05.1903. The Frenchman used crossed-over leather straps to secure the occupants of automobiles. Safety pioneer Mercedes-Benz first present-ed this new Passive Safety feature in 1957 - “Restrain-ing belt as used in aviation” was the description given to the lap belt for the open-top Mercedes-Benz 300 SL (W 198 II) optionally available from 1958. In that same year Mercedes-Benz offered com-parable seat belts for all pas-senger car models with indi-vidual front seats.
Following the introduc-tion of the seat belt as an op-tional extra, Mercedes-Benz continuously developed this restraint system further. The first versions were still lap
belts attached to the vehi-cle’s bodyshell, and they had to be individually adjusted to fit each passenger. While this was awkward, it provid-ed better protection in an accident than having no belt at all. The customers who became convinced about the new system included the West German Chancellor, Konrad Adenauer. He had a lap belt installed in the rear of his Mercedes-Benz 300.
By the end of the 1960s the three-point seat belt had prevailed as the final form for passenger cars, combin-ing a lap belt with a shoulder belt. When a retraction reel was added, it became the inertia-reel seat belt. In 1973 Mercedes-Benz included this form of seat belt as standard equipment for all front seats. In 1979 the installation of three-point inertia-reel seat belts for the rear seats also became standard.
Even in the 1970s, the accident researchers at Mercedes-Benz were aware that during a severe frontal impact, the seat belt cannot always prevent the head and body from impacting the steering wheel and dash-board. The reasons for the limited protective effect were looseness (“belt slack”), stretching and the time delay of the inertia-reel device (“film-roll effect”).
In 1981 (standard from 1984), Mercedes-Benz engi-neers prevented the inherent free travel of the belt with the belt tensioner, which rolls up and tightens the belt within milliseconds in a crash. In 1995 Mercedes-Benz presented the integrat-ed belt force limiter. This limits the force exerted on the occupant by the belt during severe impacts (for details of belt tensioner and
belt force limiter see oppo-site page). Unlike in the case of many other manufactur-ers, the belts in the rear of a Mercede s-Benz likewise fea-ture belt tensioners and belt force limiters.
The protective action of the seat belt was finally perfected with the airbag (from 1981), and the innova-tive, preventive safety sys-tem PRE-SAFE ® (2002): When the PRE-SAFE ® sen-sors recognise the danger of an accident, the system uses electric motors to pre-ten-sion the belt tensioners and build up the maximum pro-tective effect of the seat belt (see page 44/45). In 2013 Mercedes-Benz enhanced the safety system for passen-gers in the rear even further with the belt buckle extend-er and the beltbag in the new S-Class. ■
SEVERAL HUNDRED ULTRA-THIN THREADS OF POLYESTER
INTEGRAL SAFETY CONCEPT WITH AIRBAG AND PRE-SAFE®
INERTIA-REEL BELT STANDARD SINCE 1973 AT MERCEDES-BENZ
TO MAKE SURE THE BELT LETS GO WHEN IT SHOULD
This inertia reel combines a belt tensioner with a belt force limiter. At Mercedes-Benz this version is used in the rear, and in some cases the inertia-reels in the front additionally have reversible PRE-SAFE® func-tions.Operating principle: There are steel balls inside the bent tube. When the belt tensioner is triggered, a pyrotechnical charge is activated. The steel balls transfer their kinetic energy to a gear wheel mounted on the shaft of the seat belt retractor. Accordingly the belt is retracted by up to 15 centimetres and is taut against the occupant’s body.To avoid dangerous peak loads, the belt force limiter comes into operation. Once a certain force has been reached, the shaft inside the belt retractor is twisted on the torsion principle. This causes a controlled re-lease of the belt strap.
Belt strap
Shaft
Seat belt retractor
Pyrotechnical charge
Steel balls
8382
RESTRAINT SYSTEMS FACTS, FIGURES AND CURIOSITIES
8 BILLION EUROWhen rear-end collisions occur, whiplash injuries can be caused by rapid, alternating fore-and-aft movements of the head and overstressing of the cervical vertebrae. According to estimates by the EU Commission, this leads to annual costs amounting to around eight billion euros. Mercedes-Benz reduces this injury risk with appropriately designed head restraints. The basic requirement for this is best possible adjustment of the distance from the back of the occupant’s head. This is quite simple in the case of the A-Class, for example: the head restraint can simply be pulled forward until it engages. There are different engagement positions. If the head restraint is to be adjusted to the rear, the release button must be kept depressed while the restraint is pushed rearwards. When the head restraint has reached the desired adjustment, the button can be released and the restraint snaps into position.
AUTO
2000In 1981 the Mercedes-Benz “Auto 2000” research vehicle defined the status of safety technology. Its innovations included integral seats for the driver and front passenger, where all the belt attachments were mounted directly on the seat, and an integrated child restraint system.
15 BIRDS
An animal experiment like this would be unthinkable nowadays, but in the early phase of airbag development the Mercedes-Benz researchers had recourse to unusual methods: to find out what effects the gas emissions have after activation of the airbag, the technicians deposited a cage containing 15 canaries in a test vehicle. The airbag was then triggered. The birds survived the experience completely unruffled. Incidentally, the engineers tested the effect of the bang on themselves, under the supervision of an ENT specialist.
SECTION 34In Germany the trade supervisory authorities prescribe that every car workshop handling airbags and belt tensioners must nominate a trained specialist who is responsible. According to Section 34, clause 2 of the explosives law, this person must be in possession of a certificate of competence. This requires attendance at a usually 1-day seminar where specialist knowledge on pyrotechnical systems is imparted.
1976Men feared for their freedom, women for their busts: Although it became mandatory to wear a seat belt in West Germany on 1 January 1976, the seat belt was the subject of passionate debate in the mid/late 1970s. Horror stories did the rounds about cars on fire or submerged under water, from which occu-pants wearing seat belts were unable to escape. In December 1975 the news magazine “Spie-gel” even devoted its cover story with the title “Strapped to the car” to these various fears. Only the fine imposed for non-use in 1984 convinced the skeptics and greatly increased the rate of use.
DID YOUKNOW?
Photo: enens - Fotolia.com
84 858584 8584
STABLE DYNAMICSPOLAR BEARS can reach a weight of up to 800 kg and
move at over 40 km/h. But they keep a grip on things even
where the going is slippery: the soles of their feet have a
dense covering of hair, making it harder to slip over on the
ice. All four paws are armed with five non-retractable claws.
THE BASIS FOR MANY ASSISTANCE SYSTEMS
ARE THE HANDLING SAFETY SYSTEMS ABS AND ESP®. NUMER-
OUS OTHER HELPERS SUCH AS BAS, LANE KEEP-ING AND BLIND SPOT ASSIST NOWADAYS
MAKE DRIVING SAFER AND MORE COMFORTABLE. THESE
ALSO INCLUDE COLLISION PREVENTION ASSIST AND THE RECOGNITION OF TRAFFIC SIGNS.
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8786
ASSISTANTS ABS/ESP
Extreme trials in Namibia: with six driving
modes, the suspension of the M-Class is
ready for any situation. One example is Offroad
ABS. It optimises the braking characteristics,
especially on loose substrates
CONTROLLED VEHICLE DYNAMICS
THE CAR ASSISTS THE DRIVEROUTSTANDING DRIVING SKILLS WERE REQUIRED TO KEEP THE VEHICLE ON COURSE IN
EXTREME CONDITIONS. UNTIL MERCEDES-BENZ INTRODUCED FIRST ABS AND THEN ESP®.
NOWADAYS BOTH ARE LEGAL REQUIREMENTS, AND DRIVING IS SAFER IN MANY RESPECTS.
88 89
ASSISTANTS ABS/ESP
ANTI-LOCK BRAKING SYSTEM Braking without skidding
When tyres start smoking, cars start skidding: what can still be seen in Formula 1 today was the norm for every regular production car 35 years ago. Hard braking brings the wheels to an abrupt stop, the braking distance increases and the vehicle can no longer be steered. This only changed in 1978: The 116-series S-Class was the first automobile worldwide that could be ordered with fully electronic ABS. Since 2004 all new cars in Europe have been equipped with this technology.
It all started with wheels that locked when brak-ing. The problem was
this: the vehicle cannot be steered if the wheels are locked, as they transfer lateral forces to the road less effectively than rotating wheels. As early as the second half of the 1950s, Daimler examined the use of anti-lock braking systems familiar from aviation in its vehicles, however these proved unsatisfactory. In 1963 the company began to develop in-house compo-nents for an electronic/ hydraulic control system capable of higher perfor-mance. In 1966 the Teldix company, which was later
taken over by Bosch, became a development partner. By the end of 1970 the goal seemed to have been sub-stantially reached: Daimler issued invitations to a “press demonstration” on 9 Decem-ber, and the Executive Board member for development, Hans Scherenberg, ex-plained the current status.
“During panic braking, strong drivers in particular apply a higher level of brake pressure, which causes one or more wheels to lock. If the vehicle is virtually unladen or the road surface is slip-
DRIVING STRAIGHT AHEAD ON A BEND IS VERY DANGEROUS
When the wheels lock up: ABS was also tested with the /8 as the precursor to the E-Class. This bestseller never enjoyed the benefit of ABS, however
Hard going: rapidly changing road surfaces with varying levels of grip are an extreme challenge for the control quality of ABS
Premiere: from 1978 the S-Class was kept on course by ABS
In the past: without ABS the driver had a tough job Safe avoiding action: vans were also included in ABS development work at an early stage
90 91
ASSISTANTS ABS/ESP
More safety at the cornering limits: if the ESP® sensors register a tendency to understeer, the stability programme initiates specific braking intervention at the inside rear
wheel. This causes a slight yawing motion around the vehicle’s vertical axis. The effect: the vehicle steers into the bend precisely and with no loss of power
pery, however, very little pedal pressure is needed before locking occurs, and steerability and handling stability are lost. Metering the pedal pressure during emergency braking there-
fore requires awareness, experience and self-control on the part of the driver, however this is often lack-ing. Acting purely on in-stinct, many drivers apply the brakes with full force in such situations, rather than metering the braking action
in accordance with the cir-cumstances.”
Scherenberg described the consequences: “If the front wheels lock while the rear wheels are turning nor-mally, the vehicle travels straight ahead whatever the current steering angle… On a straight road this behav-iour is relatively favoura-ble…, but as we know, driv-ing straight ahead on a bend is very dangerous. If the rear wheels lock, however, …the vehicle can easily break away at the rear axle be-cause locked wheels lose their lateral stability.”
In his presentation, Sche-renberg mentioned a period of two years before the intro-
duction of the Anti-Block System (A-B-S). In fact ABS, developed together with Bosch and now in its 2nd generation, only reached production maturity eight years later. It had its world premiere in the S-Class in 1978. In 1974 the change-over from analogue to digital electronics began. It was on-ly the invention of integrated circuits that made it possible to build small, robust com-puters that were capable of converting the data from the wheel sensors into e.g. accel-eration data in minimum time, and of consistently and reliably actuating the valves controlling the brake pres-sure. Moreover, no more me-
ABS DEVELOPMENT TO PRODUCTION MATU-RITY TOOK 15 YEARS
Full range of choices:
the AMG DRIVE UNIT in the
SLS AMG enables the suspension
control systems to be set up
according to the driver’s wishes
and for the intended purpose,
right up to Race Control set-up
for the racetrack
BASIC FUNCTION ESP ® In case of understeer
TORQUE VECTORING BRAKE Specific braking action for dynamic cornering In case of oversteer
Without ESP ® The car does not turn enough and leaves the road
Without ESP ® The car turns more sharply than intended and possibly spins. The driver needs to countersteer.
With ESP ® ESP® assists the steering reaction of the driver by applying the brakes at the rear inside wheel
With ESP ® ESP® assists the driver by applying the brakes at the outside front wheel
Vehicle’s Intended without with ESP ® Torque about the center course ESP ® ESP ® brake vehicle’s vertical axis, of gravity application created by brake application
92 93
ASSISTANTS ABS/ESP
chanical rotating mass sen-sors were used, as the wheel acceleration and rpm were now calculated purely elec-tronically from the rpm sensor signals.
During the development work it soon became clear that not only the wheel ac-celeration but also the wheel slip must be taken into the equation: to this day, this combination is the basis for all dynamic control systems.
A control unit processes the sensor signals, the hydraulic unit instantly and precisely regulates the brake pressure at each wheel. In 1984 all Mercedes-Benz passenger cars were given ABS as standard, and ten years after its introduction no less than one million Mercedes-Benz cars with ABS were on the roads worldwide. As a volun-tary obligation by the Euro-pean automobile industry, all passenger cars have been equipped with ABS as stand-ard since 1 July 2004.
Mercedes-Benz also took on the pioneering role in the commercial vehicle sector. ABS for compressed air brakes, a joint development with WABCO, already be-came available in 1981. Since 1986 the brand’s large touring coaches have been equipped with ABS as stand-ard, and since 1991 also its truck models.
The next step was acceler-ation skid control (ASR),
which became available in the S-Class (W 126) models with V8 engines from 1985. When the wheel sensors detect that drive wheels are spinning, the engine torque is reduced and/or the spin-ning wheel is slowed down by the wheel brake (ETS). This was followed by the automatic locking differen-tial (ASD) and automatically activated 4MATIC all-wheel drive, both of which ap-
peared in the great innova-tion year of 1985.
Additional sensors that recognise the driver’s direc-
tional intentions (steering angle sensor) and whether the car is sliding sideways (lateral acceleration sensor),
or is in the process of rotat-ing around its own vertical axis (yaw rate sensor), pro-vided the basis for the elec-tronic stability programme ESP® (see diagram on page 91 for operating principle). An engineer’s dream and a further, major step towards reducing accident figures had become reality: for the first time, the technology ef-fectively supported drivers in situations where they
WHEN AN ELK BLOCKS THE ROAD All’s well that ends well
After ABS and acceleration skid control ASR, Mercedes-Benz went a stage further in 1995 and introduced ESP® in the luxury S 600 Coupé. From then on, the electronic stability programme held a protective hand over drivers at the physical lim-its. These were exceeded by a Swedish car tester, who caused the new compact A-Class to capsize during an abrupt evasive manoeuvre (“Elk test”). What at first seemed a humiliation for Mercedes-Benz became a triumph: in 1997 the company systematically made ESP® standard equipment – first for the A-Class, then for all its models. All the other manufacturers had to follow suit: following a directive by the European parliament and the Council dated 13 July 2009, it has been mandatory to equip all passenger cars newly registered in the EU with ESP® as standard since November 2011.
ONLY DIGITAL ELECTRONICS MADE ABS POSSIBLE AT ALL
NEW SENSORS RECOGNISE THAT THE CAR IS SKIDDING
Bus at the physical limits: today ESP® also ensures greater safety in the Citaro1969 test: it soon became clear that both wheel acceleration and slip must be registered by sensors
ESP® enters series production: In 1995 Mercedes-Benz demonstrated on snow… …how much easier the S 600 Coupé could be controlled with ESP®
Trendsetter rather than laughing-stock: the A-Class was given ESP® as standard from 1998
94 95
ASSISTANTS ABS/ESP
ACTIVE CURVE SYSTEM The M-Class serenely copes with any terrain
Driving straight ahead: Comfort is improved, as the rotary actuators decouple the two halves of the front and rear anti-roll bars in this situation, meaning that the anti-roll bars are “open” and do not react to a stimulus on just one side, such as bumps or potholes.
Cornering: Improved ride comfort and vehicle dynamics, as the torsional moments and angles of the stabilisers are actively influenced. Moreover, the torsional moment of the stabilisers also remains constant with one-sided stimuli, for example when crossing a pothole on the outside of the bend. The different control at the front and rear axles variably distributes the body roll.
Off-road: On extreme terrain at low speeds, the actuators decouple the two transverse stabilisers at the front and rear axles. This allows a higher degree of axle articulation, and therefore ground adhesion.
ACTIVE CURVE SYSTEM Less roll
The active roll stabilisation ACTIVE CURVE SYSTEM can be combined with both the AIRMATIC air suspen-sion system with adaptive damping system (ADS) and with the ON&OFFROAD package. The system operates on the front and rear axle with active an-ti-roll bars, and controls these automatically depend-ing on the lateral acceleration, the road speed and the position of the ADS Comfort/Sport switch. Compensating the body roll angle when cornering increases both agility and driving pleasure.
were on the verge of losing control. In 1995 ESP® was first introduced as standard in the S-Class.
“If all cars were equipped with the stability pro-gramme, more than 20,000 of these serious accidents with over 27,000 accident victims could be prevented in Germany,” said Prof Dr Thomas Weber, the Daimler Board of Management mem-ber for research and technol-ogy, and head of develop-ment for Mercedes Car Group. “Alongside the seat belt, airbag and ABS, ESP® is easily the most important
safety system in modern passenger cars.” His wish was to come true: ESP® has been mandatory for new cars in Europe since November 2011.
In 1996 Brake Assist (BAS) followed as a standard feature for all Mercedes-Benz passenger cars. During emergency braking, this ensures that the most effec-tive brake pressure is built up immediately, irrespective of the driver’s pressure on the brake pedal. You will read more about Brake Assist PLUS (BAS PLUS) in the next chapter. ■
Staying safe throughout winter: control
of the Mercedes-Benz all-wheel drive system
4MATIC is also based on the ESP® sensors.
The 4x4 family from Mercedes-Benz current-
ly comprises over 60 models.
Free choice: with six driving modes, the ON&OFFROAD package in the ML and GL optimises vehicle dynamics and safety
96 97
ASSISTANTS BAS PLUS
Accident black-spot: accidents at junctions will often be avoidable in future, thanks to recognition of crossing traffic
Emergency: automatic emergency braking and activation of the PRE-SAFE® systems can mitigate the consequences of accidents
NEW ASSISTANCE SYSTEMS
RECOGNISING DANGER, SUPPORTING THE DRIVERPREVENTING ACCIDENTS AND MINIMISING THEIR CONSEQUENCES: MERCEDES-BENZ
SYSTEMATICALLY PURSUES THIS STRATEGY WITH NUMEROUS NEW ASSISTANCE SYSTEMS.
COMFORT AND SAFETY ARE ENHANCED AT THE SAME TIME. THE PRINCIPLE HERE IS:
AS MATURE AS THE SYSTEMS ARE – THE DRIVER ALWAYS RETAINS CONTROL, ALSO FOR
LEGAL REASONS. THE DRIVER SHOULD BE SUPPORTED, NOT SIDELINED.
RECOGNITION OF CROSSING TRAFFIC Help in dire emergencies
The latest generation of sensors (long and short-range radar, stereo multifunction camera) is also able to recognise crossing traffic and oncoming traffic. Objects recognised include e.g. trucks, cars, motorcycles and bicycles. If critical situations involving crossing traffic are detected, BAS PLUS makes the necessary brake pressure available as soon as the driver brakes. In addition, PRE-SAFE® functions such as the belt tensioners are activated.
Mercedes-Benz driv-ers first received assistance with
emergency braking in 1996, from Brake Assist BAS: Full braking performance is available as soon as the brake pedal is operated. Over several development stages, BAS became Brake Assist PLUS (BAS PLUS). This automatically calculates the brake pressure neces-sary to prevent a crash. How-ever, no more brake pressure than necessary is applied, so
that traffic following behind also has space for braking. By the interaction of all its components, this adaptive pre-control of the braking system based on anticipatory sensors is a further innova-tion optimising vehicle de-celeration in hazardous situations.
BAS PLUS also goes into action if PRE-SAFE® Brake is on board. A visual and acoustic warning is given if the danger of a collision is recognised. If the driver reacts and operates the brake pedal, BAS PLUS takes
over and provides the opti-mum brake pressure. If the driver fails to respond to the visual and acoustic warning, PRE-SAFE® Brake first initi-ates partial braking. If a collision is recognised as unavoidable, there is emer-gency braking to mitigate the consequences.
The current development stage of Brake Assist BAS PLUS from Mercedes-Benz, which has initially been pre-sented in the S- and E-Class, and is available in the new C-Class, is now not only able to support the driver in con-
98 99
ASSISTANTS BAS PLUS
Brake Assist PLUS (BAS PLUS) calculates the brake pressure necessary to prevent a rear-end collision. Additional protec-tion is provided by the innovative PRE-SAFE® Brake from Mercedes-Benz: when an imminent rear-end collision is detected, it prompts the driver to act by means of visual and acoustic signals. If the driver fails to act, autonomous partial braking gives a further warning and the vehicle speed is reduced. If there is still no driver response, the system is able to initiate emergency braking before the now unavoida-
ble impact, thereby greatly lessening its severity. The latest generation is not only able to recognise vehicles ahead, but also pedestrians. The system makes use of information from the radar system and stereo camera. PRE-SAFE® Brake with pedestrian detection and city braking function is active at speeds up to 72 km/h and is able to prevent accidents with pedestrians as well as with stationary vehicles up to a speed of more than 50 km/h.
BAS PLUS AND PRE-SAFE® BRAKE Electronic crumple zone
approx. 72 km/h. BAS PLUS is able to aid the driver in linear situations at any speed.
Brake Assist BAS PLUS with Cross-Traffic Assist is potentially able to either pre-vent or lessen the severity of around 27 percent of all
accidents at road junctions resulting in injury. In Ger-many this corresponds to around 20,000 accidents per year.
As an automobile manu-facturer who has always also
played a decisive role in the commercial vehicle sector, Mercedes-Benz makes inno-vations available across all vehicle classes: Anti-lock braking system, acceleration skid control, disc brakes all-round, electronically con-trolled braking system, high-pressure braking sys-tem, Brake Assist, Lane Assistant, roll control, dis-tance control – the list of safety technologies that cele-brated their world premiere in trucks and buses from Mercedes-Benz is a long one. One of the development highlights is the revolution-ary Active Brake Assist (ABA). Introduced in 2006 in the Mercedes-Benz Actros
heavy truck, it has since proved highly successful in practice.
In 2012 the new Mercedes-Benz Actros, and also its distribution-oriented
brother, the Antos, became even safer. The third genera-tion of the unrivalled Active Brake Assist 3 now also ini-tiates autonomous emergen-cy braking when stationary obstacles are recognised. This means that the Actros is not only able to mitigate the effects of rear-end colli-
sions as before, but is also able to prevent them – a fur-ther milestone in safety de-velopments for trucks. It also means that already today, these Mercedes-Benz trucks meet the legal requirements of the regulation “AEBS - Advanced Emergency Brak-ing System” only coming into force from 2018. The radar technology used for Active Brake Assist 3 oper-ates reliably in all weather and light conditions, and is active throughout a trucks speed range, from fast walk-ing speed up to motorway speeds using the speed lim-iter at 89 km/h. ■
voy traffic by preventing or mitigating the conse-quences of rear-end colli-sions. Thanks to the new Cross-Traffic Assist function, critical situations involving crossing traffic can also be defused.
City centre junctions are major accident blackspots. The collisions here can most-ly be put down to driver distraction or misjudgement. Whereas humans often react too slowly, assistance sys-tems are immune to that brief moment of shock.
If this anticipatory system detects a hazardous situa-tion of this type, it prompts the driver to start emergen-cy braking by activating
visual and acoustic warn-ings. If the driver presses the brake pedal too tenta-tively, BAS PLUS will step in by automatically boosting brake pressure for effective emergency braking, even applying the brakes at full
power if necessary. Applying just the right amount of braking power for the situa-tion at hand maximises the available braking distance for traffic behind. The Cross- Traffic Assist function is operative at speeds up to
ASSISTANTS ALSO FOR TRUCKS AND BUSES
ABA 3 MEETS THE REGULATIONS FOR 2018
CROSS-TRAFFIC ASSIST IS A NEW FEATURE
I also brake for cars: the 3rd generation of ABA 3, the emergency braking assistant for trucks,
is able to recognise stationary obstacles and brake autonomously
Visual and acoustic warning
BAS PLUS: boosts inadequate braking by the driver as appropriate to the given situation
Detection of pedestrians in the area in front of the vehicle
PRE-SAFE ® Brake: autonomous braking when the driver fails to respond
100 101
ASSISTANTS LANE KEEPING AND BLIND SPOT
LANE KEEPING AND BLIND SPOT ASSIST
ON THE RIGHT TRACKSTRAYING INTO ONCOMING TRAFFIC OR OFF THE ROAD,
CUTTING-IN ON AN OVERTAKING VEHICLE – ACTIVE ASSISTANCE
SYSTEMS CAN PREVENT THESE DANGEROUS MANOEUVRES.
Let’s admit it: we have all done this at some time. A moment of
inattention, fiddling with the radio or mobile phone – and already the car has moved dangerously close
to the edge of the road. With the help of Lane Keeping Assist the driver is warned by steering wheel vibrations when this happens. When the multifunction camera recognises that the vehicle is leaving its lane uninten-tionally, a small electric
motor makes the steering wheel vibrate.
The latest further develop-ment is Active Lane Keeping Assist. This is now also able to intervene should the driv-er inadvertently cross a broken line when the neigh-bouring lane is not clear,
Active Lane Keeping Assist: when the
camera recognises that the vehicle is straying
from its lane, it is brought back on course by
ESP®-controlled braking intervention
Lane Keeping Assist: when the camera recognises that the vehicle
is straying from its lane, the steering wheel vibrates to warn the driver
Road marking
Course correction: braking intervention by ESP® prevents the vehicle from leaving its lane unintentionally
Vehicle
MPC
Multi-Purpose Camera Optical Lane Detection
Vibration element for haptic warning
of driver
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ASSISTANTS LANE KEEPING AND BLIND SPOT
meaning that a lane-change could result in the risk of a collision. The system can de-termine if this is the case us-ing the information from the stereo camera and the radar system. The latter has been supplemented by a sensor at the rear, which works in uni-son with the other sensors in the front and rear bumpers.
Active Lane Keeping As-sist is not only capable of
recognising critical situa-tions such as overtaking ve-hicles, vehicles to be over-taken and parallel traffic, it
can also respond effectively to oncoming traffic. If the system detects that the vehicle is crossing the lane markings when the adjacent
lane is not clear, not only does it cause the steering wheel to vibrate in pulses as a tactile warning for the
driver, it guides the vehicle back into lane by applying a corrective braking force on one side via ESP®, now also when the vehicle crosses
broken lines. It thereby com-plements Active Blind Spot Assist, and for the first time also enables collisions with oncoming traffic, which can often have far-reaching con-sequences, to be avoided.
Active Lane Keeping Assist is active at speeds be-tween 60 and 200 km/h. If driver activity in the form of active steering, braking or acceleration is detected, for
example, or when the indica-tors are switched on, both the warning and the correc-tive brake actuation are sup-pressed. Using the instru-ment cluster the system can be set for two levels – Stand-ard or Adaptive.
Blind Spot Assist keeps an eye on traffic behind: this radar-based system warns the driver before a lane-change if it detects an-
other vehicle in the blind spot of the exterior mirrors. A red triangle appears in the relevant exterior mirror. If
the indicators are operated despite the warning, the red triangle in the instrument cluster flashes and a warn-ing is sounded.
Active Blind Spot Assist can do even more: It inter-venes if the driver ignores the warnings and the vehicle
in the adjacent lane gets dangerously close. Braking intervention at the wheels on the opposite side of the vehicle generates a yawing
motion that counteracts the collision course. The driver is able to cancel the course- correcting braking inter-vention by countersteering with a steering angle larger than five degrees, or by operating the accelerator with a change of more than ten percent. ■
BLIND SPOT ASSIST Safe lane-changes
Blind Spot Assist developed by Mercedes-Benz uses radar technology to monitor the areas immediately next to and behind the vehicle. If the system registers another vehicle in the exterior mirror’s blind spot, this is shown by a red warning triangle lighting up in the relevant mirror. If the indicators are operated despite the visual warning, an acoustic warning is sounded as well. Active Blind Spot Assist not only warns of danger, but can help to prevent accidents by means of targeted braking intervention.
WARNING STAGE ONE: RED TRIANGLE IN THE EXTERIOR MIRROR
WARNING STAGE THREE: COURSE CORRECTION BY ESP®
Support for professionals: Blind Spot Assist is even more important where there is no rear window, which is why the new Sprinter has it
All-round vision: Blind Spot Assist not only monitors the overtaking lane, but all adjacent lanesWarning triangle: information before
the other road user appears in the mirror
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ASSISTANTS CPA
COLLISION PREVENTION ASSIST
PREVENTION OF FRONT IMPACTS COLLISION PREVENTION ASSIST (CPA) IS ON BOARD AS STANDARD, FROM THE
A-CLASS TO THE S-CLASS. THE SYSTEM WARNS THE DRIVER WHEN THERE IS A RISK
OF COLLISION. CPA PLUS IS EVEN ABLE TO BRAKE SEMI-AUTONOMOUSLY.
The radar-based COLLI-SION PREVENTION ASSIST (CPA) pro-
vides the possibly distracted driver with visual and acous-tic warnings of identified ob-stacles and prepares Brake Assist for precision braking. This braking is initiated as soon as the driver firmly
presses the brake pedal. When an impending danger of collision is identified, COLLISION PREVENTION ASSIST calculates the pre-cise braking force ideally needed to avoid an accident and makes the best possible use of any distance remain-ing. Unlike city braking sys-
tems, CPA not only assists in urban areas but from 7 to 250 km/h.
In combination with DISTRONIC PLUS, COLLI-SION PREVENTION ASSIST PLUS has an additional func-tion. When a danger of colli-sion persists and the driver fails to respond, the system is able to carry out autono-mous braking at speeds
of up to 200 km/h, thereby reducing the severity of col-lisions with slower or stop-ping vehicles. Depending on the vehicle model, the system also brakes when sta-tionary vehicles are detected up to a speed of 50 km/h, and can prevent front-end collisions up to 30 km/h. ■
COLLISION PREVENTION ASSIST System details
COLLISION PREVENTION ASSIST1 COLLISION PREVENTION ASSIST PLUS2
Distance warning • 7 – 250 km/h (moving and stopping objects) • 7 – 72 km/h (still-standing objects)
Collision Warning • 7 – 250 km/h (moving and stopping objects) • 7 – 72 km/h (standing objects)
Adaptive Brake Assist • 7 – 250 km/h (moving and stopping, but not still-standing objects)
• 7 – 250 km/h (moving and stopping • 7 – 30 km/h (still-standing objects)
Autonomous partial braking - • 7 – 250 km/h (moving and stopping• 7 – 30 km/h (still-standing objects)• deceleration by brakes up to 6 m/s• avoidance of collisions up to ca. 20 km/h difference in speed
1 Until 2013 in A- and B-Class: Protection against typical rear end collisions in dangerous traffic situations at speeds above 30 km/h2 In combination with DISTRONIC PLUS
COLLISION PREVENTION ASSIST Functioning sequence
Greyhound and hare: the developers use the Balloon Car to
simulate moving traffic ahead. If the braking distance is
inadequate during the tests, the damage is kept within reason
Visual and acoustic warning
Distance warning – activated if the driver critically approaches a vehicle in front
!
Visual and acoustic warning
Braking force calculated to the situation is applied and PRE-SAFE® activated
Adaptive Brake Assist – activated if the driver brakes in a critical situation
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ASSISTANTS TRAFFIC SIGN RECOGNITION
TRAFFIC SIGN ASSIST
ORIENTATION IN THE TRAFFIC SIGN JUNGLETHERE IS AN INCREASINGLY DENSE FOREST OF TRAFFIC SIGNS. TRAFFIC
SIGN ASSIST IS DESIGNED TO RELIEVE THE DRIVER’S WORKLOAD. IT CAN DO
MORE AND MORE, BUT ITS JOB IS MORE COMPLEX THAN ONE MIGHT
THINK BECAUSE TRAFFIC SIGN DESIGNERS HAVE LIVELY IMAGINATIONS.
Traffic Sign Assist now also identifies no-overtaking zones and can warn of no-entry signs. As before, the camera on the inside of the windscreen registers signposted speed limits, including those on gantries or where there are roadworks. The data are compared with signs stored in the system’s memory, and rec-onciled with information from the navigation system. The result
can be shown both in the instrument cluster and in the map display. If the camera detects no speed limit signs, the legally prescribed speed limits are shown on the basis of navigation data. No-overtaking signs and their cancellation are also regis-tered, and a visual and acoustic warning is given when no-entry signs are recognised.
TRAFFIC SIGN ASSIST Now also identifies no-overtaking and no-entry signs
Traffic sign designers are creative people. This certainly makes
traffic signs entertaining, but in times of international mobility it also leads to con-fusion. In 1968, at the Vien-na Convention, this caused e.g. the German-speaking countries to agree on a standardisation of the most important traffic signs. At
the time the old HALT sign was replaced by the interna-tional stop symbol. Most Eu-ropean countries and many other nations have mean-while signed up to this con-vention. Only in this way is automatic traffic sign recog-
nition possible. The basis of this standardisation is the use of pictograms that are as easy as possible to under-stand. This also facilitates recognition and understand-ing by road users unfamiliar with the local language.
Apart from standardised signs, many countries con-tinue to use their own, spe-cial signs - for example the famous elk warning signs in Sweden. And major tourist countries such as Spain have not formally acceded to the agreement. Unfamiliar signs can also often be found on eastern European roads. Mainly in the USA, road signs give instructions or in-formation not as pictograms, but in written form - a prac-tically insurmountable hur-dle for automatic recognition systems.
In clearly control-fixated Germany there are 648 offi-cial traffic signs with 1800 variations. As helpful as traffic signs can be in many
cases - less would often be more: this is because the ab-sorption ability of road users is limited, and the forest of signs on the roads is too much for drivers to process. The European record is prob-ably held by Rethelstrasse in
Düsseldorf, which has 32 signs on a stretch of 50 me-tres. Even a driver passing them at only 30 km/h has precisely six seconds in which to register all of them. This 0.18 seconds per sign is probably just a tad too short even for those among us who have lightning-fast reactions and the presence of mind of a goalkeeper in the national football team. ■
PICTOGRAMS ARE HARDLY USED IN THE USA
GERMANY: 648 OFFICIAL TRAFFIC SIGNS
Warning of no-entry signs: if Traffic
Sign Assist detects a no-entry sign, it
shows a clear message in the instrument
cluster and sounds a warning
Camera
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ASSISTANTS PARKING
PARKING ASSIST
AUTOMATIC ENTRY INTO PARKING SPACESCARS ARE TENDING TO GET LARGER, BUT NOT SO PARKING SPACES. YET CAMERAS
AND PARKING ASSISTANCE SYSTEMS ARE MAKING PARKING EASIER.
What, you still park the car yourself? Current Mercedes-
Benz models like the S-Class have their own parking valet on board with them. At speeds below 30 km/h, ultra-sonic sensors in the side bumper sections survey the nearside of the road for suita-
ble parallel and end-on park-ing spaces. If the offside indi-cators are operated, the system searches on that side of the road. Once a suitable parking space has been found, the parking procedure is as described on the right. With the 360° camera the driver also has a view of the vehicle’s surroundings on the central display. ■
After activation by the driver, Active Parking Assist recognises parking spaces on the left or right side of the road as required. It allows automatic parking with active steering and brake control in both parallel and end-on spaces. On instruction by the system, the driver needs to select the relevant transmission position
and set the vehicle in motion by accelerating or releasing the brakes. What is more, the system is now also able to manoeuvre out of parallel parking spaces again all by itself with automatic steering and brake control, assuming the vehicle was parked there automatically beforehand.
ACTIVE PARKING ASSIST WITH PARKTRONIC Automatic parking and exiting from parallel and end-on parking spaces
Development of parking
assistance: The tailfins on the
saloon models introduced in 1959
still give them their popular name.
In fact they were intended as a
guide to the driver when reversing
the vehicle. In 1991 the large
W 140-series S-Class featured
extending guide rods; from May
1995 these were replaced by
PARKTRONIC with ultrasonic sen-
sors. Even more precision was
available from the infrared and
radar sensors that measured the
distance from 2005, with displays
in the dashboard and headlining,
the latter visible in the rear-view
mirror (photos clockwise)
All-round view: with the 360° camera the surroundings are shown in the display
from various perspectives - from the complete panorama with bird’s-eye view to detailed
views. Where exits are narrow, crossing traffic in the blind spot is revealed
ASSISTANTS DRIVING ACADEMY
DRIVER TRAINING FOR EVERY LEVEL
EXPERT AT THE WHEELTHE AIM OF THE DRIVING ACADEMY IS TO PERFECT THE
INDIVIDUAL STYLE OF DRIVING WHILE HAVING PLENTY OF FUN.
THE INTERACTIVE PROGRAMME ROADSENSE FOR YOUNG
PEOPLE TRAVELLING AS PASSENGERS IS AN UNUSUAL ONE.
Icy patches, emergency braking or sudden eva-sive action on slippery
roads – in critical winter situations it is important to keep a cool head and control the vehicle with confidence. The winter training courses offered by Mercedes-Benz Driving Events or the AMG Driving Academy are specif-ically aimed at this, and instill intuitive, confident reactions at the wheel.
With the reassuring feel-ing of being in the hands of experienced instructors, the participants practice in the breathtaking winter land-scapes of Austria or Sweden, using vehicles provided from the Mercedes-Benz model range to explore their per-sonal limits.
In the summer too, nu-merous training courses are
held regularly on the cir-cuits of traffic safety centres and racetracks – for begin-ners or professionals, and also for off-road fans. Mercedes-Benz Driving Events Chief Instructor Wolfgang Müller: “Confident and safe vehicle handling is
our goal. And the drivers also experience the addition-al support they receive from the driver assistance sys-tems. This means that not only are our vehicles safer and safer, but also our drivers thanks to the driver training.”
AMG Driving Academy Chief Instructor Reinhold Renger adds: “Apart from the enjoyment of sporty
driving, precision is our aim. This also includes efficiency: maximum engine speeds and smoking tyres by no means guarantee the fastest lap times. These can usually be achieved with considera-bly less fuel consumption – which has surprised many a participant.”
With its unusual Road-Sense programme, the Mercedes-Benz Driving Academy closes the wide gap in the traffic education of young people that falls between elementary school and obtaining a driving licence. In this programme, 13 to 15 year-old adolescents are shown new and unfami-lar perspectives covering their own behaviour as pas-sengers. Under the guidance of specially trained driving instructors and on enclosed circuits, the adolescents re-alistically experience typical
FUN AND PRECISION ARE THE AIMS OF THE DRIVER TRAINING
The high art of drifting: during the
driving events on snow, car drivers
practice driving at the limits on
frozen lakes. Fun is guaranteed
Instructors: Wolfgang Müller, Chief Instructor for MB Driving Events (in the car), and Reinhold Renger, Chief Instructor at the AMG Driving Academy
Mudbath: special training courses for off-road enthusiasts Water games: dealing with aquaplaning is also practiced
110 111
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ASSISTANTS DRIVING ACADEMY
conflict situations close at hand in their role as passen-gers. The aim is to minimise the risks to adolescents in road traffic. The programme takes a unique educational approach, and actively in-volves each of the students. As passengers the young
people experience how much potential conflict can arise in a car for young occupants in particular. They learn how important it is to keep themselves and their feel-ings under control in road traffic. On the practice cir-cuit they are also briefly allowed behind the wheel under supervision. Thanks to its practical nature, this form of traffic education is not only fun, but also leaves a lasting impression.
Since June 2010, 21,000 young people in Germany alone have taken part at ten Mercedes-Benz locations in eight federal states - more than 780 8th and 9th grade school classes from more than 400 different schools. If Great Britain and the Netherlands are included, where the programme is also available, the number is no less than 30,000 stu-dents. With its RoadSense programme the Mercedes-Benz brand is now a subject of conversation on many school playgrounds, and is impressively managing to put the focus of young people onto safety. ■
13 TO 15 YEAR-OLDS ARE BRIEFLY ALLOWED BEHIND THE WHEEL
Class excursion: in Germany
alone, more than 21,000
adolescents have already
taken part in RoadSense,
experienced the conflict
situations that passengers
typically encounter in road
traffic and learned to take
a responsible view of them
Drink and drive? Using “alcohol spectacles”, students experience how spirits may affect reactions; all learnings are journalised
Discussion: before and after the exercises, there is a discussion on how passengers can contribute to traffic safety
Blind faith? The students learn that good passengers
intervene if the driver behaves irresponsibly
114 115
were driven during standard operation.
When required the elec-tronic control system
automa tically switched to all-wheel drive, with torque
distribution (33:67 favouring the rear axle) and synchronisation by a planetary
gear system. If necessary, the rear axle and centre differential were locked in two further stages.
ASSISTANTS FACTS, FIGURES AND CURIOSITIES
33:67As dynamic control systems, the automatic locking differential (ASD), accelera-tion skid control (ASR) and auto-matically engaged 4MATIC all-wheel drive celebrated their premiere in the Mercedes-Benz 124 series (1984 to 1997). In the sophis-ticated all-wheel drive system of the 124 series, the rear wheels
35 MILLION KILOMETRESBefore the anti-lock braking system ABS jointly developed by Daimler-Benz and Bosch was mature enough for series production in 1978, Mercedes-Benz conducted a major trial with 100 test vehicles covering over 35 mil-lion kilometres. Only then was the company satisfied with the reliability of the rpm sensors at the two front wheels and at the drive pinion of the rear axle, the electronic control unit and the hydraulic unit.
6.8 LITRES DISPLACEMENT The “Dernburg Car” of 1907 was the world’s first all-wheel drive car with internal combustion engine, built by Daimler- Motoren-Gesellschaft. From 1908 the vehicle was in operation in German South-West Africa, present-day Namibia. The 35 hp four-cylinder engine with a displacement of 6.8 litres sent its power to the four wheels via a sophisticated mechanical system: A shaft connected it to the precisely centrally installed transmission, providing four forward gears and one reverse gear. From there, propeller shafts transferred the rotary move-ment to the differentials at the front and rear axles, which in turn distributed it to the wheels via bevelled gears.
2,217.60 GERMAN MARKSFrom 1978 ABS became available as an optional extra for the W 116-series S-Class, the extra cost being DM 2,217.60. Since 1984 ABS has been standard equipment for Mercedes-Benz passenger cars. Ten years after its first introduction, one million Mercedes-Benz cars with ABS were already on the roads of the world.
1981Mercedes-Benz also took on the pioneering role in the commercial vehicle sec-tor. ABS for compressed air brakes, a joint development with WABCO, already became available in 1981. Since 1986 the brand’s large touring coaches have been equipped with ABS as standard, and since 1991 also its truck models. Before approval for series production, the anti-lock braking system for trucks and buses was subjected to more than 60 million test kilometres – ABS must be reliable under all circumstances. The markings on the tyres make the effect more easily visible.
100 PERCENT A customer purchasing a Mercedes-Benz with a trailer coupling automatically receives the trailer stabilisation system Trailer Stability Assist TSA as well. The same applies to vans such as the Sprinter. TSA is an additional function of the Electronic Stability Programme ESP®, and ensures more safety when towing a trailer.
TSA rapidly and reliably recognises the onset of feared sinusoidal oscillations, and effectively dispels them. To this end it uses the ESP® sensors, and initiates alternating, targeted braking intervention at individual wheels to stabilise the combination.
DID YOUKNOW?
116 117117116
DRIV
ER F
ITN
ESS
TURNING NIGHT INTO DAYOWLS are nocturnal animals with outstanding eyesight and
hearing. Their large, forward-facing eyes enable them to see
objects and prey spatially so that speed and distance can be
assessed. The eyes themselves do not move in their sockets –
instead owls are able to swivel their heads by up to 270°,
which greatly increases their field of vision. Many owl species
also have a facial hood that directs sounds towards their ears.
DRIVER-FITNESS SAFETY HAS BEEN A KEY VALUE AT
MERCEDES-BENZ FOR SEVERAL DECADES. NIGHT VIEW ASSIST, INTELLI-GENT LIGHT SYSTEMS AND THE HEAD-UP DISPLAY ENSURE
EXCELLENT VISIBILITY. STOP&GO PILOT, ATTENTION ASSIST AND INNO VATIVE
SUSPENSION SYSTEMS ARE ALSO AMONG THE
RESULTS OF DRIVER-FITNESS RESEARCH. Phot
o: M
artin
Har
vey/
Cor
bis
119
DRIVER FITNESS INFRARED
119118
Extending the field of vision: Infrared
light is invisible to the human eye. It can
therefore be used for dazzle-free road
illumination at night. An infrared camera
then makes the image visible
NIGHT VIEW ASSIST
BETTER VISION WHEN DRIVING AT NIGHTUNBELIEVABLE REALLY – THE CAR SEES MORE THAN ITS DRIVER.
TO DO THIS THE NIGHT VIEW ASSIST SYSTEMS FROM MERCEDES-BENZ
USE INFRARED LIGHT AND INFRARED CAMERAS. NIGHT VIEW ASSIST
HAD ITS WORLD DEBUT IN THE S-CLASS IN 2005.
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DRIVER FITNESS INFRARED
NIGHT VIEW ASSIST PLUS Spotlight function
For the first time, the new Night View Assist Plus is capable of detecting not just pedestrians in potentially hazardous positions in front of the vehicle, but animals too. This third-generation night vision system automatically switches the instrument cluster display from the speedometer to a crystal-clear night view image to alert the driver in unlit areas. Any pedestrians or animals detected ahead are highlighted in red in this image, and pedestrians are briefly flashed by a spotlight.
In the latest generation of this assistance system, an additional (long-
range) infrared sensor in the radiator grille is added to the well-proven Mercedes-Benz night vision technology. This enables pedestrians to be detected at a distance of up to 160 metres, and animals such as deer, horses or cows at up to 100 metres. Two separate light sources in the headlamps illuminate the road ahead of the vehicle with invisible infrared light. A (short-range) infrared camera behind the wind-screen near the rear-view mirror is able to generate
a brilliant greyscale image in the instrument cluster display.
As a third-generation night vision system, the new Night View Assist Plus is-sues a warning in particu-larly relevant situations
(darkness, unlit roads at speeds exceeding 60 km/h) by automatically switching from the speedometer to a brilliant night view image in the instrument cluster dis-play. Pedestrians or animals detected ahead are high-lighted in red in this image.
In such situations the spotlight function is addi-tionally used to repeatedly
flash pedestrians in the warning zone by means of a special module in the front headlamps. This attracts the driver’s attention to the danger, and the person at the road edge is warned at the same time. Animals are intentionally not flashed, as their reaction to light impulses is unpredictable. Pedestrian and animal de-tection, and the correspond-ing highlighting, are now also available in urban areas during darkness (illuminat-ed roads, speed less than 60 km/h) if the greyscale image is activated perma-nently. ■
Visibility with night view assist
Visibility with low-beam headlamps
Display in instrument cluster
Pop-up-function
NIGHT VIEW ASSIST PLUS SEES ANIMALS AND PEDESTRIANS
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DRIVER FITNESS HEAD-UP DISPLAY
Starting with the new C-Class, Mercedes-Benz is introducing a
new level of information for the driver. The head-up display supplements the in-formation in the central display. As in a jet fighter, it projects important informa-tion directly into the driver’s field of vision on the wind-screen, ensuring that there is less distraction from the road ahead. Neither do the driver’s eyes need to adapt between long and short-
range vision. The system provides information on speed, speed limits, naviga-tion instructions and mes-sages from driver assistance systems.
The technology is based on mirror optics and a full- colour display module with a resolution of 480 x 240 pixels which is driven by high-powered LEDs. They project the virtual image, which measures around 21 x 7 centimetres, into the driver’s field of vision where
it appears to float around two metres away above the bonnet. This means that the driver sees both the mir-ror image from the generat-ing unit and the real world in front of the windscreen. The resolution of more than 60 pixels per degree of view-ing angle ensures a crys-tal-clear image.
A light sensor located near the top edge of the roof automatically adjusts the brightness of the head-up display to the exterior light-ing conditions. Light densi-ties of 10,000 cd/m² plus can be achieved on sunny days. Since the contrast ratio is better than 1000:1, the sys-tem produces a high-quality display even in the dark.
The light density provides detailed information about the location and direction of a light beam emitted by a lighting source. It is the pho-tometric measure of what the human eye perceives as the brightness of a surface. The light density describes the brightness of extended, flat light sources. The SI unit
for light density is candelas per square metre (cd/m²).
The driver can adjust the height of the virtual image so that it can be easily viewed. On vehicles with a seat memory function this feature stores the individual setting. A range of display content can also be enabled or disabled, and the bright-ness of the display adjusted individually.
The special head-up windscreen with its wedge-shaped laminated foil eli-minates double images produced by reflections on the outer and inner boundary surfaces of the windscreen. It superimposes the secondary image, which is produced on the outer sur-face, onto the primary im-age. This offset depends on the particular angle and has been optimised for a driver in a normal seated position. ■
INFORMATION IN THE DRIVER’S FIELD OF VISION
HEAD UPTHE DRIVER RECEIVES TWO FORMS OF INFORMATION
AT A GLANCE THANKS TO THE HEAD-UP DISPLAY. THIS
IS BEING INTRODUCED WITH THE NEW C-CLASS, AND
WILL SOON BECOME A FEATURE OF OTHER MODELS.
Double information: in addition to the normal view of the
road, the driver has a virtual image showing vehicle information
projected onto the windscreen in the direct field of vision.
The blurred actual image is due to photo technology
VIRTUAL IMAGE SEEMS TO FLOAT AHEAD OF THE CAR
LIGHT DENSITY IS EVEN SUFFICIENT FOR PROJECTION AT NIGHT
DISPLAY IS INDIVIDUALLY ADJUSTABLE
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DRIVER FITNESS HEADLAMPS
As the world’s oldest and best known automotive brand,
Mercedes-Benz has always stood for innovations that are designed to benefit custom-ers. LEDs (light-emitting diodes) today represent the state of the art in vehicle
headlamps. Here is a brief chronology of the most impor-tant milestones in Mercedes-Benz light technology over the past 20 years:1991: Premiere of xenon headlamps with gas dis-charge lamps in the Mercedes F 100 research vehicle1995: Xenon headlamps with dynamic headlamp range con-trol in the E-Class1999: Premiere of bi-xenon technology in the CL-Class2003: World premiere of the active light function in the E-Class2004: World premiere of bi-xenon headlamps with active light function and cornering light function in the CLS-Class2005: Premiere of Active Night View Assist in the S-Class2006: World premiere of the Intelligent Light System in the E-Class
MILESTONES IN MERCEDES-BENZ LIGHTING TECHNOLOGY
ALL-LED HEADLAMPS Breakthrough with the CLS
2010 saw a breakthrough in LED technology. With the launch of the CLS, Mercedes-Benz became the first automotive manufacturer to offer a series-production model featuring dynamic all-LED headlamps incorporating all the adaptive light functions of xenon systems. The lighting specialists at Mercedes-Benz have also for the first time been able to combine this LED technology with the already innovative Adaptive Highbeam Assist, which has resulted in a completely new level of safety at night.
Dipped beam - base light 8 LEDs
Dipped beam-spot 8 LEDs
Cornering light 2 LEDs
NightView 10 LEDs
Main beam 8 LEDs
Side light 22 LEDs
Indicator 13 LEDs
INTELLIGENT LIGHT SYSTEMS
LET THERE BE LIGHTLIGHT-EMITTING DIODES (LEDS) HAVE BEEN BOUND TO BECOME THE NORM AS
A LIGHT SOURCE FOR HEADLAMPS SINCE THE CLS USED THEM IN THE
INTELLIGENT LIGHT SYSTEM FOR THE FIRST TIME. AND THE NEW S-CLASS IS
THE VERY FIRST AUTOMOBILE TO DISPENSE ENTIRELY WITH LIGHT BULBS.
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DRIVER FITNESS HEADLAMPS
ADAPTIVE HIGHBEAM ASSIST More light improves visibility and comfort at night
Conventional systems merely switch between low and high beam. Highbeam Assist presented in 2008 works adaptively, however, and regulates the light distribution of the xenon headlamps as the traffic situation permits. The range of the low-beam head-lamps can therefore be increased from around 65 to up to 300 metres - without dazzling other drivers. When the system detects oncoming traffic or cars ahead, it dips the headlamps and continuously adapts the beam range to the distance.
INTELLIGENT LIGHT SYSTEM – CORNERING LIGHTS More safety on junctions
The cornering light is automatically activated if the driver operates the indicators or turns the steering wheel at a speed below 40 km/h. The headlamps then illuminate the side area ahead of the vehicle to a range of around 30 metres at an angle of up to 65 degrees.
INTELLIGENT LIGHT SYSTEM – MOTORWAY MODE Up to 60 percent longer visibility
Motorway mode is automatically activated from a speed of 90 km/h. The range of the Motorway mode beams is around 120 metres; in the centre of the light cone, the driver is able to see around 50 metres further than with conventional low beam.
INTELLIGENT LIGHT SYSTEM – EXTENDED FOGLIGHT Less backglare
The foglamps are active below 70 km/h as soon as the rear foglight is switched on. The headlamp on the driver’s side is pivoted outwards by eight degrees, while the light beam is lowered. This exposes the driver to less backglare.
2009: World premiere of the Intelligent Light System with Adaptive Highbeam Assist in the E-Class2009: Premiere of Active Night View Assist Plus in the S- and E-Class 2010: World premiere of LED High Performance head-lamps incorporating all
the light functions of the Intelligent Light System in the CLS-Class2010: New xenon burner with 20 percent higher col-our temperature, and thus even closer to daylight, in the S- and E-Class2011: World premiere of the spotlight function in con-junction with Active Night
View Assist Plus in the CL-Class2013: New E-Class fitted as standard with energy-effi-cient LED low-beam head-lamps (34 watts/vehicle)2013: New S-Class becomes the first car to be equipped exclusively with LED tech-nology as standard
ADAPTIVE HIGHBEAM ASSIST PLUS Permanent high beam
Adaptive Highbeam Assist excludes recognised road users from the cone of light. If the camera-based system registers either oncoming traffic or vehicles ahead, it will adapt the light distribution according to the traffic situation when high beam is switched on.
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DRIVER FITNESS HEADLAMPS
INTELLIGENT LIGHT SYSTEM – ACTIVE LIGHT FUNCTION Up to 25 metres more visibility on bends
Depending on the steering angle, yaw rate and road speed, the high and low-beam headlamps pivot sideways by up to 15 degrees to considerably improve road illumination.
INTELLIGENT LIGHT SYSTEM – COUNTRY MODE Better illumination of the offside road verge
Country mode replaces low-beam headlamps, and illuminates the road verge on the driver’s side more brightly and widely. This enables the driver to react more rapidly in the dark when other road users cross the vehicle’s path.
The light from LED head-lamps is closest to daylight. This means that LED light is in keeping with normal hu-man perception patterns. The closer its colour is to natural daylight, the less ar-tificial light strains the eyes. With a colour temperature of 5500 kelvin, LED light is closer to daylight (6500 K) than xenon light (4200 K).
LEDs are significantly more energy-efficient than regular bulb sets and, de-pending on the area of appli-cation, consume around 75 percent less power. With a higher light output than conventional illumination systems, an energy-saving LED low-beam headlamp, for example, consumes just
34 watts and is therefore much more efficient than a halogen (110 to 120 watts) or xenon light (80 to 84 watts; figures are per vehicle in each case). This means that it is possible to save up to 0.05 litres of fuel per 100 kilometres, or 2.1 grams of CO2 per kilometre, compared to a vehicle with halogen headlamps.
LEDs last considerably longer than regular bulb sets. At 10,000 hours, the average life of an LED is around five times longer than that of a xenon bulb.
Since the spring of 2013, the new E-Class has been setting standards in terms of light features: as standard it boasts both low-beam head-
lamps and daytime running lamps which make use of LED technology. In the high-ly efficient low-beam mode, the two headlamps together have a total power consump-tion of just 34 watts. All-LED High Performance head-lamps are available as an option for the first time in
this class. The new S-Class is the first automobile in the world to be equipped only with LED headlamps, and dispense entirely with con-ventional light bulbs: almost 500 LEDs are now responsi-ble for illuminating the road, the vehicle, the interior and the luggage compart-ment. ■
The Active Multibeam LED headlamp will see the introduction of roundabout mode as an additional ILS function, and the active light function will be further improved by the use of camera data. Roundabout mode is based on navigation data, and switches on the two cornering lights 70 metres before reaching a roundabout. This gives the driver the best possible road edge illumination when entering, leaving and driving on the roundabout. Pedestrians, cyclists and obstacles can therefore be recognised more easily.In the active light function, information from the camera is used in addition to the steering angle sensor for lane recognition. This enables the light to follow the traffic lane even before the steering wheel is moved. The result is longer-range road illumination when entering and exiting bends.
Active Multibeam LED takes the situation-based control of the vehicle’s headlamps into a new dimen-sion. Previously, individual functions such as the active light function or anti-dazzle main beam have been con-trolled mechanically. In the next headlamp generation each LED can be switched on individually, thereby allowing precisely targeted areas to be illuminated. The headlamps are able to adjust their light pattern extremely quickly and unobtrusively – and this can even occur individually for the left and right headlamps respectively. Control units calculate the ideal light pattern 100 times per second.
ACTIVE MULTIBEAM LED The next generation of headlamps
130 131
DRIVER FITNESS HEADLAMP HISTORY
1999 CL-Class Bi-Xenon- headlamps 1995 E-Class Xenon headlamps 1971 350 SL Halogen headlamps (H4) 1968 300 SEL 6.3 Double Halogen headlamps (H3) 1934 500 K Bilux bulbs 1915 Benz 18 / 45 PS Electric dipping low beam headlamps 1901 Mercedes Simplex Acetylene lamps1886 Daimler Motorwagen Candle lamps
2010 CLS-Class 2013 First fully E-Class dynamic LED First fully dynamic headlamp LED headlamp with 2009 Adaptive High Beam E-Class Assist Plus Intelligent Light System with Adaptive High Beam Assist 2006 E-Class Intelligent Light System 2004 CLS-Class Bi-Xenon-headlamps with Active Curve Light and Cornering Light2003 E-Class Bi-Xenon headlamps with Active Curve Light
THE EVOLUTION OF LIGHT From the carbide lamp to the all-LED headlamp
The inventor of the automobile has also always been a pioneer in the development of lighting. For almost 100 years, incandescent bulbs on the Edison principle were the princi-pal lighting source for automobiles.
The long operating life and a colour tem-perature similar to
natural daylight have long been clear advocates for LED technology. And now Daimler engineers have accomplished a major leap in energy efficiency with the S-Class: power consumption has been reduced by 75 per-cent compared to conven-tional headlamps. A break-through into the future of lighting, and a farewell to Thomas Alva Edison’s incan-descent bulb technology.
A hundred years ago, the introduction of electric light-ing was a major innovation. Until then carbide lamps provided illumination, but were not entirely uncompli-cated. In the stately Landau-let version of the Benz 24/40 HP delivered from Mann-heim to Argentina in 1908, which remained in use there until 1966, the gas generator was located in a wooden box on the left-hand running- board. Water was added to generate acetylene gas from the calcium carbide, and copper tubing fed this to the headlamps which were ignit-
ed by the chauffeur. The light from the flame was pro-jected forward by reflectors. Afterwards, incandescent bulbs on the Edison princi-ple became the principal lighting source for automo-biles for 100 years.
A thing of the past: in the new S-Class almost 500 LEDs provide the lighting for the road, the vehicle, the interior and the boot. They require less energy by far for the same light out-put. The new, energy-saving LED low-beam headlamps require only 34 watts, and are therefore much more efficient than halogen light (120 watts) or xenonlight (84 watts, figures are per vehicle). New, powerful single-chip LEDs and a new-ly developed projection mod-ule in the headlamp, where light rays are diverted, re-flected and projected out-wards, make a significant contribution to the increased efficiency. ■
GOODBYE TO THE LIGHTBULB
BYE-BYE EDISONAROUND 100 YEARS AFTER THE INTRODUCTION OF ELECTRIC LIGHTS FOR AUTOMOBILES,
MERCEDES-BENZ IS SENDING OUT A NEW SIGNAL: THE NEW S-CLASS IS THE FIRST CAR
IN THE WORLD TO DISPENSE COMPLETELY WITH INCANDESCENT BULBS. THE BENZ 24/40 HP
OF 1908 WAS ONE OF THE LAST COMPANY MODELS NOT TO HAVE ELECTRIC LIGHT.
Lit up: the old Benz sparkles in the
powerful LED headlamps of the S-Class
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DRIVER FITNESS RESEARCH
CUSTOMER RESEARCH CENTER (CRC)
FOCUS ON DRIVER- FITNESSDRIVER-FITNESS SAFETY IS A MAJOR
COMPONENT OF THE MERCEDES-BENZ CORE
BRAND VALUE “COMFORT”. THE CUSTOMER
RESEARCH CENTER SCIENTIFICALLY EXAMINES
WAYS OF MINIMISING STRESSES FOR CAR
DRIVERS. THIS RESEARCH ALSO INCLUDES NOISE
AND VISIBILITY TESTS IN THE WIND TUNNEL.
Comfort is also condu-cive to safety. Studies by the Customer
Research Center (CRC) at Mercedes-Benz show that certain comfort attributes have a direct influence on driver performance and well-being during and after a journey.
Research into driver- fitness safety has been a key task of the CRC for over 15 years. Highly reputed international scientists are regularly invited to the com-pany to document the cur-rent status of research into
e.g. acoustic comfort, vibra-tion comfort and climatic comfort, and to analyse the effects on human mental and physical performance.
The typical approach taken by the CRC studies on performance-enhancing comfort is initially to regis-ter the customer-related in-fluencing factors. Findings on the subject of “long-dis-tance journeys” are obtained by means of detailed custom-
TESTS WITH VOLUNTEERS Taking the measure of car drivers
For more than 15 years the Customer Research Center at Mercedes-Benz has examined the stresses acting on car drivers. To this end tests are conducted in the driving simulator and on the roads, under real conditions and with specially prepared vehicles.
Typical measurements carried out on volunteers e.g. include the following data:1 Pupil test before and after the journey 2 Tension in the neck muscles 3 Online survey during the journey 4 Heart rate 5 Tension in the arm muscles 6 Electrical skin conductivity at foot level
Trials: driving simulators have been
available since 1985. They combine
driving tests with a laboratory situation
TAILBACKS ARE A MAJOR STRESS FACTOR
Wired up: the stresses are registered by physiological measurements Monitored: fitness is measured during a real test drive
1
2
3
4
5
6
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DRIVER FITNESS RESEARCH
PREVENTION OF SOILING Keeping things clean
Having the best possible visibility in all conditions makes a contribution to Active Safety. In the wind tunnel the aero-dynamic specialists optimise components with the help of a fluorescent liquid which makes the soiling clearly visible. The aim is to direct water away so that the side windows and exterior mirror lenses remain clean. This is influenced by the geometry of the A-pillar with its integral compo-nents and the geometry of the exterior mirrors and window frames, or trim strips in the case of frameless doors.
er surveys in e.g. Germany and the USA. One of the main findings is that uncer-tainty about events during a journey, e.g. traffic tailbacks, is a significant stress factor.
The second phase in-volves extensive practical driving tests to systematical-ly examine the influencing factors for their relevance to performance-enhancing comfort. For example using three externally identical E-Class test cars which no-ticeably but by no means dramatically differ in their
vibration and noise comfort, and which have different driver seats. 36 Mercedes-Benz customers with long-distance driving expe-rience were sent on a 410-kilometre long circular route covering motorways and country roads in each of the cars, and this route was completed three times.
The fitness of the test sub-jects during and after the journey was assessed using a number of indicators. Dur-ing the journey, the heart rate was monitored together with muscular tension in the neck area and the frequency of frowning as an indicator of dissatisfaction. The con-
centration of the hormone cortisol in the saliva gave an indication of stress levels. Directly after the journeys the test subjects were sub-jected to performance and alertness tests to assess their level of fitness. They were also asked to complete questionnaires and assess their level of fatigue, for example. Indirect indicators also taken into account in-cluded the average driving speeds and especially the
length of the breaks taken by the drivers.
Dr Götz Renner summa-rises the conclusions from the research as a “recipe
for performance-enhancing vehicles”: “Build a quiet vehicle, especially avoiding the low frequencies, add a
good (driver’s) seat and first-class climate control. Plan and schedule routes and rest breaks while avoiding tail-backs, entertain the driver, create the fundamental conditions for relaxation and assist them with functions such as the ENERGIZING massage function so that they can cope with stress and fatigue. This vehicle will then have a fit and alert driver – even after the journey.” ■
Acoustic comfort: the task of the aeroacoustic
specialists in the wind tunnel is to minimise
the frequency and intensity of obtrusive noises
Visibility comfort: fluorescent
liquids make soiling clearly visible in
the important areas. The channeling
of dirty water is optimised
FROWNING AS AN INDICATOR OF DISSATISFACTION
A RECIPE FOR PERFORMANCE- ENHANCING VEHICLES
Working with the wind: smoke trails make the wind visible
136 137
calculates an individual driver profile during the first few minutes of every trip. This profile is then com-pared with the current sen-
sor data and the prevailing driving situation by the car’s electronic control unit. If the system detects drowsi-ness, it emits an audible warning signal and flashes up an unequivocal message on the display in the instru-
ment cluster: “ATTENTION ASSIST. Break!”
In 2013, it was systemati-cally developed further, and the latest version has the
ability to detect drowsiness and inattentiveness across a far greater speed range from 60-200 km/h. Furthermore, the system’s sensitivity can be adjusted, for example
for drivers who already feel tired when they take the wheel.
A new menu in the instru-ment cluster display also makes the system more tan-gible and transparent for the driver by visualising the current ATTENTION ASSIST level and the driving time since the last break. If the usual ATTENTION ASSIST warning recommending the driver to take a break is emitted, nearby service areas can be indicated in the navigation system. ■
ATTENTION ASSIST developed by Mercedes-Benz reg-
isters over 70 parameters which are evaluated for drowsiness detection. This continuous monitoring is necessary to register the transition from wakefulness to drowsiness, and to warn the driver in good time.
Based on this wealth of data, ATTENTION ASSIST
ATTENTION ASSIST Measuring fatigue
The key indicator of increasing drowsiness is a change in steering behaviour. ATTENTION ASSIST measures this with a high-resolution steering wheel angle sensor. During tests with over 670 male and female car drivers over the development period, Mercedes-Benz scientists found that overtired drivers have difficulty in keeping the vehicle precisely in its lane. They make small steering errors which are often cor-rected quickly and in a characteristic manner. 70 further indicators are also evaluated.
ATTENTION ASSIST
PREVENTING FATIGUEIN GERMANY DROWSINESS IS THE CAUSE OF ONE
QUARTER OF ALL MOTORWAY ACCIDENTS. IN 2009
MERCEDES-BENZ PRESENTED ATTENTION ASSIST,
WHICH IS ABLE TO DETECT SIGNS OF DROWSINESS
USING A LARGE NUMBER OF PARAMETERS.
DRIVER FITNESS DROWSINESS
Monitored: the test subjects were
carefully monitored during the
development of ATTENTION ASSIST.
Today the system gives a timely
warning of dangerous microsleep
A CLEAR WARNING WHEN DROWSINESS SETS IN: TAKE A BREAK!
Indicator: an angle sensor in the steering wheel registers changes in behaviour
Warning: the central display recommends a break, and also tells the driver where
Premiere: in 2009 the E-Class was the world’s first automobile to feature a drowsiness warning system as standard
138 139
DRIVER FITNESS STOP&GO PILOT
MORE COMFORT IN TAILBACKS
THE CAR BRAKES, ACCELERATES AND STEERS
RELIEVING THE STRESS OF STOP & GO TRAFFIC: DISTRONIC PLUS
WITH STEERING ASSIST AND STOP&GO PILOT TAKES THE BURDEN OFF
THE DRIVER WHEN IT COMES TO LANE GUIDANCE, AND IS ALSO
ABLE TO FOLLOW VEHICLES IN TAILBACKS SEMI-AUTONOMOUSLY.
Car owners have want-ed this for a long time: a car that re-
lieves the driver of stress when tailbacks slow things down and individual mobili-ty loses its sparkle. The de-velopment of Stop&Go Pilot began in 1998 with the ac-tive cruise control system DISTRONIC - using radar, the S-Class maintained the set speed or the distance from the vehicle ahead. DISTRONIC PLUS went one better by being able to brake to a standstill. Following tailback traffic has now been perfected with Steer Assist.
The radar-based basic function has now been ex-tended by Steer Assist with Stop&Go Pilot, which assists the driver with lateral guid-ance of the vehicle. The sys-
tem helps the driver to keep the vehicle in the middle of its lane by generating a steering torque when driv-ing in a straight line or even on slight bends.
The stereo camera recog-nises lane markings as well as vehicles driving ahead together with their spatial positioning, and relays this information to the electric steering assistance system. By generating the appropri-ate steering torque, the sys-tem can enhance ride com-fort in the speed range up to
200 km/h and greatly assist the driver in many traffic situations. At speeds up to 60 km/h, the Stop&Go Pilot ‘intelligently’ decides wheth-er to use the vehicle in front or the road markings as a means of orientation, ena-bling semi-autonomous tail-back tracking even when there are no clear lane mark-ings visible. The system fus-es the data gleaned from the stereo camera and the radar sensors, calculates any reac-tions required, and then reg-ulates the vehicle’s linear speed as requirements dic-tate by controlling engine power, transmission and brakes, as well as actuating the electric steering for lateral vehicle guidance.
DISTRONIC PLUS with Steering Assist can be activated as before with a stalk on the steering column in a speed range from 0-200 km/h, now also with the vehicle standing still and no vehicle moving ahead of it. Any speed between 30 km/h and 200 km/h can be selected as the desired cruising speed. The driver starts off in this case by pulling the DISTRONIC PLUS stalk or tapping the accelerator.
A green steering wheel symbol appears in the in-strument cluster to indicate when Steering Assist is op-erating while DISTRONIC PLUS is activated. Mean-while, linear controlling actions (cruise control func-tion) continue to be visual-ised in the speed display by means of circular segments and the speedometer needle.
The system’s design is so refined that the sensors can detect whether the driver’s hands are on the steering wheel. If the system recog-nises that the driver has tak-en his/her hands off the steering wheel while the car is moving, depending on the situation, the detected sur-roundings and the speed, a visual warning is first is-
sued in the instrument clus-ter; then a warning signal sounds and Steer Assist is deactivated. This is addition-ally indicated by changing the steering wheel symbol from green to white. The lin-ear control action remains unaffected by this and con-tinues to be available. This means that the system has an intelligent hands-off de-tection feature that brings the driver’s hands back to the wheel when necessary. The use of DISTRONIC PLUS makes life easier for drivers in tailbacks – at low speeds they can even drive hands-free, without compromising safety. Thus Mercedes-Benz offers relaxed driving main-ly over long distances and on motorways, especially during otherwise tiring and annoying (slow) tailback driving.
The performance capabili-ties of the basic DISTRONIC PLUS function have been in-creased once again. Now the
STEER ASSIST KEEPS THE CAR ON TRACK
THE DRIVER’S HAND MUST REMAIN ON THE STEERING WHEEL
Preset speed: DISTRONIC PLUS accelerates up to 200 km/h
and brakes, even to standstill in stop & go traffic
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DRIVER FITNESS STOP&GO PILOT
DISTRONIC PLUS WITH STEER ASSIST Comfort in tailbacks
Steer Assist extends the radar-based basic function of DISTRONIC PLUS. The system helps the driver to keep the vehicle in the middle of its lane by generating a steering torque when driving in a straight line or even on slight bends. The stereo camera detects road markings and a vehicle in front and then forwards this information to the electric power steering. This enables the Mercedes to follow the vehicle ahead in a tailback, even if no clear lane markings are visible.
system is able to brake at a rate of up to 5 m/s² without any intervention from the driver. If the “S” transmis-sion mode button is pressed, the rate of acceleration in-creases too. Vehicle accelera-tion is also far more dynam-ic if the driver signals a wish to overtake by switching on the indicators, assuming the adjacent lane is clear.
By combining the radar and camera data, DISTRON-IC PLUS is now also able to detect both vehicles cutting in and vehicles ahead, and
vehicles ahead of them, in one’s own lane and in adja-cent lanes, and take any nec-essary action promptly. This can prevent, for example,
illegal overtaking on the inside lane on motorways and similar multi-lane high-ways by adapting the speed to that of vehicles in the out-side lanes (at speeds above 85 km/h), especially when
a tailback begins to dissolve and in streams of traffic. At lower speeds, permissible overtaking on the inside lane with a maximum speed differential of 20 km/h is possible.
It goes without saying that drivers can always over-ride DISTRONIC PLUS with Steer Assist. For instance if they signal with their indica-tors that they wish to change lanes, the lateral assistance remains passive for as long as it takes to change lanes. ■
DISTRONIC PLUS PROTECTS AGAINST INSIDE PASSING
Virtual reality: the tailback
driving assistant still seemed
Utopian in the F800 Style
research vehicle (2010), but
now it is a reality
Early trials: approaching the
vision of accident-free driving.
Active cruise control undergoing
trials as part of the Prometheus
research project (1986)
142 143
Mercedes-Benz has always sought the ultimate ride com-
fort with its innovative sus-pension systems. In 1961 air suspension had its debut in the 300 SE, and from 1964 its comfort also im-pressed in the model 600. To this day AIRMATIC guar-antees outstanding suspen-sion comfort – not only in the S- and E-Class, but for the first time now also in the new-generation C-Class.
Active Body Control (ABC) comes even closer to the ideal of a flying carpet - this active suspension sys-tem first became available in 1998. Apart from its spring-ing and damping function, this electrohydraulic suspen-sion system based on steel springs allows pitching and rolling movements of the vehicle to be compensated.
As the vehicle is kept hori-zontal by the hydraulic sys-tem, ABC models need no conventional stabilisers, which is unique in automo-bile engineering.
In the new S-Class, Mercedes-Benz makes use of the fast reaction time of an ABC suspension in com-bination with the innovative ROAD SURFACE SCAN func-
tion. This is able to recog-nise undulations in advance, and the suspension responds predictively. The result is unprecedented ride comfort.
The “eyes” for the ROAD SURFACE SCAN function are provided by a stereo camera fitted behind the
windscreen, which scans the road up to 15 metres ahead of the vehicle and delivers a precise image of the road contours. Based on the cam-era pictures and driving sta-tus information, the control unit constantly calculates the best control strategy for overcoming unevenness such as prolonged bumps.
This means that in ad-vance, and for each individu-al wheel, the vehicle is able to select stiffer or softer damper settings and use the active hydraulics to vary the load at each wheel. The suspension is adapted to the relevant situation within fractions of a second, ena-bling body movements to be considerably reduced. As ROAD SURFACE SCAN is camera-based, it works in the daytime, in good visibili-ty, with suitable surface structures and at speeds up to 130 km/h.
ROAD SURFACE SCAN The suspension reads the road ahead
The new S-Class is the first car in the world able to recognise road surface undulations in advance. Once ROAD SURFACE SCAN has detected such undulations with the help of the stereo camera, the suspension system MAGIC BODY CONTROL adjusts the damping at each individual wheel in advance for a softer or harder setting and uses the active hydraulics to increase or lessen the load on the wheel. The result is unprecedented ride comfort. As ROAD SURFACE SCAN is camera-based, it works in the daytime, in good visibility, with suitable surface structures and at speeds up to 130 km/h.
Suspension strut: each wheel has an individually adaptable spring/damper unit. The spring pretension is hydraulically adjusted in fractions of a second
Magic eye: the stereo camera scans the road surface ahead to a distance of up to 15 metres and reports undulations
Brain centre: the infor-mation is processed and the control unit gives precise instructions to the wheel suspension
Undulation: when undulations are recog-nised the suspension adjusts itself in advance – body movements are prevented
Suspension strut: each wheel has an individually adaptable spring/damper unit. spring pretension is hydraulically adjusted in fractions of a second
mation is processed and
ABC SUSPENSION REACTS ALMOST INSTANTLY
DRIVER FITNESS MAGIC BODY CONTROL
THE WORLD’S FIRST SUSPENSION SYSTEM WITH “EYES”
FLYING CARPETWITH THE HELP OF A STEREO CAMERA, MAGIC BODY CONTROL WITH
ROAD SURFACE SCAN RECOGNISES UNDULATIONS AND BENDS
IN ADVANCE, THE SUSPENSION VARIABLY ADJUSTS ITSELF TO
NON-LEVEL STRETCHES AND WITH THE NEW CURVE INCLINATION
FUNCTION THE CAR ELEGANTLY LEANS INTO THE BEND.
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DRIVER FITNESS MAGIC BODY CONTROL
In the Active Body Con-trol system from Mercedes-Benz, the four spring struts are equipped with hydraulic cylinders (plungers) to ad-just the force in each spring strut individually. This means that the system can almost completely compen-sate for lifting, rolling and pitching of the body. The control unit receives infor-mation on the current driv-ing situation from various acceleration sensors and then compares these data with those from the pressure sensors in the spring struts
and the level sensors on the control arms. The system then computes the control signals for the servo-hydrau-lic valves at the front and rear axle to ensure precisely metered oil flows.
Once oil flows into the plunger cylinders, this modi-fies the tracing point of the steel springs integrated into the spring struts, generating
the necessary force to coun-teract the body movements. Thanks to a constantly avail-able hydraulic pressure of up to 200 bar, ABC is able to stabilise the body within fractions of a second.
Cross-wind stabilisation is a further function of Ac-tive Body Control. When the control detects a strong gust of wind, the wheel load distribution is changed in fractions of a second. This creates a yawing motion of the vehicle which considera-bly reduces the effect of the cross-wind.
The curve inclination function in the new S-Class Coupé is another world first for series production automo-biles. The vehicle leans into bends in a similar way to motorcyclists or skiers. The lateral acceleration acting on the occupants is reduced as when passing through a high-bank curve, and they sit more firmly in their seats. Especially on country roads, the new curve incli-nation function means more driving pleasure and com-fort. The aim is not to achieve higher cornering
speeds, but a new driving experience: the S-Class Coupé glides elegantly through bends.
Depending on the bend to be negotiated, the curve in-clination function modifies the base points of the rele-vant suspension struts. This means that in fractions of a second, the vehicle continu-ously leans into the bend to
an angle of up to 2.5 degrees – depending on the bend radius and road speed. This innovative system recognis-es bends with the help of the stereo camera behind the windscreen, which regis-ters the curve in the road surface up to 15 metres ahead, and using an addi-tional lateral acceleration sensor. The curve inclination function can be selected us-ing the ABC switch, and is active in a speed range of 30 to 180 km/h. ■
CROSS-WINDS ARE ALSO COMPENSATED
THE CAR LEANS INTO THE BEND LIKE A SKIER
CURVE INCLINATION FUNCTION More fun on bends
The ABC system (Active Body Control) independently regulates the oil-flow to the suspension struts at each wheel. The base point of the spring is adjusted. This influences the movement of the vehicle body. The new curve inclination function actively responds to bends recog-nised by the camera and a special lateral acceleration sensor: the body leans into bends at an angle of up to 2.5 degrees, depending on the bend radius and speed. The result is a completely new driving experience, with a reduction of lateral force for the occupants.
Gliding through bends: the vehicle leans elegantly into the bend,
the occupants enjoy a surprisingly new cornering experience
Safely on track in cross-winds: modifying the wheel load distribution counteracts the gust of wind – the vehicle remains on course
Suspension comfort: coping serenely with road surface defects
has always been a strength of saloons from Mercedes-Benz
Wheel actuator: each suspension strut is individually adjustable
by the hydraulics – the base point of the spring is modified
146 147
DRIVER FITNESS FACTS, FIGURES AND CURIOSITIES
54 ACTUATOR MOTORS
As standard, the front seats of the new S-Class are electrically adjustable for travel, height, inclination and seat cushion depth. With full specifications, up to nine seat adjustment motors bring each of the front seats and EASY ADJUST luxury head restraints into the ergonomically right position. Plus there are six seat ventilation motors. In the rear there can be up to twelve motors per seat. All in all, therefore, up to 54 actuator motors take care of the seating comfort of occupants in an S-Class, while two further motors move the steering wheel to the desired position. The seats are adjusted with the help of a design icon: since 1981 the switch has been in the form of a miniature seat.
15 PERCENTInsurers have recognised that assistance systems help to prevent accidents or mitigate their consequences. This also pays off financially for Mercedes-Benz drivers: customers ordering the Driving Assistance package Plus (with the functions DISTRONIC PLUS with Steer Assist and Stop&Go Pilot, Active Blind Spot Assist and BAS PLUS with Cross Traffic Assist) can save 15 percent on their insurance premium.
16 SENSORSIn April 2010 two Mercedes-Benz trucks set off for a historic comparative test drive: the Actros and LP 1620 were sepa-rated by 50 years. The aim was to meas-ure driver stress. Each driver wore an EEC cap with 16 sensors. These were used to register brain impulses and measure response. The result was that the slower processing of impulses in the LP 1620 amounted to up to 400 milliseconds com-pared to the Actros. However, if this value is applied to the sequence “signal-precep-tion-reaction” or e.g. “seeing brake lights, consciously perceiving them and taking braking action oneself”, it means that in a truck travelling at 80 km/h braking action is taken nine metres later.
70 LEDSConsideration for other road users: with so-called multi-level functionality, Mercedes-Benz has achieved another world first in the tail lights of the new S-Class. The 35 LEDs per light cluster (brake lights and indicators) are operated with varying light intensity, depending on the driving situation and ambient lighting (day/night). If the Mercedes-Benz driver presses the brake pedal while stopped at traffic lights at night, for instance, the brightness of the brake lights will be automatically dimmed to avoid dazzling anyone behind.
40 PERCENTOnly 20 percent of car journeys are at night, but they account for 40 percent of fatal accidents - one of the shocking findings by Mercedes-Benz accident research. According to a study by the German Federal Agency for Road Affairs (BASt), five times as many pedestrians are killed on country roads at night as during the day.
5 QUESTIONSIn the mid-1960s the subject of automobile safety became a matter of public concern in view of increasing accident figures. Mercedes-Benz responded with adver-tisements, asking: “Would you rather have a safe car and no dreams than a dream car without safety?” Item 4 is particularly interesting: driver-fitness safety was already in the book of specifications for Mercedes engineers at that time.
DID YOUKNOW?
148 149149148
IMPACT AT 50 KM/HBISON fighting and each weighing up to 900 kg
are reminiscent of the forces involved in a crash test.
Nature neglected to provide a crumple zone
CRAS
H T
ESTI
NGFOR 55 YEARS MERCEDES-BENZ HAS BEEN SYSTEM-
ATICLY TESTING CARS IN CRASHES. FROM THE
START, NOT JUST COLLISIONS WITH A SOLID BARRIER HAVE BEEN A POINT OF FOCUS, BUT
SAFETY IN THE EVENT OF A SIDE IMPACT
WAS ALSO TAKEN INTO ACCOUNT FROM AN EARLY
STAGE. ANALYSING REAL ACCIDENTS LED TO THE
STANDARDISATION OF OFFSET CRASHS.
ANOTHER SYSTEMATIC POINT OF FOCUS ARE CAR VERSUS CAR ACCIDENTS.
Foto
: Don
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M. J
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151150
Small versus large: lightweight, compact cars are at a disadvantage
in the event of an accident if they collide with a considerably
heavier car. Mercedes-Benz designs the bodywork structure of large
vehicles to absorb part of the impact energy of the other vehicle
thus improving the situation for the small vehicle
CRASH TEST PROCEDURES
500 CRASH TESTS EVERY YEAR
ORGANISED DESTRUCTIONWHAT HAPPENS IF AN ACCIDENT CANNOT BE AVOIDED? SINCE
THE 1950s MERCEDES-BENZ HAS CONDUCTED A SOPHISTICATED
SERIES OF TESTS INTO THE CRASH PERFORMANCE OF ITS CARS,
FAR EXCEEDING THE TESTING REQUIRED BY LAW.
152 153
CRASH TEST PROCEDURES
The first impact tests carried out by Mercedes-Benz as
early as the late 1950s were spectacular: winches or hot-water rockets were used to propel the cars. For the roll-over test, the techni-cians built a corkscrew ramp and, for lack of dummies, the
engineers took part in some tests themselves.
Crash tests still form the basis of safety developments at Mercedes-Benz. These days, however, vehicles are accelerated by means of a high-tech cable pulley sys-tem. Every year some 500 impact tests of this kind are carried out at the develop-ment centre in Sindelfingen.
Altogether, new Mercedes-Benz cars must currently pass almost four dozen dif-ferent crash tests.
This is because, as part of an integrated approach to “Real Life Safety”, Mercedes-Benz not only performs crash tests in collision con-figurations prescribed by rating tests and for interna-tional registration – crash
REAL LIFE SAFETY Unusual crash tests
As part of an integrated approach to “Real Life Safety”, Mercedes-Benz not only per-forms crash tests in collision configurations prescribed by rating tests and for inter-national registration – traditionally the test programme has also included Mercedes-Benz test set-ups derived from in-house accident research. At the world’s biggest commercial vehicle manufacturer, these obviously extend to collisions with trucks as well as overturns involving roadsters and cabriolets. At frequent intervals this result-ed in test configurations being adopted subsequently in legislation.
Side impact with deformable barrier: standardised re-creation of a cross-traffic accident. The camera on the bonnet documents what happens Front impact against deformable barrier: standardised re-creation of a rear-end collision at high speed
E-Class versus Actros: when the big saloon becomes the smaller party A “pagoda” overturns: the SL is tipped over with some force
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CRASH TEST PROCEDURES
tests are also derived from in-house accident research by Mercedes-Benz. Require-ments here often go far be-yond those stipulated by legalisation. At times these have set the standard across the automotive industry: in 1979, for example, the offset crash was introduced in-house as a test method that closely approximates reality. Engineer Wolfgang Schwede from the testing department: “Analysis of types of frontal collision occurring on the road shows that (with right-hand traffic) collisions off -set to the left occur most frequently at 50 percent, whereas the collision test
prescribed by law occurs only 25 percent of the time.”
A frontal impact with a contact ratio of 40 percent places enormous stress on the occupant cell. To transfer the forces, engineers devel-
oped the concept of three load paths: the longitudinal forces resulting from the impact are transferred to the sidewall, tunnel and floor. These days, the offset crash is an established legal requirement worldwide.
Until the methodology and collision configurations could be defined, this work was trial and error. Within Europe, crash testing in the 1950s represented an entire-ly new field. Engineers at Daimler-Benz closely watched developments in the United States as crash tests became established there as a new research and develop-ment tool. Visits to American universities and automotive manufacturers gave experts from Stuttgart useful ideas for their own component ex-periments and crash tests. They learned to tackle safety issues head-on. Why? Be-cause the engineers were
BEYOND BARRIERS Crashing car versus car
Mercedes-Benz started crash testing as early as 1959. In the decades that followed stand-ardised tests were designed against barriers. These became established worldwide and found their way into law. Right from the start, accident ex-perts in Sindelfingen were also interested in what happens during real accidents. By the early 1960s, cars were already being crashed into each other or buses in order to recon-struct the reality of such acci-dents. Here too it took some time for criteria to be defined based on findings from re-search into real accidents which would then influence crash test parameters.
MERCEDES-BENZ PIONEERED THE OFFSET CRASH
2004: the smart fortwo’s tridion safety cell demonstrated its protective effect in a crash test against an E-Class
1968: old versus new S-Class. Early on, side impact protection becomes a further focus of development
1962: the “Fintail”, the first car with safety body, hits a bus at 86 km/h
1988: 190 (W 201) versus 200 (W 124). The real side impact shows the development advances which have been made
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CRASH TEST PROCEDURES
convinced that the sharp rise in the number of acci-dent victims was not inevi-table. It was up to them to make cars safer.
However, for a long time they did not have nearly enough knowledge. Com-pared with evaluating a car damaged in an accident, the major benefit of a crash test lies in the ability to record every detail of the actual col-lision in sequence. The ana-lysis equipment for this was developed in the years prior to 1959. It included accelera-tion sensors in dummies and
in the test vehicle itself, as well as high-speed films so that the images needed to analyse the collision could be slowed right down.
Originally the spectacular vehicle tests were conducted outside. The necessary tools to carry them out were rela-tively simple from today’s perspective. Improvisation was the order of the day. A
table would be used as a camera stand or the roof of the measurement bus would serve as an observation plat-form. Filming the course of a collision using high-speed cameras is particularly diffi-cult with variable amounts of cloud. For example, the aperture could be set for sun and the rocket would be ready to go but a small cloud in front of the sun could per-sistently cast a shadow over the test site.
Given the rising number of crash tests and high de-mand for the results of such
TESTING THEN CALLED FOR IMPROVISATION
THE EVOLUTION OF BARRIERS Acid test: the offset crash
Originally, tests were conducted with full contact against a solid barrier. This was later stipulated by legislation, too. Mercedes-Benz accident research, however, showed that offset collisions were twice as common. From 1979, therefore, internal tests were carried out with a contact ratio of 40 percent. In terms of occupant cell stability, this is a tough challenge: a collision at 55 km/h stands for a crash with oncoming traffic. Today a modified offset crash is an established requirement, worldwide.
1987: Coupé C 124 versus a skewed barrier (30° angle), a legal requirement in the USA
1989: the offset crash was an important step. Here a 300 SL (R 129) undergoes testing. Thanks to the inspection pit, the process can also be filmed from below
1968: once the methodology was in place, the researchers wanted to know how early models behave – this is a 170 S from 1951
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NEW CONSTRUCTION
SAFETY CENTREWork on the new vehicle safety tech-nology centre started in July 2013. Following investment worth hundreds of millions of euros, the new building in Sindelfingen is scheduled for comple-tion in mid-2016 and will be 273 metres long, 172 metres wide and up to 23 metres high. With floor space totalling 55,000 square metres, the vehicle safety technology centre will have a test hall covering 8,100 square metres.
CRASH TEST PROCEDURES
experiments, it was clear by the late 1960s that capacity and resources at the old test track in Sindelfingen were too restrictive. A new acci-dent test centre was built in Sindelfingen between 1971 and 1973. The safety researchers initially in-stalled what is known as a Bendix sled for the purposes of accident simulation. To achieve the same accelera-
tion as in a real accident, this sled is not slowed down. Instead it is accelerated, meaning that the direction of movement is reversed. In 1972 work began on building a new crash facility. This would make it possible to ex-amine frontal and side colli-sions, as well as overturns.
High-speed cameras now recorded the whole crash under very bright lights and
CHANGES TO PROPULSION From rocket to linear motor
Initially cars were accelerated using a cable winch. Engineers borrowed the towing technology from glider pilots at Stuttgart’s technical university. From 1962 onwards, a hot-water rocket provid-ed propulsion on the test track, which was by now built of concrete. The rail-mounted rocket accelerated the test vehicle to the desired speed and was then slowed down. Over in the new crash hall, 1973 saw the introduction of a linear motor to propel the test vehicle down a 65-metre test track with the force of 53,000 newtons. The unit accelerated cars to the target speed along the first half of the track, regulated the speed to the desired level along the remaining section and decoupled in time before the collision occurred. From 1998 on-wards, the modernised test centre switched back to using a sophisticated cable pulley system for acceleration purposes. This made it possible to accel-erate two vehicles simultaneously for the car versus car tests.
Ready to ruin: an SLK is prepared for crash testing in 2010. A winch accelerates it into the obstacle
Track extension: the crash track was
100 metres long for the 600 model
Plan: how the new safety centre in Sindelfingen will look in 2016
Indoor testing: from 1973 crash tests were conducted inside
a hall. The new aspect: an electric system of propulsion
On rails: the track-guided rocket has been used to accelerate test vehicles
since 1962. When decoupled, the test vehicle rolls into the obstacle, unpowered
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CRASH TEST PROCEDURES
from various different van-tage points. While the hu-man eye can process only 16 images per second, this high-tech equipment can handle some 1000 images per second. Because the cameras are, of course, digi-tal there is no more waiting for the film to be developed.
A crash test takes just milliseconds, whereas evalu-
ating the data takes several days. What got broken un-derneath the metal of a vir-tually unscathed (outwardly at least) preproduction mod-el? And why? What was the load on the dummies?
Twice a day, the “accident detectives” are fed new in-formation. “In addition to around 500 crash tests car-ried out each year, more
than 50,000 computer simu-lations are generated,” ex-plains Head of Crash Testing Ferdinand Gaiser. Although realistic simulation saves on iterative loops, it can by no means replace conventional testing – of that the engineer is certain: “As a bridge be-tween simulation and reali-ty, the crash test will not be superseded any time soon.”
PLANK TEST Staying on the road
At the Sindelfingen vehicle testing site, numerous tests were conducted for the German Federal Ministry of Transport from 1962 to 1968 to test and specify the crash barriers which are still in use today. Alterna-tives were tried out, such as steel cables tensioned between posts, but these were not able to withstand colliding trucks. For the crash barriers, it soon became apparent that firm anchoring was needed to withstand impact forces. As can clearly be seen from the photograph above, photographic documentation of crash tests still depended greatly on the photographer’s ability to react. It is also interesting to note the number of construction cranes in the background working to extend the Sindelfingen body plant.
Rocket truck: the hot-water rocket brought even this heavily laden truck up to speed for crash barrier tests Breaking through the crash barrier: it was not planned for this “Fintail” to burst through the boundary during crash barrier testing
Testing materials: side crash in 1970 against the plastic body of the C111 research vehicle
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CRASH TEST PROCEDURES
DATA ANALYSIS Recording on tape
When the new crash facility opened in 1974, modern electronics also found their way into safety development. Until that time, analogue data was transferred to the crash vehicles via trailing cables. Due to the increasing number of measuring points, these were getting thicker and more unwieldy all the time. The new fre-quency-division multiple access system featuring integral data storage remedied this situation by relaying four to ten times the amount of data per cable. It was also now possible to save the measured data on tape prior to systematic analysis.
“No one experiences as many accidents as us,” says Gaiser who has worked for Mercedes-Benz since 1991. The cars are not always new: for example, out of interest, some years ago Gaiser and his colleagues crashed a vehicle from the world’s first model series to be fitted with air-bags (W 126). An official car of former Chancellor of Germany Helmut Kohl,
a V 140 model S-Class, also breathed its last breath in the crash test hall in Sindelfingen.
Increased safety will con-tinue to be a key develop-mental goal at Daimler into the future. For that reason, the company is investing hundreds of millions of euros in a new vehicle safe-ty technology centre due for completion in 2016. Con-struction in Sindelfingen
commenced in July 2013. As well as concentrating on passive safety, special attention will be paid here to the requirements posed by new alternative drive system concepts and vehicle technology. Further re-search and development work will also be conducted here into the potential of PRE-SAFE® and assistance systems in the pre-accident and crash phase. ■
Bogie: twice a day, a crash test takes place. Head of Crash Testing Ferdinand Gaiser analyses the results
Control room: using state-of-the-art technology, from 1974 data was recorded onto magnetic tape for subsequent evaluation
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was the VIP 50 model from Alderson Research Laborato-ries. The Daimler engineers called their first dummy “Oskar” and kept it in use for almost 30 years. The front passenger seat was
initially occupied by sand-bags and shop window dum-mies - which failed to yield much in the way of findings.
The dummies’ dimensions and the employed measuring methods quickly diversified and abandoned the standard set by the VIP model, how-
CRASH DUMMIES
MOCK-UP HUMANS
THEY SUFFER FOR USTEST DUMMIES MODELLED ON THE HUMAN
BODY PROVIDE INSIGHTS INTO THE STRESSES
AND STRAINS WHICH APPLY IN AN ACCIDENT.
AS SUCH, CRASH-TEST DUMMIES SYMBOLISE
ACCIDENT RESEARCH PER SE.
The great advantage of a crash test as op-posed to analysing
cars which have been in-volved in accidents lies in the possibility of tracing the actual course of the collision in full detail. The necessary analysis technique was de-veloped in the 1960s. It in-volves dummies which rep-resent the human body.
The initial dummies to be employed had been devel-oped for tests in the aviation industry. They already incor-porated load cells to record acceleration values. The first dummy created specifically for the automobile industry
Dummies with keen senses: Sensors inside the dummy record over
30 different items of data and save them on a data recorder. Sensors
and data memory are checked during preparations for a crash test.
After the crash, the data are read out and undergo further processing
DUMMY OSKAR SPENT 30 YEARS IN RIGOROUS SERVICE
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CRASH DUMMIES
Family get-together: Different
dummies are used for different tests.
Many still transfer their data by cable
ever: the 1960s saw the emergence of dummies which had proportions corre-sponding to the average for men, women and children and which were fitted with flexible joints. The measur-ing accuracy for certain test set-ups also underwent con-tinual improvement – in addition to passenger dum-mies, a test dummy was also introduced for re-creating accidents involving pedestri-ans. Dummies were addition-ally developed to enable par-ticularly accurate assess-ments of specific accident scenarios.
Today’s industry standard is defined by dummies of the Hybrid III family, which was developed by General Motors
in 1976. These constructions consisting of metal, plastic and foam are fitted with numerous measuring probes and cost up to 150,000 euros. Hybrid III is also subject to ongoing development and
can be fitted today with a whole range of sensors in the head, neck, chest, spine, pel-vis and legs. Accelerometers and force sensors are the most commonly used fit-tings. Other standard items are angle gauges for the knee and angular velocity sensors for the head.
ACCELEROMETERS AND FORCE SENSORS PROVIDE INSIGHTS
DUMMY DEN Where the dummies live
The original Hybrid III dummy, which was presented in 1976 as the “50 percent man”, has since acquired an entire family of dummies in many different variants covering different sizes and weights. As the 50 percent man (H III 50%) it measures 175 cm in height and weighs 78 kg, representing the average male car driver. Its big brother (H III 95%) is 188 cm in height and weighs 101 kg. H III 5% represents a short woman (152 cm / 54 kg). There are also three Hybrid III child dummies representing children with a body weight of 16.2 kg (for three year-olds), 23.4 kg (for six year-olds) and 35.2 kg (for ten year-olds).
Not fit for purpose: The originally employed shop window dummies failed to make the grade
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CRASH DUMMIES
The primary advantage of the Hybrid III is its wide-spread use. As a standard-ised test object, its parts can be exchanged between dif-ferent dummies and defec-
tive parts can be replaced on an individual basis. As such, a dummy has more lives than any cat and stays in use over many years.
Dummies nevertheless remain essentially very rudi-mentary, even in their more sophisticated variants. “Joints, muscles, tendons,
ligaments, bones – all the essential biological features of human beings, can only be modelled on a very basic level with dummies,” explains Daimler expert Dr Hakan Ipek. An alterna-tive is THUMS (Total Human Model for Safety) – the model of a virtual human being (see page 23).
In the light of this state of affairs, Oskar and his colleagues are likely to be put out to grass one day. They will certainly have earned their retirement – countless people owe their health and their lives to the tests carried out with the dummies’ help. ■
STANDARDISED REPLACEMENTS FOR A LONG LIFE
GETTING INTO SHAPE Preparing the dummies
In order to obtain reliable test results, the dummies have to be calibrated each time before use. The head of Hybrid III is dropped from a height of 40 cm in an apparatus, for example, in order to set the instruments accordingly. The head is then bolted onto the shoulders and after brief acceleration followed by abrupt braking the flexibility of the neck is checked. The shoulders and head are then connected to the torso which has been subjected to impact from a pendulum in a test apparatus in order to check the flexibility of the thorax.
Calibration: As their name suggests,
side impact dummies (SID) are
used to measure side collisions.
Their special sensors also must be
calibrated, as shown here with
the calibration pendulum
Pedestrians: Tests aimed at improving protection for pedestrians first got underway back in the 1970s
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FOLLOWING AN ACCIDENT
RAPID RESCUEMERCEDES-BENZ’S SAFETY CONCEPT COMPRISES A HOST OF FUNCTIONS TO
FACILITATE CASUALTY RESCUE. THE VEHICLE QR CODE IS JUST ONE. THIS GIVES
THE EMERGENCY SERVICES SWIFT ACCESS TO ALL RELEVANT VEHICLE DATA.
MERCEDES-BENZ ALSO PROVIDES PRACTICAL TRAINING FOR FIRE SERVICES.
OVERVIEW: POST-SAFE functions of the S-Class
Activation of the hazard warning lamps to secure the scene, warn following traffic and protect the occupants from a secondary accident
Activation of interior lighting to help passengers and emergency services at night
The central locking system is unlocked for easier access by the emergency services
Closed side windows are lowered to allow venting of smoke from activated airbag systems and give the occupants a clear view (orientation/avoiding panic)
The electrically adjustable steering column is raised to facilitate rescue or egress by the occupants
The belt buckles on the rear seats are extended and illuminated, allowing easier access to the buckle and thereby facilitating rescue or egress by the occupants
Mercedes-Benz emergency call system activated to notify emergency services of the location and emergency situation and initiate rescue
Automatic engine cut-off to prevent hazards and to stop the vehicle moving unintentionally
High-voltage power supply switched off on hybrid vehicles to cut the voltage to the vehicle during rescue
Swift access to all vehicle data relevant for rescue via a QR code on the fuel filler flap and on the opposite B-pillar
CRASH POST-SAFE
MERCEDES-BENZ EMERGENCY CALL SYSTEM Help at the scene, fast
In combination with COMAND Online, the brand’s new models are equipped with the Mercedes-Benz emergency call system. If COMAND Online is connected to a mobile phone, the emergency services can be rapidly and automatically alerted in the event of a serious accident. After the airbags or the pyro-technical belt tensioners are triggered, the vehicle’s exact GPS position and vehicle identi-fication number (VIN) are sent by SMS to a special emergency centre, with positional data also being transmitted using the DTMF method (dual-tone multi-frequency) at the same time. On receiving the call, the emergency centre establishes voice contact with the vehicle occupants in a matter of seconds.
Digital rescue card: Mercedes-Benz is equipping new
models with a QR code. Using a smartphone or tablet,
this allows the emergency services to access a rescue
card for the specific model. This card contains all the
information needed to rescue casualties quickly
CRASH POST-SAFE
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CRASH POST-SAFE
SAFETY CAR Increased safety in Formula One
When it comes to safety in motorsport, Mercedes-Benz is out in front: for the 18th year in a row, in 2013 performance brand AMG has supplied the official Formula One Safety Car and the official Formula One Medical Car. The stewards always deploy the SLS AMG GT and the C 63 AMG Estate if bad weather or unusual occurrences pose a threat to race safety. The job of these cars is to guide the Formula One field safely around the course until the hazardous situation is averted.
Mercedes-Benz coaches the emer-gency services: in
practical training sessions, fire services are able to learn and apply various rescue options relating to the latest models from Mercedes-Benz and smart. Under the guid-ance of experienced, special-ly trained Daimler employ-ees, the fire services practise the correct handling of vehi-cles that have been involved in an accident.
Attention is paid to de-tailed aspects: where should spreaders or expanders be positioned? Where are the sections of bodywork located which are made of ultra-high performance steel grades to optimise passive safety, but which may make it more difficult to cut through the vehicle body? Where are the gas generators for the side airbag or windowbag? If possible, these should not be damaged during a rescue operation. Andreas Wilhelm, a member of the Baden-
Baden fire service, describes the importance of these training sessions: “Daimler offers us unparalleled practi-cal training. It is particular-ly important to familiarise ourselves with handling the most modern vehicles under rescue conditions. Normally we have to conduct such exercises using old, scrap cars which are technologi-cally outdated and enable only limited preparation for call-outs.” ■
Firefighter drill: during practical training exercises, the emergency services are able to practise
how best to get into the cab of a truck which has been involved in an accident
Destruction for a good cause: The exercises cover the most effective places to position spreaders and expanders
Leadership: The official Formula One Safety Car is driven by Bernd Mayländer
Phot
o: p
ictu
re a
llian
ce /
dpa
174 175
CRASH FACTS, FIGURES AND CURIOSITIES
30 TONNESIn the early years, a concrete block weighted down with old pressing tools acted as a mobile barrier for collisions. This 30-tonne, heavy monster was cleverly fixed in place by letting the air out of the tyres.
4 CANSBefore the Bendix simulator was operational, in the 1960s accident researchers used a spring-loaded test sled to provide acceleration for component tests. This helped them to optimise steering systems and seat belts, for example. Large gherkin cans from the works canteen were used to create a crumple zone. Taking the cue from these cans, the inventor of the cost-saving crashboxes was nicknamed “Canned Maier”.
260 DEGREESNow and again you need to know how competitor vehicles are performing, too. Here a Beetle waits to take its final journey. The hot-water rocket used for propulsion is fitted onto a single-axle trailer and consists of a pressure tank, a quick-opening valve and a rocket nozzle. To produce thrust, prior to the experiment the vessel is filled about three quarters full with water and heated until the water reaches a temperature of around 260 degrees Celsius. When the valve is opened, the resulting excess pressure propels the vehicle and rocket and accelerates the entire unit to more than 100 km/h.
16.472 KILOMETRESIn the first few years, test vehicles were not guided along the track but instead just their steering was fixed. As a result, some test vehicles missed the barrier or corkscrew ramp and instead landed in the stream next to the test track. Unlike this car, which is going nowhere, the Schwippe flows for another 16.472 kilometres until it joins the Würm river.
2,400 YEARSTest sleds or catapults have been used for component testing since the early 1960s. In 1972 Daimler installed a Bendix accident simulator into the new safety centre in Sindelfingen in order to test restraint systems, steering systems, seats, instrument panels and roof racks. Cameras are installed on the side arms. The catapult was invented in Greece in 400 BC (from the Ancient Greek “katapeltes”, “kata” meaning “downwards” plus “pallein” meaning “to hurl”).
1979What actually happens when an airbag is deployed? Brave engineers found out the answer to this question by taking part in many tests themselves while the passenger airbag was developed in the late 1970s. Cameras mounted on the side arms recorded what happened in minute detail.
DID YOUKNOW?
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OUTLOOK XXXXXXXXXXX
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SWARM INTELLIGENCEAn estimated 50 billion MIGRATORY BIRDS fly back and forth
between their breeding grounds and winter quarters each year. In
these flocks, each bird takes its lead from its neighbour and
adopts the same speed and direction. Formation flying protects
against predators and saves energy.
OUTL
OUTL
OOK
THE FUTURE HAS ALREADY BEGUN: CAR-TO-X COMMUNICATION PLAYS AN IMPORTANT
ROLE WHEN IT COMES TO THE VISION OF ACCI-
DENT-FREE DRIVING. AND THE MERCEDES-BENZ S 500
INTELLIGENT DRIVE RESEARCH VEHI-
CLE SHOWS THAT IN PRINCIPLE, AUTONO-MOUS DRIVING IS ALREADY POSSIBLE TO-
DAY EVEN IN INTER-CITY AND URBAN TRAFFIC. Phot
o: L
u/V
iew
stoc
k/C
orbi
s
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OUTLOOK CAR-TO-X COMMUNICATION
CAR-TO-X COMMUNICATION
VEHICLES IN A DIALOGUEINTELLIGENT NETWORKING OF CARS WITH EACH OTHER AND
WITH THE INFRASTRUCTURE CAN HELP TO PREVENT ACCIDENTS
AND TAILBACKS. BEGINNING IN 2013, MERCEDES-BENZ BRINGS
RADIO-BASED CAR-TO-X TECHNOLOGY ONTO THE ROADS. AS AN
INITIAL STEP THE DRIVE KIT PLUS IS USED WHICH, IN COMBINA-
TION WITH A SMARTPHONE AND THE DIGITAL DRIVESTYLE APP
DEVELOPED BY MERCEDES-BENZ, TURNS THE VEHICLE INTO A
SIMULTANEOUS TRANSMITTER AND RECEIVER OF INFORMATION.
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OUTLOOK CAR-TO-X COMMUNICATION
Every driver has expe-rienced potentially dangerous situations
like this: accidents and tail-backs are often only report-ed on the radio after a delay of several minutes. This is where Car-to-Car communi-cation can help: because vehicles networked with each other can exchange information very rapidly to warn drivers.
By integrating Car-to-X communication into the Drive Kit Plus and the Digital DriveStyle App, Mercedes-Benz offers
the new technology on a universal basis in almost all Mercedes-Benz passenger cars since the end of 2013.
If a vehicle is reported to have broken down in the driver’s vicinity, a warning is given and the location of the danger is marked on the map. Moreover, every vehicle equipped with Car-to-X technology can also send hazard warnings to other road users. Mercedes-Benz passenger cars are able to recognise many of these events automatically by virtue of seamless integra-tion of the Car-to-X system into the vehicle systems. A manual reporting option has been developed for hazards that are not or not
yet detectable automatically. At the touch of a button, e.g. vehicles travelling the wrong way or shed loads can be reported to the Mercedes-Benz Cloud. A warning mes-sage to all vehicles fitted with Car-to-X technology which are in the vicinity is sent.
As a next step Car-to-X technology will also contrib-ute to more efficient mobili-ty, as e.g. highly accurate traffic situation information is used to improve traffic flows by controlling traffic light systems to suit. ■
One of the world’s largest field trials recently demon-strated that Car-to-X communication is mature enough for day-to-day motoring: during the research projekt simTD (Safe Intelligent Mobility – Trial in Deutschland/ Germany) under the aegis of Daimler AG, a total of 120 cars and three motorcyles were on the roads in the Rhine-Main region between August 2012 and June 2013. All the vehicles were equipped with the same technology. All in all more than 1,650,000 kilometres were covered during this field trial – on the A5 motor-way, on federal highways B3 and B455, and in the in-ner-city area of Frankfurt. The vehicles and infrastructure were networked with the help of so-called “ITS Roadside Stations”. The stations were in contact with the local traffic control systems, but could also receive signals from the test vehicles and send signals to them. The simTD project is a joint project between German automobile manu-
facturers, automotive suppliers, communication companies, research institutes and the public sector. Daimler is also researching and developing C2X com-munication in the USA. At the location in Palo Alto, California, for example, vehicles have likewise been equipped with C2X systems and put through trials. Apart from its involvement in the simTD research project and the research in the USA, Daimler’s strong commitment to C2X communication is shown by many years of participation in other projects in this field. For example, the company was the initiator of basic research projects such as NoW (Network on Wheels) and Fleetnet, whose results have been incorporated in-to the present C2X activities and their standardisation. Daimler is also a founding member of the CAR 2 CAR Communication Consortium (C2C CC), and is driving the Europe-wide harmonisation of this technology forward in the DRIVE C2X project.
TRAFFIC LIGHT, THIS IS CAR, over and out
Drivers do their share: accidents and breakdowns can be
reported manually so that other road users are warned
Attention, emergency vehicle coming from the right: warnings like this are
possible if police and emergency vehicles are equipped with Car-to-X technology
Time saving: with the use of Car-to-X technology, information about potential hazards to road traffic,
e.g. a vehicle travelling the wrong way, is rapidly and precisely relayed to other road users affected
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OUTLOOK AUTONOMOUS DRIVING
AUTOPILOT
THE SELF-DRIVING CAR
IN AUGUST 2013, WITH ITS S 500 INTELLIGENT DRIVE RESEARCH VEHICLE, MERCEDES-BENZ
BECAME THE FIRST MOTOR MANUFACTURER TO DEMONSTRATE THE FEASIBILITY OF AUTONOMOUS
DRIVING ON BOTH INTERURBAN AND URBAN ROUTES. THE ROUTE IN QUESTION, COVERING
THE 100 KILOMETRES OR SO FROM MANNHEIM TO PFORZHEIM, RETRACED THAT TAKEN BY BERTHA
BENZ WHEN SHE BOLDLY SET OFF ON THE VERY FIRST LONG-DISTANCE DRIVE.
The main advantages of autonomous driving are plain to see: it al-
lows motorists to reach their destination quickly, safely and in a more relaxed frame of mind. Above all on routine journeys, in traffic jams, on crowded motorways with speed restrictions and at ac-cident blackspots, an autono-
mous vehicle is capable of assisting the driver and taking over tedious routine tasks. Partially automated driving is already available to drivers of new Mercedes-Benz E- and S-Class models: The new DISTRONIC PLUS with Steer Assist and Stop&-Go Pilot is capable of steer-
FOLLOWING THE TRACES of Bertha Benz
The research vehicle was equipped with a further development of near-series sensor systems. For example, the developers taught this technology platform to know where it is, what it sees and how it should respond of its own accord: with the aid of its highly automated “Route Pilot”, the vehicle was able to negotiate its own way through dense urban and rural traffic.
Hands off the wheel: in an emergency the test drivers would have been able to intervene at any time. The red button is used to stop the autopilot
Zebra-crossing: a major challenge in urban traffic
Overtaking and cutting in: complex interurban traffic
FASTER AND MORE RELAXED ARRIVAL
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OUTLOOK AUTONOMOUS DRIVING
AUTONOMOUS AT JUNCTIONS S 500 INTELLIGENT DRIVE observes right-of-way rules
The maps created for autonomous driving list all junctions and traffic signs in effect there. When the car approaches such a location, it uses its radar sensors and cameras to examine the surroundings. Approaching vehicles are recognised, and the right-of-way rules are obeyed as the car autonomously responds to the traffic situation
AUTONOMOUS NEGOTIATION OF ROUNDABOUTS Aware of other cars
The vehicle recognises a roundabout by the map data. The surroundings are checked with the help of the radar sensors. The car stops if another car on the roundabout is approaching and there is insufficient space to join the flow. Otherwise the roundabout is crossed autonomously
TRAFFIC-LIGHT RECOGNITION Green light
The exact positions of all traffic-lights on the test route are stored in the map material. A colour camera behind the windscreen recognises the status of the relevant traffic-light. If the traffic-light is amber or red, the vehicle brakes autonomously and only resumes its journey autonomously once the light changes to green
ing the vehicle mainly au-tonomously through traffic jams (see page 140).
The next step is highly automated driving where the driver no longer needs to monitor the vehicle continu-ously. In August 2013, with the S 500 INTELLIGENT DRIVE research vehicle, Mercedes-Benz demonstrat-ed that this is already possi-
ble today, beyond closed-off test routes and comparative-ly clear situations. In the heavy traffic of the 21st cen-tury the self-driving S-Class had to deal autonomously with a number of highly complex situations – traffic lights, roundabouts, pedes-trians, cyclists and trams. It should be noted that this pioneering achievement was
not realised with the use of extremely expensive, special technology, but with near- series technology. It is al-ready available in similar form in the new C-, E- and S-Class. The project thus marks a milestone along the way that leads from the self-propelled (automobile) to the self-driving (autono-mous) vehicle. ■
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OUTLOOK INTERVIEW
RALF G. HERRTWICH
“AUTONOMOUS DRIVING IS COMING”
AN INTERVIEW WITH THE HEAD OF DRIVER ASSISTANCE
AND SUSPENSION SYSTEMS AT DAIMLER ADVANCE DEVELOPMENT
Many people still need to get used to the idea that cars are able to drive around autonomously. Do we actually need cars that drive autonomously?Herrtwich: This is unavoidable if we re-ally want to make the vision of acci-dent-free driving a reality. Systems we have already introduced in our cars
quite clearly show that autonomous braking when an impending accident is detected provides an evident safety ben-efit. Also, the driver is relieved of stress in situations where driving becomes te-dious. The Stop&Go Pilot in the S-Class is the best example of this.
Do you find that customers accept to-day’s assistance systems? Or do you have to battle with scepticism?Herrtwich: At first there was scepti-cism, no doubt about it. And incidental-ly it was no different when ABS and ESP® were introduced. But as the tech-nical performance of these assistance systems improves, driver confidence in them is gradually increasing and they
are more and more interested in the subject. Driver assistance systems have now become a very important competi-tive factor.
But we still have a long way to go, do we not, from assisting drivers in stop-and-go traffic to the completely auton-omous driving that you demonstrated on the Bertha-Benz route in August 2013?Herrtwich: This is a long journey which we are undertaking in stages. Our spe-cific vision for the next step is autono-mous driving on motorways, and we think this can be realised early in the next decade. In principle we already have the sensor systems for this on board, in the form of the stereo camera and radar sensors. It is now a matter of intensive trials, so that we can be sure that the signal processing also delivers the right results at higher speeds.
And what about autonomous driving off the motorway?Herrtwich: That is a far more complex matter. In this case we need much more information about the car’s surround-ings. Oncoming traffic, pedestrians, cy-clists and children playing; traffic lights, junctions and roundabouts, etc., can only be negotiated if the vehicle precisely knows the route it is to cover autonomously. That is also how we pre-pared for the Bertha Benz drive – the S-Class learned the route intensively be-forehand. To give you an idea of the time perspective before cars can drive anywhere autonomously: I think this will still take a good 20 years.
Of course there are legal questions to be resolved as well as technical issues.Herrtwich: Quite right. Autonomous driving is still a grey area today, as practically all traffic regulations world-wide stipulate that a driver must have control over the vehicle. One could ar-
gue that this is in fact the case with au-tonomous driving: at least in our vehi-cles, the computer can after all be switched off by the driver at any time. But without doubt this is a different form of control than we are accustomed to. In order to stay on the safe side with respect to current legislation, we meas-ure the driver’s steering impulses when the Stop&Go Pilot is in operation – if the driver’s hands are not on the wheel, the system is switched off after a short time. Naturally we do not expect things to remain like this in the mid-term, however: legislation is always adapted in line with technical progress, and that will be the case here too. We would not be working in the field of autonomous driving if we had no solutions in mind for these and other technical and legal questions. ■
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Prof Ralf G. Herrtwich (51) has worked at Daimler AG Group Research since 1998. Holding a diploma in Information Technology, he began his career at the Technical University of Berlin and at UC Berkeley.
This was followed by management positions with IBM and several telecom-munications companies. After ten years as Head of Advance Development for Infotainment and Telematics, he is currently responsible for Driver Assistance and Suspension Systems, and in this function for future safety and comfort innovations at Mercedes-Benz. Since 2009 Herrtwich has also been an Honorary Professor for Vehicle Information Technology at the Technical University of Berlin.
Following the trail of Bertha Benz:
Ralf Herrtwich was responsible for the autonomous
drive undertaken in the S 500 INTELLIGENT DRIVE
A route learned by heart: the driver did not
need to intervene during the demonstration
drive from Mannheim to Pforzheim
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1968As yet the Vienna Convention on Road Traffic of 1968 forbids driverless vehicles. Clause 5 of the Convention reads: “Every driver must have control of his vehicle at all times or be able to lead his animals”. In addition every vehicle on the road must have a driver. Experts expect the Convention to be revised fairly soon.
100 TEST SUBJECTSJust as when the automobile was originally invented, it will first be necessary to build up confidence in the technical capabilities of the systems. This is borne out by a recent study carried out by the Customer Research Centre at Mercedes-Benz involving around 100 test persons aged between 18 and 60. The initial scepticism of the study participants was almost entirely dispelled following an autonomous drive in the driving simulator. Even among those participants who were negatively disposed to begin with, there was a significant increase in acceptance after the drive in the simulator.
300 GIGABYTESTo enable the developers to reconstruct the decisions made by the autonomous S 500 INTELLIGENT DRIVE research vehicle in individual driving situations, the car recorded all its sensor data. Images from the stereo camera alone generated 300 gigabytes of data every hour.
OUTLOOK FACTS, FIGURES AND CURIOSITIES
25 YEARS AGOThe research project EUREKA- PROMETHEUS initiated by Daimler-Benz in 1986 was an early milestone. The test vehi-cles made newspaper head-lines in 1994, when they cov-ered around 1,000 kilometres mainly autonomously on a multi-lane motorway in the greater Paris area, and in 1995 when they drove from Munich to Copenhagen.
95 PERCENTWell over 95 percent of all day-to-day journeys are on routes which a vehicle has already covered before. Like a human, a vehicle equipped with a corresponding sensor system should therefore be able to learn a route by heart. At the “driveU” innovation centre founded by Daimler and the University of Ulm in 2012, scientists are therefore also researching into how such background knowledge stored by the vehicle might be used.
1.5 MILLION EUROSIn the Villa Ladenburg project, the Daimler and Benz Trust supports the scientific analysis of social effects arising from autonomous driving. The Trust supports scientists intensively concerned with the subject of autonomous driving to the tune of around € 1.5 million. At the end of the two-year support period, these specialists will submit a white paper with a com-prehensive overview of autonomous driving.
155 TRAFFIC-LIGHTS125 years after the first long-distance automobile journey by Bertha Benz and her sons, Mercedes-Benz developers with the S 500 INTELLIGENT DRIVE research vehicle covered the route from Mannheim to Pforzheim autonomously. There were a total of 155 traffic-lights and 18 roundabouts on the roughly 100 km route.
DID YOUKNOW?
191190
RECALL HERITAGE
THE KEY MILESTONES
PACEMAKER FOR SAFETYMERCEDES-BENZ IS THE PIONEER OF AUTOMOBILE SAFETY. NO OTHER
AUTOMOTIVE BRAND RESEARCHES AS INTENSIVELY IN THIS FIELD,
AND HAS BROUGHT AS MANY KEY INNOVATIONS TO MARKET. SINCE THE
INVENTION OF THE AUTOMOBILE IN 1886, MERCEDES-BENZ AND ITS BRAND
PREDECESSORS HAVE MASSIVELY INFLUENCED THE DEVELOPMENT OF
ACTIVE AND PASSIVE SAFETY, AND REPEATEDLY REDEFINED THE STANDARDS.
1900 Wilhelm Maybach develops the Mercedes 35 HP as a vehicle with exemplary handling stability. Contributing features are the long wheelbase, the low centre of gravity, the engine bolted to the frame and the wide track.
1921 The Mercedes 28/95 HP gets front wheel brakes. The other car models of DMG (Daimler Motoren Gesellschaft) and Benz & Cie. follow in 1923/24.
1931 The Mercedes-Benz 170 (W 15) is the first series production car with a hydraulic braking system and independent suspension using swing axles at the front and rear.
1941 Patent no. 742 977 dated 23 February 1941 is granted for the platform frame developed by Béla Barényi.
1945 In this and subsequent years Béla Barényi develops the vehicle studies “Concadoro” and
“Terracruiser”. Both studies are among the most important stepping-stones towards the safety bodyshell of cellular construction.
1949 Patent no. 827 905 dated 23 April 1949 is granted for the conical pin door lock.
1952 Patent no. 854 157 dated 28 February 1952 is granted for the safety bodyshell with a rigid passenger cell and crumple zones. In 1959 it is employed in the Mercedes-Benz W 111 series.
1954 The W 180-series Mercedes-Benz 220a is given a single-joint swing axle with a low pivot point.
1958 Patent no. 1 089 664 dated 2 July 1958 is granted for the wedge-pin door lock. In 1959 it is introduced as standard in the “Fintail” (W 111) models.
1959 Systematic accident research using crash tests and dummies commences.
Around 50 years of passenger car safety development: from the world’s first car with a crumple zone (model 220) to the C-Class (W 204) Exemplary roadholding thanks to highly sophisticated suspension geometry: Mercedes 35 HP from 1900
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RECALL HERITAGE
1959 The Mercedes-Benz W 111 series (“Fintail”) is the first to feature a safety bodyshell, an interior designed to prevent secondary injuries and wedge-pin door locks.
1961 Disc brakes and dual-circuit braking systems are gradually introduced into the passenger car range.
1966 Hans Scherenberg and Béla Barényi formulate the distinction between active and passive safety that remains valid until the introduction of PRE-SAFE®.
1967 The safety steering system with a telescopic steering column and impact absorber is introduced into the entire Mercedes-Benz passenger car range.
1971 An extensive package of active and passive safety features has its debut in the 107-series Mercedes-Benz SL: collision-protected fuel tank above the rear axle, heavily padded dashboard, deformable or recessed switches and controls,
four-spoke safety steering wheel with an impact-absorbing boss and a wide bolster plate, newly developed air deflectors on the A-pillars and large rear lights with a ribbed surface profile to substantially prevent soiling.
1976 The “Safety steering shaft for automobiles” patented by Béla Barényi in 1963, with a steering column in the form of a corrugated tube, has its debut in the Mercedes-Benz W 123 series.
1978 The second-generation anti-lock braking system ABS celebrates its debut in the W 116-series S-Class. Mercedes-Benz had already presented a first version not yet up to series production maturity in 1970. From 1980 ABS is standard equipment in all model series.
1979 The W 126-series Mercedes-Benz S-Class is the first car constructed to cope with an asymmetrical frontal collision employing a forked front member structure.
1981 The world’s first driver airbag is introduced in the S-Class. Mercedes-Benz has conducted research into this supplementary restraint system since 1968. From 1982 the driver airbag becomes available for all models, followed by the front passenger airbag in 1987 and the sidebag in 1995.
1982 The multi-link independent rear suspension is introduced in the Mercedes-Benz 190 (W 201).
1989 The new SL Roadster (R 129) sees the debut for a seat-integrated belt system and a rollover bar that automatically extends when a rollover threatens.
1995 Rain sensor and xenon headlamps are intro-duced in the 210-series Mercedes-Benz E-Class.
1995 The Electronic Stability Programme ESP® is introduced as standard in the 140-series S-Class Coupé.
1996 Mercedes-Benz introduces Brake Assist BAS into series production as a world first.
1997 The sandwich floor of the W 168-series A-Class allows the engine to slide beneath the passenger cell during a frontal collision.
1998 The windowbag has its premiere as an optional extra for the Mercedes-Benz S-Class.
1999 The proximity control system DISTRONIC has its debut.
1999 The active suspension system ABC (Active Body Control) enters series production in the C 215-series CL-Class.
1999 Bi-xenon headlamps become standard equipment in the 215-series CL-Class.
2001 Head-thorax sidebags are introduced in the SL-Class Roadsters from Mercedes-Benz.
2002 The preventive occupant protection system PRE-SAFE® is introduced in the Mercedes-Benz S-Class, gradually followed by the other model series.
First trials of the airbag: the development of the airbag by Mercedes-Benz began as early as 1968. Pictured here is a crash test in 1969 Shorter braking distance, improved directional stability: ABS tests in the 1970s with an S-Class (W 116)
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RECALL HERITAGE
2003 The active light function with bi-xenon head-lamps is introduced (211-series E-Class).
2005 The integral safety concept of Mercedes-Benz combines the different active and passive safety systems.
2005 Mercedes-Benz presents various safety systems in the 221-series S-Class, for example DISTRONIC PLUS, Brake Assist BAS PLUS and Night View Assist.
2006 The Intelligent Light System ensures optimum light distribution on the road surface, depending on the driving situation (in the 211-series E-Class).
2006 PRE-SAFE® Brake celebrates its premiere as an optional extra for the 216-series CL-Class.
2007 Blind Spot Assist has its debut as an optional extra in the S-Class and CL-Class.
2009 The drowsiness detection system ATTENTION ASSIST has its debut in the 212-series Mercedes-Benz E-Class.
2009 Crosswind Assist has its debut as an additional function of Active Body Control (ABC) in the
face-lifted 221-series Mercedes-Benz S-Class. In addition Torque Vectoring Brake enters series production.
2010 World premiere of Active Blind Spot and Active Lane Keeping Assist in the CL-Class (C 216) and S-Class (W 221).
2011 The radar-based assistance system COLLISION PREVENTION ASSIST is introduced as standard in the B-Class.
2013 New assistance systems with considerably extended functions (DISTRONIC PLUS with Steering Assist and Stop&Go Pilot, Brake Assist BAS PLUS with Cross-Traffic Assist, Active Lane Keeping Assist, Adaptive Highbeam Assist Plus, Night View Assist Plus, ATTENTION ASSIST) are introduced in the S-Class. New PRE-SAFE® functions (PRE-SAFE® Brake, PRE-SAFE® PLUS, PRE-SAFE® Impulse), improve protection in the rear (belt buckle extender with PRE-SAFE®, beltbag).
2013 Mercedes-Benz brings Car-to-X communication onto the roads.
2014 The QR code sticker allowing the emergency services direct access to the vehicle-specific rescue card also becomes available for retrofitting in older Mercedes-Benz models. ■
COLLISION PREVENTION ASSIST as standard in the compact class: Mercedes-Benz B-Class (2011)
IMPRINT
Publisher Daimler AG Global Communications Mercedes-Benz Cars D-70546 Stuttgart www.media.daimler.com
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