16th eth-conference on combustion generated … eth-conference on combustion generated nanoparticles...
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16th ETH-Conference on Combustion Generated Nanoparticles Zurich, Switzerland June 24th – 27th 2012
REAL-WORLD PARTICULATE EMISSIONS FROM A 2010 COMPLIANT HD DIESEL
TRUCK TRAVELING ACROSS THE CONTINENTAL UNITED STATES. Marc C. Besch1, Arvind Thiruvengadam1, Daniel K. Carder1, Adewale Oshinuga2, Alberto Ayala3, and Mridul Gautam1 1West Virginia University, Dept. of Mechanical & Aerospace Engineering, Morgantown, WV 26506 2South Coast Air Quality Management District, Diamond Bar, California 3California Air Resources Board, Sacramento, California Contact information; Phone: 001 (304) 293-5913 E-mail: [email protected] Extended Summary Engine manufacturers across the US and Europe introduced advanced aftertreatment systems, most commonly comprising Diesel Particle Filters (DPF) and Selective Catalytic Reduction (SCR) systems in order to comply with latest heavy-duty (HD) on-road emissions legislations. With exception of the upcoming Euro VI regulation (2014), current standards do not include limitations for nanosized particle emissions which have been identified by the health science community to increase both morbidity as well as mortality in humans and putting especially the population living in close proximity to major road ways and in densely populated urban areas at elevated risk. Indeed, researchers [1, 2 and 3] reported an increase in nanoparticles from catalyzed DPF’s for exhaust temperatures above 380°C even for engines operating on Ultra Low Sulfur Diesel (ULSD) fuel. It has been suggested that these are sulfuric acid-based particles formed as a result of sulfur oxidation (mainly originating from lube oil) over the catalytic surface of DPFs at high temperatures. Furthermore, the introduction of SCR systems augmented the possibility of formation of new particles caused by the ammonia based Diesel Exhaust Fluid (DEF) injection [4].
This work is aimed at gaining insight into real-world particle matter (PM) emissions including both, gravimetric and number specific aspects, from a 2010 compliant heavy-duty Diesel (HDD) tractor equipped with advanced aftertreatment technology. Acquired data allows for, however is not limited to, i) comparison of in-use PM emissions with engine dynamometer based US EPA 2010 emissions certification standards, ii) quantification of PM mass emitted during Not-to-Exceed (NTE) events, and iii) calculation of particle concentrations with regard to the particle number (PN) limit as will be introduced by the EURO VI legislation in 2014. Specifically, a Mack® heavy-duty Diesel Class-8 tractor equipped with a model year (MY) 2011, 12.8liter (MP8-445C) engine, a diesel oxidation catalyst (DOC), a state of the art catalyzed DPF, and liquid urea based SCR aftertreatment system (see Table 1) was under investigation while traveling across the continental US. The tractor was coupled to a flatbed trailer loaded with WVU’s Transportable Emissions Measurement System (TEMS) that houses a full-flow CVS tunnel and a multitude of analytical instruments for gaseous and PM emissions characterization, amounting to a gross vehicular weight (GVW) of 66,740lbs.
The driving conditions ranged from the smooth hills of the Appalachian Mountains, the flat steppes of the mid-west, the Rocky Mountains all the way to the busy highways of the greater Los Angeles metropolitan area, resulting in a multitude of operating conditions induced to the aftertreatment system. The total trip distance between Morgantown, WV and Riverside, CA, as shown on the map in Figure 1, was 2450 miles, resulting in a six days journey. Furthermore, the route provided with a range of environmental conditions, including temperature variations from 3 to 36°C (37 to 97°F), relative humidity variations from 12 to 78% as well as changes in ambient pressure between 65.5 to 100.5kPa. Figure 2 depicts the elevation profile of the route as a function of driving distance. The overall net change in elevation between Morgantown and Riverside is only -57ft (final destination lower than start Morgantown), with the highest encountered elevation being ~11,990ft during the Loveland Pass, CO crossing. Note that the elevation profile shows driving from right to left, same as for the map in Figure 1.
See Figure 3
Figure 1: Driving route between Morgantown, WV and Riverside, CA (Google maps)
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Figure 2: Elevation profile between Morgantown, WV and Riverside, CA
Particulate matter sampling and characterization was performed within the raw and diluted exhaust gas streams. For the purpose of diluted measurements, the exhaust stream was ducted from the vehicle’s exhaust stack into the full-flow CVS tunnel of the TEMS which was commissioned and operated according to recommendations outlined in 40 CFR 1065. PM was sampled onto 47mm PTFE-coated glass fiber filters (TX-40, Pall Corp.) using a secondary dilution system, for subsequent gravimetric analysis. Particle number concentrations and size distributions were measured directly from the CVS tunnel using an Exhaust Emissions Particle Sizer (EEPS™) spectrometer from TSI Inc. (model 3090), operating at 10Hz.
Additionally, a slipstream was extracted directly from the truck’s exhaust stack in order to quantify gravimetric Not-to-Exceed zone PM emissions using Horiba’s portable Transient PM Emissions Measurement System (OBS-TRPM). The OBS-TRPM is a combination of a proportional dilute sampling system for gravimetric PM sampling on 47mm filter media (TX-40, Pall Corp.) and real-time measurements of particle length [mm/cm3] (including soot, sulfates and volatile particles), which can be defined as the product of total number concentration and average particle diameter, by means of a diffusion charging type sensor called Electrical Aerosol Detector (EAD) from TSI Inc. The underlying assumption is that the mass accumulated on the filter is proportional to the PM length parameter as measured by the EAD, therefore, making the OBS-TRPM ultimately capable of calculating a quasi “real-time” PM mass concentration rate.
To assess real-time particle numbers and mass from the raw exhaust an in-line particle sensor from Pegasor Ltd., Finland, (Pegasor Particle Sensor, model PPS-M) was installed within the exhaust stack downstream the aftertreatment systems. The sensor detects particles based on the escaping current principle at a sample rate of 10Hz and is designed as a flow through device. The sensors output can be subsequently correlated to other aerosol instruments by means of simple linear regression in order to
Morgantown, WV Las Vegas, NV
Riverside, CA Grand Junction, CO
Terre Haute, IN Salina, KS Denver, CO
See Figure 3 for detailed view of this
portion of route
measure the concentration of the mass, surface or number of the exhaust particles, depending on the chosen reference instrument.
Results show a predominant mono-modal particle distribution with a count mode diameter (CMD) in the range of 6.04-15nm and a stable peak number count on the order of 2 x 108 [particles/cm3] during periods where exhaust gas temperatures exceed ~340°C as can be seen from Figure 3. Note that the number concentration displayed on the z-axis (dN/dlog(Dp)) in Figure 3 is not corrected for dilution ratio of the CVS tunnel. Figure 4 depicts a normalized exhaust gas temperature histogram for the DPF inlet location from continuous data of the entire route. It can be seen that the temperature of the exhaust stream entering the DPF is exceeding 350°C for ~45% and is between 350-400°C for ~36% of the entire test route, respectively, indicating a favorable temperature range for possible nanoparticle formation over the catalyzed DPF via possible sulfur oxidation [2, 3].
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Figure 3: a) Elevation profile for 30min highway section after Denver, CO climbing I-70 into Rocky Mountains (see), b) corresponding particle number and size distribution as measured by EEPS™, data not
corrected for CVS dilution, red circle indicating DPF regeneration event.
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Figure 4: Normalized exhaust gas temperature histogram for DPF inlet location, data from entire route
between Morgantown, WV and Riverside, CA
Increased particle number concentrations with a CMD in the size range of 30-40nm were observed periodically during the trip as indicated by a red circle in Figure 3. These events coincided with an increase in in-line particle sensor (PPS) signal along with a reduction in relative DPF soot load, a parameter publicly broadcasted by the engine control unit (ECU) and indicating the percentage of soot loading within the DPF relative to the maximum allowable soot loading value as defined by the engine manufacturer. Based on these data, it was concluded that the increased particle concentrations were indicative of DPF regeneration events.
Finally, Figure 5 depicts distance-specific PM mass emissions in [g/mi] for selected sections along the test route. The PM mass values presented in Figure 5 were not corrected for CVS background PM values which was judged valid since a “clean” CVS tunnel (no prior PM deposition that could re-entrain during the test) was utilized and the dilution air was being filtered by high-efficiency particulate air (HEPA) filters with a minimum collection efficiency of 99.97% prior to entering the CVS. It can be seen from Figure 5 that on average the distance specific PM mass emissions remained below 0.05 g/mi. Test sections with increased PM mass values as seen for test IDs C0035-002-64, 72, and 73 correspond to test portions where increased particle number concentrations in the 30-40nm (CMD) range and in-line particle sensor signals were measured with the EEPS™ and PPS instruments, respectively. Hence, the increased PM mass emissions are attributed to DPF regeneration events that oxidize parts of the soot cake layer on the filter walls and thus, temporarily reduce the filtration efficiency of the DPF.
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Las Vegas, NV to Riverside, CA
Morgantown, WV to Terre Haute, IN
Terre Haute, IN to Salina, KS
Salina, KS to Denver, CO
Denver, CO to Grand Junction, CO
Grand Junction, CO to Las Vegas, NV
Figure 5: Distance specific gravimetric PM emissions in [g/mi] for different portions of the route Outlook Data reduction and analysis efforts are currently on-going and will focus on, but are not limited to following areas of interest: • Calculation of NTE PM rates using the Horiba TRPM system and comparison of results to an
alternative NTE PM mass calculation method based on the in-line particle sensor (PPS) signal. • Calculation of total particle number concentration per mile driven, using the EEPS™ and investigate
the possible influence of aftertreatment temperature, vehicle speed, elevation, and road grade on particle number emissions and DPF filtration efficiencies.
• Evaluate the durability and applicability of the in-line, real-time particle sensor (PPS) with regard to its possible application in the On-Board Diagnostics (OBD) environment.
Table 1: Test vehicle and engine specifications
Chassis Manufacturer / Model Mack Trucks Inc. / CXU613 Class 8 Vehicle Model Year (MY) 2011 Aftertreatment System DOC / DPF / urea-SCR Fuel Standard ULSD (<15ppm) Emission Family BVPTH12.8S01 Curb Weight [lbs] 15’000 Gross Vehicle Weight (GVW) [lbs] 66’740 Engine Manufacturer Mack Trucks Inc. Engine Model MP8-445C Engine Model Year 2011 Displacement [L] 12.8 Configuration / # of Cylinders In-line / 6 cylinder Rated Power [hp] 445 @ 1500rpm NOx [g/bhp-hr] 0.2* PM [g/bhp-hr] 0.01*
*Engine complies with 2010 EPA HD emission standards (NOx: 0.2 g/bhp-hr, PM: 0.01 g/bhp-hr)
References [1] Kittelson, D. B., Watts, W. F., Johnson, J. P., Thorne, C., Higham, C., Payne, M., Goodier, S.,
Warrens, C., Preston, H., Zink, U., Pickles, D.; Goersamnn, C., Twigg, M. V., Walker, A. P., Boddy, R., “Effect of fuel and lube oil sulfur on the performance of a diesel exhaust gas regenerating trap,” Environ. Sci. Technol., Vol. 42, pp. 9276−9282, (2008).
[2] Thiruvengadam, A., Besch, M.C., Carder, D.K., Oshinuga, A., and Gautam, M., “Influence of Real-World Engine Load Conditions on Nanoparticle Emissions from a DPF and SCR Equipped Heavy-Duty Diesel Engine,” Environ. Sci. Technol., Vol. 46 (3), pp. 1907-1913, (2012).
[3] Vaaraslahti, K., Keskinen, J., Giechaskiel, B., Solla, A., Murtonen, T., and Vesala, H., “Effect of Lubricant on the Formation of Heavy-Duty Diesel Exhaust Nanoparticles,” Environ. Sci. Technol., Vol. 39, pp. 8497-8504, (2005).
[4] Ardanese, R., Ardanese, M., Besch, M.C., Adams, T.R., Thiruvengadam, A., Shade, B.C., Gautam, M., Miyasato, M., and Oshinuga, A., “PM Concentration and Size Distributions from Heavy-Duty Diesel Engine Programmed with Different Engine-Out Calibrations to Meet the 2010 Emission Limits,” SAE Technical Paper No. 2009-01-1183, (2009).
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REALREAL--WORLD PARTICULATE EMISSIONS FROM A 2010 COMPLIANT HDWORLD PARTICULATE EMISSIONS FROM A 2010 COMPLIANT HD DIESEL TRUCK TRAVELING ACROSS THE CONTINENTAL UNITED STATES DIESEL TRUCK TRAVELING ACROSS THE CONTINENTAL UNITED STATES
West Virginia University
CAFEE Center for
Alternative Fuels, Engines and Emissions
Marc C. Besch1, Arvind Thiruvengadam1, Daniel K. Carder1, Adewale Oshinuga2, Alberto Ayala3, Mridul Gautam1,† 1 West Virginia University, Department of Mechanical and Aerospace Engineering
2 South Coast Air Quality Management District, Diamond Bar, California 3 California Air Resources Board, Sacramento, California
Mridul Gautam, PhD West Virginia University Robert C. Byrd Professor of Mechanical and Aerospace Engineering Morgantown, WV 26505 Associate Vice President for Research and Economic Development voice: (304) 293-5913 fax: (304) 293-7498
† For more information please contact:
Introduction
Objective
Vehicle Technology and Test Route
Data reduction and analysis efforts are currently on-going and will focus on, but are not limited to following areas of interest: Calculation of NTE PM rates using the Horiba TRPM system and comparison of results to an alternative NTE PM
mass calculation method based on the in-line particle sensor (PPS) signal. Calculation of total particle number concentration per mile driven, using the EEPS™ and investigate the possible
influence of aftertreatment temperature, vehicle speed, elevation, and road grade on particle number emissions and DPF filtration efficiencies.
Evaluate the durability and applicability of the in-line, real-time particle sensor (PPS) with regard to its possible application in the On-Board Diagnostics (OBD) environment.
This work is aimed at gaining insight into real-world particle matter (PM) emissions including both, gravimetric and number specific aspects, from a 2010 compliant heavy-duty Diesel (HDD) tractor equipped with advanced after-treatment technology. Specifically, the acquired data allows for: i) comparison of in-use PM emissions with engine dynamometer based US EPA 2010 emissions certifica-
tion standards, ii) quantification of PM mass emitted during Not-to-Exceed (NTE) events, and iii) calculation of particle concentrations with regard to the particle number (PN) limit as will be introduced
by the EURO VI legislation in 2014.
Engine manufacturers across the US and Europe introduced advanced aftertreatment systems, most commonly comprising Diesel Particle Filters (DPF) and Selective Catalytic Reduction (SCR) systems in order to comply with latest heavy-duty (HD) on-road emissions legislations. With exception of the upcoming Euro VI regulation (2014), current standards do not include limitations for nanosized particle emissions which have been identified by the health science community to increase both morbidity as well as mortality in humans and putting especially the population living in close proximity to major road ways and in densely populated urban areas at elevated risk. In-deed, researchers [1, 2 and 3] reported an increase in nanoparticles from catalyzed DPF’s for exhaust tempera-tures above 380°C even for engines operating on Ultra Low Sulfur Diesel (ULSD) fuel. It has been suggested that these are sulfur derived particles formed as a result of sulfur oxidation (mainly originating from lube oil) over the catalytic surface of DPFs at high temperatures. Furthermore, the introduction of SCR systems augmented the pos-sibility of formation of new particles caused by the ammonia based Diesel Exhaust Fluid (DEF) injection [4].
A Mack® heavy-duty Diesel Class-8 tractor equipped with a model year (MY) 2011, 12.8liter (MP8-445C) engine, a diesel oxidation catalyst (DOC), a state of the art catalyzed DPF, and liquid urea based SCR aftertreatment system (see Table below) was under investigation while traveling across the continental US. The tractor was coupled to a flatbed trailer loaded with WVU’s Transportable Emissions Measurement System (TEMS) that houses a full-flow CVS tunnel and a multitude of analytical instruments for gaseous and PM emissions characterization, amounting to a gross vehicular weight (GVW) of 66,740lbs. The driving conditions ranged from the smooth hills of the Appalachian Mountains, the flat steppes of the mid-west, the Rocky Mountains all the way to the busy highways of the greater Los Angeles metropolitan area, resulting in a multitude of operating conditions induced to the aftertreatment system. The total trip distance between Morgantown (WV) and Riverside (CA) was 2450 miles, resulting in a six days journey. Furthermore, the route provided with a range of environmental conditions, including temperature variations from 3 to 36°C (37 to 97°F), relative humidity variations from 12 to 78% as well as changes in ambient pressure between 65.5 to 100.5kPa. The overall net change in elevation between Morgantown and Riverside is only -57ft (final destination lower than start Morgan-town), with the highest encountered elevation being ~11,990ft during the Loveland Pass (CO) crossing.
16th ETH-Conference on Combustion Generated Nanoparticles June 24-27, 2012, Zurich, Switzerland
Chassis Manufacturer / Model Mack Trucks Inc. / CXU613 VIN 1M1AW07Y1CM017126 Class 8 Vehicle Model Year (MY) 2011 Aftertreatment System DOC / DPF / urea-SCR Fuel Standard ULSD (<15ppm) Emission Family BVPTH12.8S01 Curb Weight [lbs] 15’000 Gross Vehicle Weight (GVW) [lbs] 66’740
Engine Manufacturer Mack Trucks Inc. Engine Model MP8-445C Engine Model Year 2011 Displacement [L] 12.8 Configuration / # of Cylinders In-line / 6 cylinder Rated Power [hp] 445 @ 1500rpm NOx [g/bhp-hr] 0.2* PM [g/bhp-hr] 0.01*
Scientific Approach Results and Discussion
Project Outlook
Particulate matter sampling and characterization was performed within the raw and diluted exhaust gas streams. Diluted Exhaust Measurements (full-flow CVS tunnel):
- PM sampled onto 47mm PTFE-coated glass fiber filters (TX-40, Pall Corp.) using a secondary dilution system, for subsequent gravimetric analysis.
- Particle number concentrations and size distributions measured directly from the CVS tunnel using an Exhaust Emissions Particle Sizer (EEPS™) spectrometer from TSI Inc. (model 3090), operating at 10Hz.
Partially Diluted Exhaust Measurements: Slipstream extracted from raw exhaust to quantify gravimetric Not-to-Exceed (NTE) zone PM emissions using Ho-riba’s portable Transient PM Emissions Measurement System (OBS-TRPM). The OBS-TRPM is a combination of a proportional dilute sampling system for gravimetric PM sampling on 47mm filter media (TX-40, Pall Corp.) and real-time measurements of particle length [mm/cm3] (including soot, sulfates and volatile particles), which can be defined as the product of total number concentration and average particle diameter, by means of a diffusion charging type sensor called Electrical Aerosol Detector (EAD) from TSI Inc.
Raw Exhaust Measurements: Measurement of real-time particle numbers and mass from the raw exhaust using an in-line particle sensor from Pegasor Ltd., Finland, (Pegasor Particle Sensor, model PPS-M) The sensor detects particles based on the escaping current principle at a sample rate of 10Hz and is designed as a flow through device. The sensors shows a propor-tional response to particle surface area concentration and can be subsequently correlated to other aerosol instru-ments by means of simple linear regression in order to measure concentration of particle mass or numbers.
HoribaMEXA 7200D
THC CH4NOx NOCO CO2
DiluteBag
Back-ground
Bag
Clean Dilution Tunnel
Variable Speed Blower
Sub-Sonic VenturiCVS
Heated Probes and Sample Lines
Mixing Orifice
EEPS(TSI Inc., 3090)
PAP PDP
TPMFilter
Holder
Gravimetric PM
2.5μmCut-pointCyclone
MFC
MFCPressurized Air SupplyChiller
Secondary Dilution Air
Heated Line
HoribaOBS-TRPM
(Gravimetric PM and EAD from TSI Inc.)
Flexible High Temperature
Resistant Transfer Hose
HEPA Filters
TRTDTSP
TMO
TDil-Air
RHDil-AirChilled Mirror (GE Dew-10) CO2 Dil-Air
(Horiba, AIA-220)
Pdiff
Pabs
TAnnubar-Out
TAnnubar-In
Annubar®
Flow Device
SCRDPF
Engine
Tpre-DPF
Ppre-DPF
NOx pre-DPF(MEXA-720)
Dry, 25°C Compressed
HEPA Filtered Air Supply
Pegasor Particle Sensor
(PPS-M) ECU Data via J1939
HoribaOBS-2200
CO, CO2 (NDIR, heated wet)NOx (CLD, heated wet)THC (FID, heated wet)
FTIR Analyzermks MultiGasTM
(Model 2030HS)NO, NO2, N2O, NH3,
CH4, CO, CO2
Tpost-SCR
Pitot-tube flowmeter
Transportable Emissions Measurement System (TEMS)
Ppost-SCR
NTE TPM Mass
Raw Particle Concentration
Gravimetric TPM
Particle Concentration and Size Distribution
Pegasor Operating Principle:
Picture provided by Pegasor Ltd.
In-line PM Sensor (Pegasor PPS-M)
Sample Inlet
Dilution Air (Dry, ~25°C compressed HEPA filtered air supply)
Sensor Electronics
PPS wrapped with tape heater (200°C)
Sample probes/lines for OBS-TRPM system
Sample Outlet
EEPS (Model 3090, TSI Inc.) • Engine Exhaust Particle Sizer®
(EEPS) Spectrometer • Diluted exhaust measurement from
CVS sampling plane • Average dilution ratio (DR): ≈ 10 • Dilution air temperature and humidity
varying depending on location
Gravimetric TPM • According to 40 CFR, 1065 • 47 mm TX40 filter media • Total flow across filter: 2.3scfm • Secondary dilution flow: 1.1scfm
Vehicle Specifications Engine Specifications
Truck-stop in Terre-Haute, Indiana Loveland Pass, Colorado Canyon Land, Utah
Las Vegas, NV to Riverside, CA
Grand Junction, CO to Las Vegas, NV
Denver, CO to Grand Junction, CO
Salina, KS to Denver, CO
Terre Haute, IN to Salina, KS
Morgantown, WV to Terre Haute, IN
Riverside, CA
Las Vegas, NV
Grand Junction, CO
Denver, CO
Salina, KS
Terre Haute, IN
Morgantown, WV
Number concentration not corrected for CVS
dilution.
Diameter [nm]
dN/d
LogD
p [#
/cm
3 ]
Time [sec]
Distance-specific PM mass emissions in [g/mi] for se-lected sections along the test route.
Values are not corrected for CVS background PM since HEPA filtered dilution air was utilized.
On average the distance spe-cific PM mass emissions re-mained below 0.05 g/mi.
Test sections with increased PM mass (e.g. C0035-002-64, 72, and 73) correspond to test portions where increased par-ticle number concentrations in the 30-40nm (CMD) range and in-line particle sensor sig-nals were measured with the EEPS™ and PPS instru-ments, respectively. Hence, the increased PM mass emis-sions were attributed to DPF regeneration events.
Active DPF regeneration (addition of HC via 7th injector) occurred during test section C0035-002-64.
Note that PM mass graph and elevation graph show driving from right to left, thus corre-sponding to map.
Source: Google Maps
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Results show a predominant mono-modal particle distribution with a count mode diameter (CMD) in the range of 6.04-15nm and a stable peak number count on the order of 2x108 [#cm3] dur-ing periods where exhaust gas tem-peratures exceed ~340°C.
Exhaust temperature at DPF inlet is ex-ceeding 350°C for ~45% and is be-tween 350-400°C for ~36% of the entire test route.
Increased particle number concentra-tions with a CMD in the size range of 30-40nm were observed periodically dur-ing the trip, as indicated by a red circle, coinciding with an increase in in-line particle sensor (PPS) signal of up to two orders of magnitude.
Increased particle concentrations are considered to be good indicators of DPF regeneration events, leading to a temporary reduction in DPF filtration efficiency.