e-series magnetostrictive displacement sensor - … eh series magnetostrictive displacement sensor...

Magnetostrictive displacement sensor

E-series

TM

E.01

The EH series magnetostrictive displacement sensor features

a prominent external housing structure. Its sophisticated

mechanical structure is made of durable aluminum while the

modular shape allows for easy installation. The sliding magnet

runs on an external track. The moving parts are connected by

the ball hinge arm of bear axial force.

Magnetostrictive displacement sensor – a non-contact alternative to contacting transducers.

10 V

U+

Analog V/A

U-

UREF

Connection scheme potentiometer, block diagram.

Magnetostrictive displacement sensor connections, block diagram.

U+

Analog V/A

U-

≈

24 V

GND

Analog

·Linear, Absolute Measurement

·Non-Contact Sensing Technology

·Rugged industrial sensor

·EMC shielded and CE certification

·Linearity Deviation:：±0.02% F.S.

·Repeatability:±0.001% F.S.

Prominent structure of the shell with oriented positioning magnet

EH -series Analog output

E.02

0…+10 V / +10…0 V

—

—

—

—16 bit D/A，0.0015%（min.1μm）

Max.5 mA

[150 μV/°C＋（5 ppm/°C×P×U/L）]×△T

16 bit D/A，0.0015%（min.1μm）

≤ 500Ω

≤ 4 μm

fstandard=1kHz

＜±0.02% F.S.（min.±60um）

＜±0.001%F.S.

≤150 mA

12…30V DC

-40°C…+85°C （Customized 105°C）

-40°C…+100°C

50~4000 mm

100g/6 ms as per IEC 60068-2-27

15g/10-2000Hz per IEC 60068-2-6

YES

TransZorb protection diodes

500 V (GND to housing)

IP67

Anodized aluminum

Connector

Mounting kit

EMC testing：

EN 55011 group 1, Grade A

IEC 61000-4-2，Severity level 3




4…20 mA / 20…4 mA

V

Analog

Analog

A

Analog

Analog

10V

0V0 smax

UA[V]

UA

UA

20mA

4mA0mA

0 smax

IA[mA]

IA

IA

[0.6 μA/°C＋（10 ppm/°C×P×I/L）]×△T

Ordering example

Example:EH-0050-D801-V01

EH EH -Series Magnetostrictive Displacement Sensor0050

D801

V01

Standard nominal stroke (mm)：0050=50mm

Connector：·D801=8 PIN ; 12…30V DC

Output：·V01=0…+10V ·V02=+10…0V ·A01=4…20mA ·A02=20…4mA

Transducer interface

Output signal

Input interface

Output voltage

Output current

Resolution

Load current

Load resistance

Temperature coefficient

Hysteresis

Sampling rate

Linearity deviation

Repeat accuracy

Current consumption

Supply voltage

Operating temperature

Storage temperature

Stroke length:

Shock load

Vibration

Polarity reversal protected

Over voltage protected

Dielectric strength

Degree of protection

Housing material

Connection

Install

EMC testing

Radio interference emission

Static electricity (ESD)

Electromagnetic fields (RFI)

Rapid, transient electrical

pulses (burst)

Conducted interference induced

by high-frequency fields

E.03

Standard SSI interface

Synchronous serial data transmission works with controllers

from various manufacturers, including Siemens, Bosch

Rexroth,WAGO, B & R, Esitron, PEP and others

displays/controllers.

Reliable signal transmission, even with cable lengths of up to

400m between controller and EH -transducer, is assured by

interruptionfree RS485/422 differential line drivers and

receivers. Any interference signals are effectively suppressed.

Synchronized SSI interface

magnetostrictive displacement sensor with

synchronized SSI interface are well suited for

dynamic control applications. Data acquisition in the

sensor is synchronized using the external clock of the

controller,allowing an optimum speed calculation to

be performed in the regulator/controller. A

prerequisite for this synchronous method of sensor

operation is the time stability of the clock signal.

The maximum sampling frequency fA, at which a new

current value is generated for each sample, can be

derived from the following table:

120 <

475 <

750 <

1250 <

2600 <

≤ 120 : 2500

≤ 475 : 2000

≤ 750 : 1500

≤ 1250 : 1000

≤ 2600 : 500

≤ 4000 : 333

mm mm Hz

Nominal stroke

Nominal stroke

Nominal stroke

Nominal stroke

Nominal stroke

Nominal stroke

Clock frequency depends on the cable length.

< 25 m

< 50 m

< 100 m

< 200 m

< 400 m

< 1000 kHz

< 500 kHz

< 400 kHz

< 200 kHz

< 100 kHz

Cable lengt Clock frequency

EH…with controller / processor connection example

Controller or processor

EH……magnetostrictive displacement sensor

+Clk

-Clk

+Data

-Data

GND

12…30 V

BlueCanaryyellow

Yellow

Grey

Black

White

EH -series SSI outputProminent structure of the shell with oriented positioning magnet







E.04

Resolution


Hysteresis

Sampling rate

Linearity deviation

Repeat accuracy

Supply voltage

Current consumption


Storage temperature

Stroke length

Data rate

Shock load

Vibration



Dielectric strength


Housing material

Connection

Install

EMC testing





pulses (burst)



1μm,2μm,5μm,10μm,20μm,40μm

(6 μm+5 PPM×L)/°C

≤5μm / ±1 digit

fstandard=2kHz

＜±0.01% F.S.（min.±50um）

＜±0.001%F.S.

12…30 V DC

≤150mA

-40°C…+85°C（Customized 105°C）

-40°C…+100°C

50~4000 mm

Line length：＜3 ＜50 ＜100 ＜200 ＜400 m

Rate： 1000 ＜400 ＜300 ＜200 ＜100 kBd

100g/6 ms as per IEC 60068-2-27

15g/10-2000Hz per IEC 60068-2-6

YES



IP67

Anodized aluminum

Connector

Mounting kit

EMC testing：






SSI

Synchronous-serial

Synchronous-serial

1

MSB LSBout of range

tv

2 3 4 23 24

t tm

Clock pulse sequence

+Clk

+Data

Example:EH-0050-D801-S002

EH

0050

D801

S Output Signal：·S= SSI

02

0 Code：·0=Binary code rising (24-bit) ·1=Gray code rising (24-bit)

Resolution：·01=1μm ·02=2μm ·05=5μm ·10=10μm ·20=20μm ·40=40μm

·6=Binary code rising (25-bit) ·7=Gray code rising (25-bit)·T=Other figures, can be customized


Output signal

input interface

Ordering example

EH -Series Magnetostrictive Displacement Sensor



E.05

Based on CAN (ISO/IEC 7498 and DIN ISO 11898),

CANopen provides a Layer-7 implementation for

industrial CAN networks. The serial data protocol of

the CAN specification is defined according to the

producer-consumer principle as opposed to most other

fieldbus protocols. This eliminates target addressing of

the process data. Each bus station decides for itself

how the received data is processed.

The CANopen interface of the magnetostrictive

displacement sensor is compatible with CANopen

conforming with CiA Standard DS301 Rev. 3.0, and

with CAL and Layer 2 CAN networks.

The features of CAN bus

-Linear topology，such as using a repeater can be used

star structure.

-Low-cost wiring with two-wire cable

-Fast response times

-High data security due to CRC checking

-Hamming distance of 6

-1 Mbps at cable length < 25 m

-Protocol limits number of nodes to 127

CANopen offers a high level of flexibility in

configuration functionality and data exchange. Using a

standard data sheet in the form of an EDS file, it is

easy to link the magnetostrictive displacement sensor

to any CANopen system.

Process Data Object (PDO)

Twelve magnetostrictive displacement sensors send

their measured values optionally in one, two or four

PDOs with 8 bytes of data each. The contents of the

PDOs are freely configurable. The following

information can be sent:

-The current magnet with a resolution in 5 μm

increments.

-Current speed of the magnet, with resolution

selectable in 0.1mm/s increments.

Synchronization Object (SYNC)

SYNC serves as a network-wide trigger for

synchronizing all network nodes. When the SYNC

object is received, all magnetostrictive displacement

sensors connected to the bus store their current

position and velocity information and then send it

sequentially to the controller. This assures

time-synchronous acquisition of the measured values.

Emergency Object

This object is sent with the highest priority and is

used, for example,for error messages when tahe cam

states change.

Service Data Object (SDO)

Service Data Objects transmit the configuration

parameters to the transducer. The transducer may be

configured on the bus by the controller or offline with

a bus analyzer/CANopen tool. The configuration is

stored in the non-volatile memory of the transducer.

EH -series CANopen outputProminent structure of the shell with oriented positioning magnet






·Repeatability:±0.001% F.S.；

E.06

1μm,2μm,5μm,10μm


≤1 digit

fstandard=1kHz

＜±0.01% F.S.（min.±50um）

＜±0.001%F.S.

12…30 V DC

≤150 mA


-40°C…+100°C

50~4000 mm

＜25 ＜50 ＜100 ＜250 ＜500 ＜1000 ＜1250 ＜2500

1000 800 500 250 125 100 50 20/10

100g/6 ms as per IEC 60068-2-27

15g/10-2000Hz per IEC 60068-2-6

YES



IP67

Anodized aluminum

Connector

Mounting kit

EMC testing：






CANopen

CANopen

CANopen

Bit-Stuffing

RTR-Bit(Remote-Transmission-Request)recessive

Delimiting Bits

dominant

Numberof bits 1 11 1 1 1 1 7 36 150…8 byte

Data Field

Start-of-Message-Bit

object-identifier

Arbitration Field

Control Field ACK SlotEnd-of-MessageField

IntermissionField

CRC-Field

Acknowledge-Field

Data Frame

Example:EH-0050-D801-C0110EH0050D801C Output Signal：·C= CANopen

1

0

01Baud rate：·0=1Mbps ·1=800kbps ·2=500kbps ·3=250kbps ·4=125kbps ·5=100kbps ·6=50kbps ·7=20kbps ·8=10kbps

Resolution：·01=1μm ·02=2μm ·05=5μm ·10=10μm

Resolution


Hysteresis

Sampling rate

Linearity deviation

Repeat accuracy

Supply voltage

Current consumption


Storage temperature

Stroke length

Cable length [m]

Baud rate [kbps]

Shock load

Vibration



Dielectric strength


Housing material

Connection

Install

EMC testing





pulses (burst)




Output signal

input interface

Ordering example

EH -Series Magnetostrictive Displacement SensorStandard nominal stroke (mm)：0050=50mmConnector：·D801=8 PIN ; 12…30V DC

Termination resistors·0=NO ·1=YES

E.07







Based on CAN (ISO/IEC 7498 and DIN ISO 11898),

CANopen provides a Layer-7 implementation for

industrial CAN networks. The serial data protocol of

the CAN specification is defined according to the

producer-consumer principle as opposed to most other

fieldbus protocols. This eliminates target addressing of

the process data. Each bus station decides for itself

how the received data is processed.

The CANopen interface of the magnetostrictive

displacement sensor is compatible with CANopen

conforming with CiA Standard DS301 Rev. 3.0, and

with CAL and Layer 2 CAN networks.

The features of CAN bus

-Linear topology，such as using a repeater can be used

star structure.

-Low-cost wiring with two-wire cable

-Fast response times

-High data security due to CRC checking

-Hamming distance of 6

-1 Mbps at cable length < 25 m

-Protocol limits number of nodes to 127

CANopen offers a high level of flexibility in

configuration functionality and data exchange. Using a

standard data sheet in the form of an EDS file, it is

easy to link the magnetostrictive displacement sensor

to any CANopen system.

Process Data Object (PDO)

Twelve magnetostrictive displacement sensors send

their measured values optionally in one, two or four

PDOs with 8 bytes of data each. The contents of the

PDOs are freely configurable. The following

information can be sent:

-The current magnet with a resolution in 5 μm

increments.

-Current speed of the magnet, with resolution

selectable in 0.1mm/s increments.

Synchronization Object (SYNC)

SYNC serves as a network-wide trigger for

synchronizing all network nodes. When the SYNC

object is received, all magnetostrictive displacement

sensors connected to the bus store their current

position and velocity information and then send it

sequentially to the controller. This assures

time-synchronous acquisition of the measured values.

Emergency Object

This object is sent with the highest priority and is

used, for example,for error messages when tahe cam

states change.

Service Data Object (SDO)

Service Data Objects transmit the configuration

parameters to the transducer. The transducer may be

configured on the bus by the controller or offline with

a bus analyzer/CANopen tool. The configuration is

stored in the non-volatile memory of the transducer.

Data transmission

A Profibus telegram can contain up to 244 bytes of

user data per telegram and node. The EH uses max.

32 bytes (max. 4 position values and max. 4 velocity

values) for process data transmission. Up to 126 active

stations (addresses 0...125) can be connected on

Profibus DP. User data cannot be sent with node

address 126. This address is used as the default

address for bus nodes that have to be configured by a

Class 2 master (for setting the device address if there

are no mechanical switches available). Each Profibus

station has the same priority. Prioritizing of individual

stations is not intended, but can be done by the

master since the bus transmission only makes up a

fraction of the process cycle anyway. At a transfer rate

of 12 mbaud, the transmission time for an average

data telegram is in the 100 μs range.

The master station

There are two types of PROFIBUS-DP master station.

To realize the user information and from stations

exchange a main station. Two class master used to

start and diagnostic control process and simple control

from the station.

From the station

PROFIBUS master received for the parameters

defining the settings from the station, you can

exchange information with each other. This parameter

contains the slave parameters and configuration data.

From the station parameters included from the station

set up the rules (such as position value resolution).

The configuration data in the provisions of the length

and structure of a data message.

GSD (device master data)

The length of the data exchangeable with a slave is

defined in the Device Master Data file (GSD) and is

checked by the slave with the configuration telegram

and confirmed for correctness. In modular systems,

various configurations are defined in the GSD file.

Depending on the desired functionality, one of these

configurations can be selected by the user when the

system is configured.

Process data

Under Profibus DP, by default, the process data is to

be sent from the master to slaves acyclically and for

the slave data to then be queried. To ensure

synchronization of multiple devices, the master may

use the SYNC and FREEZE services.

EH -series PROFIBUS-DP outputProminent structure of the shell with oriented positioning magnet

E.08

1μm,2μm,5μm,10μm


≤±1 digit

fstandard=1kHz

＜±0.01% F.S.（min.±50um）

＜±0.001% F.S.

12…30 V DC

≤150mA


-40°C…+100°C

50~4000 mm

＜100 ＜200 ＜400 ＜1000 ＜1200

12000 1500 900 187.5 93.7/19.2/9.6

100g/6 ms as per IEC 60068-2-27

15g/10-2000Hz per IEC 60068-2-6

YES



IP67

Anodized aluminum

Connector

Mounting kit

EMC testing：





PROFIBUS-DP

PROFIBUS-DP

PROFIBUS-DP

SYZ SD2 SD2LE DA SA FC DU EDFCSLEr

SD2 SD2LE DA SA FC DU EDFCSLErDP-

Mas

ter

DP-

Sta

ve

SRD-Request,variable lenght of user data

SRD-Response,variable lenght of user data

Example:EH-0050-D801-P020EH0050D801P Output Signal：·P= PROFIBUS-DP02 Resolution：·01=1μm ·02=2μm ·05=5μm ·10=10μm0 Baud rate：·0=12000 kbps ·1=1500 kbps ·2=900 kbps ·3=187.5 kbps

·4=93.7/19.2/9.6 kbps

Resolution


Hysteresis

Sampling rate

Linearity deviation

Repeat accuracy

Supply voltage

Current consumption


Storage temperature

Stroke length

Cable length [m]

Baud rate [kbps]

Shock load

Vibration



Dielectric strength


Housing material

Connection

Install

EMC testing





pulses (burst)




Output signal

input interface

EH -Series Magnetostrictive Displacement SensorStandard nominal stroke (mm)：0050=50mmConnector：·D801=8 PIN ; 12…30V DC

Ordering example

E.09

EH Size chart

12 10 10

80（unusable area）

40

40（unusable area）Nominal stroke 50~4000

Nominal stroke 50~4000

M4

（M5×10）M6×10

28

354358

26.5

36.8

6268.5

33

EH wiring configuration

1

2

3

4

5

6

7

8

Voltage

Current

Color

SSI

Color

CANopen

Color

1

-

-

-

C-Canaryyellow

-

-

2

-

-

-

-

-

-

-

3

-

-

-

-

-

-

-

4

12…30 V

12…30 V

Brown

12…30 V

White

12…30 V

Brown

5

GND

GND

Grey

GND

Black

GND

Grey

6

0V

AGND

White

D-

Grey

CAN_H

White

7

0…+10 V / +10…0 V

4…20 mA / 20…4 mA

Yellow

D+

Yellow

CAN_L

Yellow

8

-

-

-

C+

Blue

-

-

pin

pin

Signal

Signal

1

2

3

4

5

6

7

8

10

40

3042

PROFIBUS-DP

Color

1

R×D/T×D-N

Yellow

2

R×D/T×D-N

White

3

DGnd

-

4

VP

-

5

12…30 V

Brown

6

0 V

Grey

7

-

-

8

-

-

Size：mm

Tolerance ISO 8015ISO 2768-mH＜6mm:±0.2mm



E.10

Orderubg exampleExample:E-DH01-0075EDH01

D=Extension rodH=facilitatedJoint：·01= Straight corner joint bearing ·02= The ball joint bearing

0075 ·0075=75mm

EH Accessories

AccessoriesDescription

E-MH00-0001

Magnet

M5

28

3.3

22.614

17

E-B100-0001 E-FSC8-PG9

7.57.5

15

4.3

7

43

58

11.5

Extension rod selection

Example:E-C102-000LEC1

C=extension line

0L

0200

Extension line selection

Fisheye joint Universal jointExtension rod

(Right angle ball joint)Extension rod

(Ball joint)

Note: the extension order number, please refer to the E.10 page

M5

10 6

25.15

M6M6

M5

8

20

10

Extension rod

Extension rod

Custom

length

Custom

length

E-Y000-0001 E-W000-0001

It must be used for the extension rod


ø17.8ø5

M5

33

M5

40

M6

40

E-Y000-0002 E-W000-0002

42 30

ø17.8ø5

M6

33

The order No.

The order No.

The order No.

Clamping bracket Plug



Fisheye joint Universal joint

It must not be used for the extension rod

It must not be used for the extension rod

E -Series

E -Series

Orderubg example

Left side interface: · 1 = 8 pin

Extension line’s length:· 01=1m · 02=2m …… · 30=30mRight side interface · 00=Don't need to joint · 01=custom designPlug type: · 0 = production since

Extension category: ·L = analog signal extension · C = CANopen special extension cord ·S = SSI special extension cord

E.11

The ER series magnetostrictive displacement sensor features

a built-in push-pull rod system. The stainless steel piston rod

is relatively thick and can withstand a significant amount of

the load. The piston is also rust-free which results in longevity

of usage. The sensor for the non-contact magnet is located at

the rear end of the piston rod and is protected by the

aluminum housing. This prevents environmental pollution

from affecting the performance.

ER type shell accord with IP67 standard and CE certification.

Built-in push-pull rod design

Analog

10 V

U+

Analog V/A

U-

UREF

U+

Analog V/A

U-

≈

24 V

GND

ER -series Analog output

·Solid aluminum cylinder push rod








Connection scheme potentiometer, block diagram.Magnetostrictive displacement sensor connections, block diagram.

Example:ER-0050-D801-V01ER

0050D801V01



E.12

0…+10 V / +10…0 V

16 bit D/A，0.0015%（min.1μm） 16 bit D/A，0.0015%（min.1μm）

Max.5 mA

[150 μV/°C＋（5 ppm/°C×P×U/L）]×△T

≤ 500Ω

≤ 4 μm

fstandard=1kHz

＜±0.02% F.S.（min.±60um）

＜±0.001% F.S.

≤150 mA

12…30V DC


-40°C…+100°C

50~1500 mm

100g/6 ms as per IEC 60068-2-27

15g/10-2000Hz per IEC 60068-2-6

YES



IP67

Anodized aluminum

Connector

Mounting kit

EMC testing：






4…20 mA / 20…4 mA

V

Analog

Analog

A

Analog

Analog

10V

0V0 smax

UA[V]

UA

UA

20mA

4mA0mA

0 smax

IA[mA]

IA

IA

[0.6 μA/°C＋（10 ppm/°C×P×I/L）]×△T

——

——

Ordering example

ER -Series Magnetostrictive Displacement SensorStandard nominal stroke (mm)：0050=50mm


Output signal

Input interface

Output voltage

Output current

Resolution

Load current

Load resistance


Hysteresis

Sampling rate

Linearity deviation

Repeat accuracy

Current consumption

Supply voltage


Storage temperature

Stroke length:

Shock load

Vibration



Dielectric strength


Housing material

Connection

Install

EMC testing





pulses (burst)



E.13

ER Size chart

Magnet12 20 20

ER wiring configuration

1

-

-

-

2

-

-

-

3

-

-

-

4

12…30 V

12…30 V

Brown

5

GND

GND

Grey

6

0V

AGND

White

7

0…+10 V / +10…0 V

4…20 mA / 20…4 mA

Yellow

8

-

-

-

Magnet

Magnet Magnet

35

40.3

36.3

43

58M4

3042

20

1

2

3

4

5

6

7

8

Size：mm



80（unusable area） Nominal stroke 50~1500



Voltage

Current

Color

pinSignal

E.14


0L

0200

ø17.8ø5

M6

33

M6

40

E-Y000-0001 E-W000-0001

ER Accessories

E-B100-0001 E-FSC8-PG9

7.57.5

15

4.3

7

43

58

11.5

The built-in magnet without number, without selection

13.5

25.6

R6

ø5.5ø9.5

10.72.

33.

5

20.6

42 30



Magnet

Fisheye joint Universal joint



The order No.

The order No.


C=extension line


E -Series

Orderubg example

Right side interface · 00=Don't need to joint · 01=custom design

Plug type: · 0 = production since

Extension category: ·L = analog signal extension

Left side interface: · 1 = 8 pinExtension line’s length:· 01=1m · 02=2m …… · 30=30m

E.15

The EP series displacement sensor has a prominent structure

and non-contact position feedback components. These

features make the EP Series a superior alternative to the

potentiometer because it provides a higher level of protection,

longevity of use, as well as ease of installation.

Magnetostrictive displacement sensors are becoming standard

parts for the industry of high precision injection molding

machinery replacing the previously used potentiometer.

Despite a wide range of applications, magnetostrictive

displacement sensors are still relatively expensive. However,

the EP series Magnetostrictive displacement sensor is very

competitively priced to meet the requirements of the

industry. The EP Series magnetostrictive displacement sensor

has minimum downtime and applies to a variety of

applications ranging from airplanes to automobiles.

Analog

10 V

U+

Analog V/A

U-

UREF

U+

Analog V/A

U-

≈

24 V

GND

Freestyle

EP -series Analog output

·Solid aluminum cylinder push rod





·Not sensitive to impact and vibration

·Linearity Deviation:±0.02% F.S.



Connection scheme potentiometer, block diagram. Magnetostrictive displacement sensor connections, block diagram.

E.16

Example:EP-0050-D401-V01EP EP-Series Magnetostrictive Displacement Sensor0050D401V01



0…+10 V / +10…0 V

16 bit D/A，0.0015%（min.1μm）

[150 μV/°C＋（5 ppm/°C×P×U/L）]×△T

16 bit D/A，0.0015%（min.1μm）

≤ 500Ω

4…20 mA / 20…4 mA

10V

0V0 smax

UA[V]

UA

UA

20mA

4mA0mA

0 smax

IA[mA]

IA

IA

[0.6 μA/°C＋（10 ppm/°C×P×I/L）]×△T

—

—

——


Output signal

Input interface

Output voltage

Output current

Resolution

Load current

Load resistance


Hysteresis

Sampling rate

Linearity deviation

Repeat accuracy

Current consumption

Supply voltage


Storage temperature

Stroke length:

Shock load

Vibration



Dielectric strength


Housing material

Connection

Install

EMC testing





pulses (burst)



≤ 4 μm

fstandard=1kHz

＜±0.02% F.S.（min.±60um）

＜±0.001% F.S.

≤150 mA

12…30V DC


-40°C…+100°C

50~1500 mm

100g/6 ms as per IEC 60068-2-27

15g/10-2000Hz per IEC 60068-2-6

YES



IP67

Anodized aluminum

Connector

Mounting kit

EMC testing：






V

Analog

Analog

A

Analog

Analog

Max.5 mA

Ordering example


E.17

EP Size chart

max.distance2.5 mm±2 mm

max.distance10mm

max.distance10mm

33M4

1 2

3

EP wiring configuration

3

12…30 V

12…30 V

Brown

2

0V

AGND

Grey

1

0…+10 V / +10…0 V

4…20 mA / 20…4 mA

Yellow

32

19.5

12 10 10

32

14

24.5

10





Size：mm


Voltage

Current

Color

pinSignal

E.18


0L

0200


EP Accessories

E-B100-0001 E-FRS4-PG11

58

11.5

4 PIN

E-MP00-0001

33

ø4.4通孔

20

24

6

7.57.5

15

4.3

7

43 14.5

14.5

10


Magnet

The order No.


C=extension lineE -Series

Orderubg example

Right side interface · 00=Don't need to joint · 01=custom designPlug type: · 0 = production sinceExtension category: ·L = analog signal extension

Left side interface: · 0 = 4 pinExtension line’s length:· 00=Don’t need extension line ·01=1m · 02=2m …… · 30=30m

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RAYNIWILL (logo) are trademarksRAYNIWILL 's only obigations are those stated in RAYNIWILL 's general terms and conditions of Business.RAYNIWILL ’ s expressly disclaims any implied warranty regarding the information contained herein,including,but not limited to,the implied warranties of merchantability or fitness for a particular purpose. Te

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e-series magnetostrictive displacement sensor - … eh series magnetostrictive displacement sensor...

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