References Inductive proximity sensors - Trinet Gruptrinetgrup.ro/cat_schneider/pdf/Detectie/2_4_Osiprox_accesories_tables.pdf · An alternating magnetic field is generated in front

37317-EN_Ver2.2.fm/2 Schneider Electric

References 2 Inductive proximity sensors 2

Osiprox®

Accessories

Mounting and fixing accessoriesDescription For use with sensors Unit reference Weight

kgType Diameter (mm)“Clip” mounting plateMounting possible without“clip” on tapped holes

XSp J – XSZ BJ00 0.003XSp F – XSZ BF00 0.005

XSp E – XSZ BE00 0.025XSp C – XSZ BC00 0.060

“Clip” 90° mountingbracketMounting possible without“clip” on tapped holes

XSp J – XSZ BJ90 0.003

XSp F – XSZ BF90 0.005XSp E – XSZ BE90 0.025

XSp C – XSZ BC90 0.060Replacement bracket XSp E

Replaced: XS7 T2,XS8 T2, XSE

– XSZ BE10 0.060

XSp CReplaced: XS7 T4,XS7 C40, XS8 T4,XS8 C40 and XSC

– XSZ BC10 0.110

XSp D (for XSD) (1) – XSZ BD10 0.065Fixing clamp forremote control

XS9, XS6pppB2 – XSZ BPM12 0.015

Fixing clamps XS1 4 (smooth) XSZ B104 0.0055 (M5 x 0.5) XSZ B105 0.005

XS1, XS2 6.5 (smooth) XSZ B165 0.005XS1, XS2, XS4, XS5,XS6

8 (M8 x 1) XSZ B108 0.006

XS1, XS2, XS4, XS5,XS6, XT1, XT4

12 (M12 x 1) XSZ B112 0.00618 (M18 x 1) XSZ B118 0.010

30 (M30 x 1.5) XSZ B130 0.020XT1, XT4 32 (smooth) XUZ B32 0.050

Set of 2 fixing nuts, metalnickel chromed

XS1 5 (M5 x 0.5) XSZ E105 0.010

XS1, XS2, XS5, XS6 8 (M8 x 1) XSZ E108 0.015XS1, XS2, XT1, XS5,XS6

12 (M12 x 1) XSZ E112 0.015

18 (M18 x 1) XSZ E118 0.02030 (M30 x 1.5) XSZ E130 0.050

Set of 2 fixing nuts,stainless steel

XS1, XS2, XS5, XS6 8 (M8 x 1) XSZ E308 0.015

XS1, XS2, XT1, XS5,XS6

12 (M12 x 1) XSZ E312 0.01518 (M18 x 1) XSZ E318 0.020

30 (M30 x 1.5) XSZ E330 0.050Set of 2 fixing nuts,plastic

XS4 8 (M8 x 1) XSZ E208 0.002

12 (M12 x 1) XSZ E212 0.003XS4, XT4 18 (M18 x 1) XSZ E218 0.004

30 (M30 x 1.5) XSZ E230 0.005

Adaptor collar Ø 20 XSp, XTp 18 (M18 x 1) XSZ A020 0.005Ø 34 XSp, XTp 30 (M30 x 1.5) XSZ A034 0.005

Protection accessoriesOuter covermade of silicon (reinforcedresistance to chemical)

XSp E – XSZ EE10 0.003

XSp C – XSZ EC10 0.007XSp D – XSZ ED10 0.010

Cable sleeve adaptor(CNOMO type)

XSp, XTp 12 (M12 x 1) XSZ P112 0.005

18 (M18 x 1) XSZ P118 0.00530 (M30 x 1.5) XSZ P130 0.010

Outer cover (IP 68) XT7 C – XSC Z01 0.100Thread adaptor XSp, XTp 30 (M30 x 1.5) XTA Z30 0.035

No. 13 plastic cable gland Clamping capacity Ø 9 to 12 mm XSZ PE13 0.010Protective coverSold in lots of 50

M12 universal connectors XSZ F10 0.020

Mounting partsThread inserts for rearfixing

XSpE M3 XSZ VF03 0.002

XSpC M4 XSZ VF04 0.005XSpD M5 XSZ VF05 0.006

Fuses (for unprotected 2-wire c/a sensors)

Description Type Sold in lots of Unit reference Weightkg

Cartridge fuses5 x 20

0.4 A “quick-blow” 10 XUZ E04 0.0010.63 A “quick-blow” 10 XUZ E06 0.001

0.8 A “quick-blow” 10 XUZ E08 0.001Fuse terminal block for XUZ E0p 50 AB1 FU10135U 0.040(1) Depth adjustment block for converting from 80 x 80 x 26 mm format to 80 x 80 x 40 mm format.

Also enables clipping onto 35 mm “omega” rail.

XSZ Bp00

5206

91

XSZ Bp90

5614

54

XSZ BC10 XSZ BE10

XSZ BD10

XSZ B1pp

XSZ Ep10

XSZ P1pp

XSZ A0pp

XSC Z01

XSZ F10 XTA Z30

5206

95 5206

94

5622

71

8259

94

5206

97

8259

96

8259

97

8259

95

5209

35

8219

80

XSZ BPM12

5622

70

37317-EN_Ver2.2.fm/3Schneider Electric

Dimensions 2 Inductive proximity sensors 2

Osiprox®

Accessories

XSZ BJ00 XSZ BF00

XSZ BE00 XSZ BC00

(1) 2 M3 x 12 screws supplied. (1) 4 M4 x 14 screws supplied.

XSZ BD00 (for mounting on XSp Dpppp) XSZ BJ90

XSZ BF90 XSZ BE90

(1) 2 M3 x 12 screws supplied.

199,9

8

22,55,5

125,1 M3

M3

27,5

15

34,5

7 206,1 M3

M3

5,5

1011,9

617 27,4

48,5

M3

(1)

16

12

103042

77,24,5

M5 (1)

M5

80

80

83,7

14

65

65

4

14

M3

M3125,1

22,58

10,5

4,5

9

32

18,5

15

206,1 M3

M3

M3

16

34,5

10

27,46 17

23,9

29,4

30,8

M3

(1)


Dimensions (continued) 2 Inductive proximity sensors 2

Osiprox®

Accessories

XSZ BC90 XSZ BC10

(1) 4 M4 x 14 screws supplied.

XSZ BE10

XSZ EE10 XSZ EC10

XSZ ED10

16 (1)

10 30 42

44,344,4

36,9 M542

41

55

30 41

2,8

M5

42,5

35

3925

M3

2030,2

30,2

47,1

6,8 M3 M47,8

33

44,2

33

62,1

16,4

88,5

14

65

M565

28,8 88,5

114,8


Dimensions (continued) 2 Inductive proximity sensors 2

Osiprox®

Accessories

XSZ-B104, B105 XSZ-B108, B112, B118, B130, B165 XUZ-B32

XSZ Ø XSZ a a1 b b1 b2 Ø (1) Maximum value(2) 2 holes Ø 5.5Clamp supplied with two M5 screws, HMhead

B104 4 B108 19.9 14.5 14 12.5 7.5 8B105 5 B112 21.9 14.5 16 15.5 8.5 12

Note: for saddle clamps XSZ B118 and XSZ B130, seesetting-up recommendations, page 31100/9.

B118 26 15.7 22 20.1 11.5 18B130 39 21.7 35.5 31 18.5 30B165 19.9 14.5 14 12.5 7.5 6.5

XSZ P112, P118, P130 XSZ A0pp XTA Z30

XSZ h Ø d1 Ø d2 a a1

P112 7 12 16.8 Ø18 Ø20P118 6.2 18 23 Ø30 Ø34

P130 6.2 30 34.4

XSC Z01

(1) No. 13 plastic cable gland

15

8

=9=12,3

8,5

3

4 6,7

b2

a

3,5

b1

a1

38,3

b

4 822

(1)= =50

60

25(1

) 40

=

15

(2)

(2)

34

h a

a1

20

44,4

25,4

1,5

1" 1/2 12UNF

33,3

31

50,8 9,4

M30 x 1,5

134

147

88

48

12,5 7 12,5

60

2

60=

=

=

69

=

49

22

(1)


General 2 Inductive proximity sensors 2

Recommendations

The sensors described in this catalogue are designed to be used in standard industrial presencedetection applications.These sensors do not have a redundant electrical circuit as would be needed to allow them tobe used in safety applications.For safety applications, consult our “Safety solutions using Preventa” catalogue.

Standards and certificationsParameters related to the environment

Quality controls

Our inductive proximity sensors are subject to specific precautions guaranteeing theirreliability in the harshest industrial environments.b Qualificationv The product characteristics stated in this catalogue are subject to a qualification procedurecarried out in our laboratories.v The products are notably subjected to climatic cycle tests for 3000 hours with their supply onto check their ability to hold their characteristics over time.b Productionv The electrical characteristics and detection distances at both ambient temperature andextreme temperatures are 100% checked.v Products are sampled at random during production and are subject to monitoring testsrelating to all their qualified characteristics.b Customer returnsIf, in spite of all these precautions, defective products are returned to us, they are subject tosystematic analysis and corrective actions are taken to eliminate the risks of the faultreoccurring.

Conforming to standards

All Telemecanique brand proximity sensors conform to the standard IEC 60947-5-2

Mechanical shock resistance

The sensors are tested in accordance with the standard IEC 60068-2-27, 50 gn, duration 11 ms.

Vibration resistance

The sensors are tested in accordance with the standard IEC 60068-2-6, amplitude ± 2 mm,f = 10…55 Hz, 25 gn at 55 Hz.

Resistance to the environment

b Please refer to the characteristics pages for the various sensors.b IP 67: protection against the effects of immersion.Test conforming to IEC 60529: sensor immersed for 30 minutes in 1 m of water.No deterioration in either operating or insulation characteristics is permitted.b IP 68: protection against prolonged immersion.The test conditions are subject to agreement between the manufacturer and the user (e.g.machine-tool applications or other applications on any other machine drenched in cutting fluids).

Resistance to magnetic interference

Telemecanique inductive proximity sensors are tested in accordance with therecommendations of the standard IEC 60947-5-2.

Resistance to electromagnetic interferenceb Electrostatic discharges Versions a and z: level 4 immunity (15 kV).

IEC 61000-4-2b Radiating electromagnetic fields(electromagnetic waves)

Versions c, a and z : level 2 immunity (3 V/m) orlevel 3 immunity (10 V/m). IEC 61000-4-3

b Fast transients(motor start/stop interference)

Version c: level 3 immunity (1 kV).Versions a and z: level 4 immunity (2 kV) exceptØ 8 mm model (level 2). IEC 61000-4-4

b Impulse voltage Versions c, a and z : level 3 immunity (2.5 kV)except Ø 8 mm and smaller models (1 kV level).IEC 60947-5-2

Resistance to chemicals in the environmentb Owing to the very wide range of chemicals encountered in modern industry, it is very difficultto give general guidelines common to all sensors.b To ensure lasting efficient operation, it is essential that the chemicals coming into contact withthe sensors will not affect their casings and, in doing so, prevent their reliable operation.b Cylindrical and flat plastic case sensors offer an excellent overall resistance to:v chemical products such as salts, aliphatic and aromatic oils, fuel oils, acids and diluted bases.For alcohols, ketones and phenols, preliminary tests should be made relating to the nature andconcentration of the liquid.v agricultural and food industry products such as animal or vegetable based food products(vegetable oils, animal fat, fruit juice, dairy proteins, etc.).In all cases, the materials selected (see product characteristics) provide satisfactorycompatibility in most industrial environments (for further information, please consult yourRegional Sales Office).

Insulation Class 2 devices i

Electrical insulation conforming to the standards IEC 61140 and NF C 20-030 concerning electricshock protection means.

0 2 4 6 8 10 12 14 16 18

100

80

60

20

0

7570

50

25

0

- 25

˚C %

Temperature °CHumidity as a %

- 25 + 70 °C cycle, 95% RH

Tem

per

atu

re

Rel

ativ

eh

umid

ity



Principle of inductive detection Operating principle

1 Oscillator2 Output driver3 Output stage

b Inductive proximity sensors are solely for the detection of metal objects.They basically comprise an oscillator whose windings constitute the sensing face.An alternating magnetic field is generated in front of these windings.

Composition of an inductive proximity sensor

Detection of a metal object

b When a metal object is placed within the magnetic field generated by the sensor, the resultingcurrents induced form an additional load and the oscillation ceases.This causes the output driver to operate and, depending on the sensor type, a normally open(NO) or normally closed (NC) output signal is produced.

Inductive proximity detectionb Inductive proximity sensors enable the detection, without contact, of metal objects.b Their range of application is very extensive, and includes:v the monitoring of machine parts (cams, stop, etc.),v monitoring the flow of metal parts, counting, etc.,

Advantages of inductive detection

b No physical contact with the object to be detected, thus avoiding wear and enabling fragile orfreshly painted objects to be detected.b High operating rates. Fast response.b Excellent resistance to industrial environments (robust products fully encapsulated in resin).b Solid-state technology: no moving parts, therefore service life of sensor independent of thenumber of operating cycles.

Osiconceptb Osiconcept sensors are suitable for all metal environments (flush mountable or non flushmountable) as they provide for a maximum sensing distance even in the presence of a metalbackground. Precision detection of the object’s position can be provided by means of the teachmode. For further information, see page 37316/2.

Output LED Output LED

All Telemecanique brand inductive proximity sensors incorporate an output state LED indicator.Osiconcept sensors are provided with a green LED which indicates the presence of the voltageand guides the user during setting-up (teach mode).

Mounting of sensors on a metal support Sensors suitable for flush mounting in metal

b No side clearance required.b All models using the Osiconcept system are flush mountable in the metal without reducing thesensing distance and even allow an object to be detected against a metal background. Forfurther information, see page 37316/2 and 37316/3.

Sensors not suitable for flush mounting in metalb Side clearance requiredSensing distance greater than a standard flush mountable model.b The Osiconcept system eliminates the side clearance requirement. For further information,see page 37316/2 and 37316/3.

1 2 3

LED

Outputstate

LED

Outputstate

Objectpresent

No objectpresent

N/O output N/C output

3 Sn

Detected object

Me

tal

Met

al

3 Sn

2 Sn

Detected object

Me

tal

Me

tal



Mounting of sensors on a metal support Mounting in conjunction with fixing bracket

b Standard flush mountable models: e = 0, h = 0b Standard non flush mountable modelsv Ø 6.5 / 8 / 12 mm: e = 0, h = 0v Ø 18 mm: if h = 0, e u 5; e = 0, h u 3.Ø 30 mm: if h = 0, e u 8; e = 0, h u 4.b Osiconcept models: e = 0, h = 0

Mounting distance between sensors Standard sensors

Two sensors mounted too close to each other are likely to lock in the "detection state", due tointerference between their respective oscillating frequencies.To avoid this condition, minimum mounting distances given for the sensors should be adheredto or sensors with staggered oscillating frequencies used.

Staggered frequency sensors

For applications where the minimum recommended mounting distances for standard sensorscannot be achieved, it is possible to overcome this restraint by mounting a staggered frequencysensor adjacent or opposite to each standard sensor. For information on staggered frequencysensors, please consult your Regional Sales Office.

Tightening torque for cylindrical typesensors

Maximum tightening torque for the various sensor case materialsBrass Brass Stainless steel Plastic

Diameter ofsensor in mm

Short case model Form A model Form A model All modelsXS5 ppB1 XS6 ppB1

XS6 ppB2XS5 AVp

XS1 ppXS2 pp

XS4 Ppp

Ø 5 1.6 N.m 1.6 N.m 2 N.m –Ø 8 5 N.m 5 N.m 9 N.m 1 N.m

Ø 12 6 N.m 15 N.m 30 N.m 2 N.mØ 18 15 N.m 35 N.m 50 N.m 5 N.m

Ø 30 40 N.m 50 N.m 100 N.m 20 N.m

e (mm)

h (m

m)

Non ferrous orplastic material

e

e

Mounting side by sidee u 2 Sn

Mounting face to facee u 10 Sn



Sensing distance Definitions

To allow customers to make reliable comparisons and selections, the IEC 60947-5-2 standarddefines various sensing distances such as:b Nominal sensing distance (Sn)The rated operating distance for which the sensor is designed. It does not take into account anyvariations (manufacturing tolerances, temperature, voltage).b Real sensing distance (Sr)The real sensing distance is measured at the rated voltage (Un) and at the rated ambienttemperature (Tn).It must be between 90 % and 110 % of the real sensing distance (Sn): 0.9 Sn ≤ Sr ≤ 1.1 Sn.b Usable sensing distance (Su)The usable sensing distance is measured at the limits of the permissible variations in the ambienttemperature (Ta) and the supply voltage (Ub). It must be between 90 % and 110 % of the realsensing distance: 0.9 Sr ≤ Su ≤ 1.1 Sr.b Assured operating distance (Sa).This is the operating zone of the sensor. The assured operating distance is between 0 % and81 % of the nominal sensing distance (Sn): 0 ≤ Sa ≤ 0.9 x 0.9 x Sn

Standard metal targetThe IEC 60947-5-2 standard defines the standard metal target as a square mild steel (Fe 360)plate, 1 mm thick.The side dimension of the plate is either equal to the diameter of the circle engraved on the activesurface of the sensing face, or 3 times the nominal sensing distance (Sn).

Terminology Differential travel

The differential travel (H), or hysteresis, is the distance between the pick-up point, as thestandard metal target moves towards the sensor, and the drop-out point as it moves away.This hysteresis is essential for the stable operation of the sensor.

Repeat accuracyThe repeat accuracy (R) is the repeatability of the usable sensing distance between successiveoperations. Readings are taken over a period of time whilst the sensor is subjected to voltageand temperature variations: 8 hours, 10 to 30 °C, Un ± 5 %.It is expressed as a percentage of Sr.

Detection zone and precision adjustment zoneb Through sensitivity adjustment in teach mode, Osiconcept proximity sensors allow theposition of an object to be detected when it approaches from the front or the side.The teach mode can be used when the object is located in the zone known as the “precisionadjustment zone”. When the object approaches from the front, the object’s detection zone rangesfrom the stored distance to zero.

Operating zone

1 Detection threshold curves2 "Object detected" LED

b The operating zone relates to the area in front of the sensing face in which the detection of ametal object is certain.The values stated in the characteristics relating to the various types of sensor are for steelobjects of a size equal to the sensing face of the sensor.For objects of a different nature (smaller than the sensing face of the sensor, other metals, etc.),it is necessary to apply a correction coefficient.

Su max.

Sr max.

Sn

Sr min.

Su min.Sa=Certaindetection

Su max. + H

Sr max. + H

Sn + H

Sr min. + H

Su min.. + H

Sensing face

Standard metal target

Output ON Output OFF

H = differential travel

��

Assuredoperatingdistance


Sn

0.81 Sn


H

Sensingdistance

PE = pick-up pointPR = drop-out point

PRPE

Sensing range: Sr

Object detectionzone Example of stored

position

Precisionadjustment zone

12

Frontalapproach



Correction coefficients to apply to theassured sensing distance

Sensor operating distance

In practice, most target objects are generally made of steel and are of a size equal to, or greater,than the sensing face of the proximity sensor.

For the calculation of the assured operating distance for different operating conditions, one musttake into account the correction coefficients which influence it.

The curves indicated are purely representative of typical curves. They are only given as a guideto the approximate usable sensing distance of a proximity sensor for a given application.

Influence of ambient temperatureApply a correction coefficient Kθ determined from the curve shown opposite.

Influence of the object material to be detectedApply a correction coefficient Km, determined from the diagram shown opposite.

The fixed sensing distance models for ferrous/non ferrous (Fe/NFe) materials enable thedetection of different objects at a fixed distance, irrespective of the type of material.

Special case of a very thin object made of a non ferrous metal.

Size of the object to be detectedApply a correction coefficient Kd, determined from the curve shown opposite.When calculating the sensing distance for the selection of a sensor, make the assumption thatKd = 1.

Variation of supply voltageIn all cases, apply the correction coefficient Kt = 0.9.

Calculation examples Correction of the sensing distance of a sensor

Sensor with a nominal sensing distance Sn = 15 mm.Ambient temperature variation 0 to + 20°C.Object material and size: steel, 30 x 30 x 1 mm thick.The assured sensing distance Sa can be determined using the formula:Sa = Sn x Kq x Km x Kd x Kt = 15 x 0.98 x 1 x 0.95 x 0.9i.e. Sa = 12.5 mm.

Selecting a sensor for a given application

Application characteristics:- object material and size: iron (Km = 0.9), 30 x 30 mm,- temperature: 0 to 20 °C (Kθ = 0.98),- object detection distance: 3 mm ± 1.5 mm, i.e. Sa max. = 4.5 mm,- assume Kd = 1.A sensor must be selected for which Sn u

i.e. Sn u 5.7 mm

-25 0 20 50 70

1,1

0,9

Temperature °C

1Km

0,5

type316

magn. CuAU4GUZ33A37type304

Stainless steel Steel Brass Alumin.

CopperIron Lead Bronze

1Km0,9

0,80,7

0,60,5

0,40,3

0,2

0,2 0,4 1

0,1

0,1 0,3 0,5 1,5 Thickness ofobject (mm)

Typical curve for a copper object used with a Ø 18 mmcylindrical sensor

4 Sn3 Sn2 SnSn

1Kd0,9

0,80,7

0,60,5

0,40,3

0,20,1

Typical curve for a steel object used with a Ø 18 mmcylindrical sensor

SaKq x Km x Kd x Kt = 4.5

0.98 x 0.9 x 1 x 0.9



Specific aspects of electronic sensors Terminology

b Residual current (Ir)v The residual current (Ir) corresponds to the current flowing through the sensor when in the"open" state.v Characteristic of 2-wire type proximity sensors.

b Voltage drop (Ud)v The voltage drop (Ud) corresponds to the voltage drop at the sensor’s terminals when in the"closed" state (value measured at nominal current rating of sensor).

b First-up delayv The first-up delay corresponds to the time (t) between the connection of the power supply tothe proximity sensor and its fully operational state.1 Supply voltage U on2 Sensor operational at state 13 Sensor at state 0

b Delaysv Response time (Ra): the time delay between the object to be detected entering the proximitysensor’s operating zone and the subsequent change of output state. This parameter limits thespeed and size of the object.v Recovery time (Rr): the time delay between an object to be detected leaving the sensor’soperating zone and the subsequent change of output state. This parameter limits the intervalbetween successive objects.

Supply Sensors for a.c. circuits (a and z models)

Check that the voltage limits of the sensor are compatible with the nominal voltage of the a.c.supply used.

Sensors for d.c. circuitsb d.c. source: check that the voltage limits of the sensor and the acceptable level of ripple, arecompatible with the supply used.

b a.c. source (comprising transformer, rectifier, smoothing capacitor): the supply voltage mustbe within the operating limits specified for the sensor.

Where the voltage is derived from a single-phase a.c. supply, the voltage must be rectified andsmoothed to ensure that:- the peak voltage of the d.c. supply is lower than the maximum voltage rating of the sensor.Peak voltage = nominal voltage x √2- the minimum voltage of the supply is greater than the minimum voltage rating of the sensor,given that:∆V = (I x t) / C∆V = max. ripple: 10% (V),I = anticipated load current (mA),t = period of 1 cycle (10 ms full-wave rectified for a 50 Hz supply frequency),C = capacitance (µF).As a general rule, use a transformer with a lower secondary voltage (Ue) than the required d.c.voltage (U).

Example:a 18 V to obtain c 24 V,a 36 V to obtain c 48 V.

Outputs Output signal (contact logic)

b N/OCorresponds to a sensor whose output changes to the closed state when an object is present inthe operating zone.

b N/CCorresponds to a sensor whose output changes to the open state when an object is present in theoperating zone.

b N/O + N/C complementary outputsCorresponds to a sensor with a normally closed output and a normally open output.

IrMA

XS

UdV

XS

t

1

2

3

Ra Rr

Detectedobject

Sensoroutput



Outputs (continued) 2-wire type c, non polarised NO or NC output

b Specific aspectsThese sensors are wired in series with the load to be switched.As a consequence, they are subject to:v a residential current in the open state (current flowing through the sensor in the “open” state),v a voltage drop in the closed state (voltage drop across the sensor’s terminals in the “closed”state).

b Advantages:v Only 2 leads to be wired: these sensors can be wired in series in the same way as mechanicallimit switches,v They can be connected to either positive (PNP) or negative (NPN) logic PLC inputs,v No risk of incorrect connections.

b Operating precautionsv Check the possible effects of residual current and voltage drop on the actuator or inputconnected,v For sensors that do not have overload and short-circuit protection (a.c. or a.c./d.c. symbol), itis essential to connect a 0.4 A quick-blow fuse in series with the load.

3-wire type c, NO or NC output; PNP or NPN

b Specific aspectsv These sensors comprise 2 wires for the d.c. supply and a third wire for the output signal,v PNP type: switching the positive side to the load,v NPN type: switching the negative side to the load.

b Advantages:v Protected against reverse supply polarity,v Overload and short-circuit protection,v No residual current, low voltage drop.

4-wire type, complementary outputsc, NO and NC outputs, PNP or NPN,b Advantages:v Protected against reverse supply polarity (+/-),v Overload and short-circuit protection.

4-wire type, multifunction, programmablec, NO or NC output, PNP or NPN,b Advantages:v Protected against reverse supply polarity (+/-),v Overload and short-circuit protection.

Specific output signals, analogue type

b These sensors convert the approach of a metal object towards the sensing face into an outputcurrent variation which is proportional to the distance between the object and the sensing face.b Two models available:- output 0...10 V (0...10 mA) for 3-wire connection,- output 4-20 mA for 2-wire connection.

BU

BN

BU

BN

BU

BN

BU

BK

BNPNP

+

–

+

–BU

BK

BNNPN

BU

WH (NC)

BK (NO)BNPNP

+

–

+

–BU

BK (NO)

WH (NC)

BNNPN

BK

WH

BN (NO), BU (NC)

BU (NO), BN (NC)

BN (NO), BU (NC)

BU (NO), BN (NC)

PNP

+

–

+

–

WH

BK

NPN

+

–S I

+

–

S I

2-wire connection 3-wire connection



Features of the various models Types of case

b Cylindrical casev Fast installation and setting-up,v Pre-cabled and connector versions,v Small size facilitates mounting in locations with restricted access.v Interchangeability, provided by indexed fixing bracket: when assembled, becomes similarto a block type sensor.

. b Flat casev Reduced size (sensor volume divided by 8).v Fast installation by mounting on clip-on brackets.v Precision detection through Osiconcept teach mode.

Electrical connection Connection methods

1 Pre-cabled: factory fitted moulded cable, good protection against splashing liquids (IP 68).Example: machine tool.2 Connector: easy installation and maintenance (IP 67).3 Remote connector: easy installation and maintenance (IP 68 at sensor level and IP 67 atremote connector level).

Wiring adviceb Length of cablev No limitation up to 200 m or up to a line capacitance of < 100 nF (characteristics of sensorremain unaffected),v In this case, it is important to take into account the voltage drop on the line.

b Separation of control and power circuit wiringv The sensors are immune to electrical interference encountered in normal industrialconditions,v Where extreme conditions of electrical "noise" could occur (large motors, spot welders, etc.),it is advisable to protect against transients in the normal way:- suppress interference at source,- separate power and control wiring from each other,- smooth the supply,- limit the length of the cable.

b Connect the sensor with the supply off.

XSp E

XSp CXSp D

XS7 F

XS7 J

1

2

3



Setting-up Connection in series

2-wire type proximity sensorsb The following points should be taken into account:v Series wiring is only possible using sensors with wide voltage limits.Based on the assumption that each sensor has the same residual current value, each sensor, inthe open state, will share the supply voltage, i.e.

U sensor = .

U sensor and U supply must remain within the sensor’s voltage limits.v If only one sensor in the circuit is in the open state, it will be supplied at a voltage almost equalto the supply voltage.v When in the closed state, a small voltage drop is present across each sensor. The resultantloss of voltage at the load will be the sum of the individual voltage drops and therefore, the loadvoltage should be selected accordingly.

3-wire type proximity sensorsThis connection method is not recommended.b Correct operation of the sensors cannot be assured and, if this method is used, tests must bemade before installation.The following points should be taken into account:v Sensor 1 carries the load current in addition to the no-load current consumption values of theother sensors connected in series. For certain models, this connection method is not possibleunless a current limiting resistor is used.v When in the closed state, a small voltage drop is present across each sensor. The load shouldthus be selected accordingly.v As sensor 1 closes, sensor 2 does not operate until a certain time "t" has elapsed(corresponding to the first-up delay) and likewise for the following sensors in the sequence.v The use "flywheel" diodes is recommended when an inductive load is being switched.

Sensors and devices in series with an external mechanical contact

2 and 3-wire type sensorsb The following points should be taken into account:v When the mechanical contact is open, the sensor is not supplied.v When the contact closes, the sensor does not operate until a certain time "t" has elapsed(corresponding to the first-up delay).

Connection in parallel2-wire type proximity sensors

This connection method is not recommended.b Should one of the sensors be in the closed state, the sensor in parallel will be "shorted-out"and no longer supplied.As the first sensor passes into the open state, the second sensor will become energised and willbe subject to its first-up delay.b This configuration is only permissible where the sensors will be working alternately.b This method of connection can lead to irreversible damage of the units.

3-wire type proximity sensorsb No specific restrictions. The use of “flywheel” diodes is recommended when an inductive load(relay) is being switched.

a.c. supply

b 2-wire type sensors cannot be connected directly to an a.c. supply.v This would result in immediate destruction of the proximity sensor and considerable danger tothe user.v An appropriate load (refer to the instruction sheet supplied with the sensor) must always beconnected in series with the proximity sensor.

Capacitive load (C > 0.1 µF)b At switch-on, it is necessary to limit (by resistor) the charging current of the capacitive load C.v The voltage drop in the sensor can also be taken into account by subtracting it from the supplyvoltage for calculation of R.

R =

Load comprising an incandescent lampb If the load comprises an incandescent lamp, the cold state resistance can be 10 times lowerthan the hot state resistance. This can cause very high current levels on switching. Fit a pre-heatresistance in parallel with the proximity sensor.

R = , U = supply voltage and P = lamp power

U supply

n sensors

R

CU (supply)I max. (sensor)

U2

Px 10



Fast troubleshooting guideProblem Possible causes Remedy

The sensor’s output will not change state when a metalobject enters the detection zone

On an Osiconcept sensor:setting-up or programming error.

b After a RESET, follow the environment teach modeprocedure. See the sensor instruction sheet.

Output stage faulty or completefailure of the sensor or theshort-circuit protection has tripped

b Check that the proximity sensor is compatible with thesupply being used.b Check the load current characteristics:v if load current I ≥ maximum switching capacity, anauxiliary relay, of the CAD N type for example, should beinterposed between the sensor and the load,v if I ≤ maximum switching capacity, check for wiringfaults (short-circuit).b In all cases, a 0.4 A "quick-blow" fuse should be fitted inseries with the sensor.

Wiring error b Verify that the wiring conforms to the wiring shown onthe sensor label or instruction sheet.

Supply fault b Check that the sensor is compatible with the supply (aor c).b Check that the supply voltage is within the voltage limitsof the sensor. Remember that with a rectified, smoothedsupply,U peak = U nominal x 2 with a ripple voltage ≤ 10 %.

False or erratic operation, with or without the presence ofa metal object in the detection zone

On an Osiconcept sensor:setting-up or programming error.

b After a RESET, follow the environment teach modeprocedure. See the sensor instruction sheet.

Influence of background or metalenvironment

b Refer to the instruction sheet supplied with the sensor.For sensors with adjustable sensitivity, reduce the sensingdistance.

Operating distance poorly definedfor the object to be detected

b Apply the correction coefficients.b Realign the system or run the teach mode again.

Influence of transient interference onthe supply lines

b Ensure that any d.c. supplies, when derived fromrectified a.c., are correctly smoothed (C > 400 µF).b Separate a.c. power cables from d.c. low-level cables(24 V low level).b Where very long distances are involved, use suitablecable: screened and twisted pairs of the correctcross-sectional area.

Equipment liable to emitelectromagnetic interference

b Position the sensors as far away as possible from anysources of interference.

Response time of the sensor tooslow for the particular object beingdetected

b Check the suitability of the sensor for the position orsize of the object to be detected.b If necessary, select a photo-electric sensor with ahigher switching frequency.

Influence of high temperature b Eliminate sources of radiated heat, or protect thesensor casing with a heat shield.b Realign, having adjusted the temperature around thefixing support.

No detection following a period of service Vibration, shock b Realign the system.b Replace the support or protect the sensor.

37018-en_Ver1.1.fm/2 Schneider Electric

Product association 2 Inductive proximity sensors 2

XS compatibility with other Telemecaniqueproductsd.c. circuits

Operation on d.c.Type of output 3-wire, solid-stateOutput current 50 mA 100 mA 200 mASensor type XS1 D08 pA140p (1)

XS1 L06 pA140p (1)XS1 D ppp A140 ppXS1 ppppp 31p ppXS2 D ppp A140 ppXS6 pp B2 ppppXS7 p 1A1 ppppXS7 V12 p A332 pp (1)XS8 E 1A1 ppppXS9 E 11RPB ppppXSp G 12 p A140 pp (1)

XS1 L06 p C410XS1 L06 pp 34p ppXS1 Mpp KPM40 ppXS1 M18 PASpp ppXS2 L06 p A340 ppXS4 Ppp pp 340 ppXS5 pp B1 ppppXS7 C40 KPM40XS8 p 1A1 ppppXS9 C 11RPB pppp

XS6 pp B1 ppppXSp G12 p C440

Supply voltage (V) 12 24 12 24 12 24 24 48

Contactors (2)

TeSys model d contactors LCp D09…D38

TeSys model k contactors LP1 K, LP2 KLP4 K, LP5 K

Mini-contactors LP1 SK06

Interface modules LA4 DFBQ/DFB/DLBLA4 DFE/DLE

LA4 DWBLA4 DT

Control relays CA3 K

CA4 KCADCAD low consumption

Starters, drivesSoft start - soft stop units LH4 except N106, N112, N125

for LI (logic inputs)b b b b

ATS 46, ATS 48

Variable speed drives ATV 08, ATV 11, ATV 28,ATV 58, ATV 58F,VW3 A58 (communication cardfor ATV 58)ATV 68VW3 A68 (communication cardfor ATV 68)

b b b b

Automation system relaysPlug-in relays RHC

RHD/RHERHNRHR/RHT

Universal relays RUN 21, RUN 31, RUN 33

Miniature relays RXNTiming relays RE1 LA

RE7 pp1pBU

RE7 ppppMWRE8RE9

Measurement and control relays RM3 PA101RM3 PA102

RM4 JA31/JA32RM4 LA32

RM4 UA3p(1) When used on a rectified and smoothed 24 V supply, ensure that the maximum voltage (including ripple) is less than 30 V.(2) It is recommended that suppressor blocks are mounted on the contactors. Refer to our catalogue: "Motor starter solutions - Control and protection components".

Association possible.

Association not possible.

Association impractical.

Association to be tested.b

37018-en_Ver1.1.fm/3Schneider Electric

Product association(continued) 2

Inductive proximity sensors 2


Operation on d.c. (continued)Type of output 2-wire, solid-state 2-wire, solid-state (a/c)Output current 100 mA 100 mA 200 mASensor type XS7 p 1A1 pppp XS5 pp B1 Dp pp XS4 P08 Mp230 pp

XS9 E 11RMB ppppXS4 P12 Mp230 ppXS4 P18 Mp230 ppXS4 P30 Mp230 ppXS6 pp B1 Mp ppXS8 p 1A1 ppppXS9 C 11 RMB ppppXSp G12 Mp230

Supply voltage (V) 12 24 24 48 24 48 110 230 24 48 110 230

Contactors (2)

TeSys model d contactors LCp D09…D38

TeSys model k contactors LP1 K, LP2 KLP4 K, LP5 K

Mini-contactors LP1 SK06

Interface modules LA4 DFBQ/DFB/DLBLA4 DFE/DLE F FLA4 DWBLA4 DT

Control relays CA3 K

CA4 KCADCAD (low consumption)

Starters, drivesSoft start - soft stop units LH4 except N106, N112, N125

for LI (logic inputs)b b b b

ATS 46, ATS 48

Variable speed drives ATV 08, ATV 11, ATV 28,ATV 58, ATV 58F,VW3 A58 (communication cardfor ATV 58)

A1 A1 A1F

A1F

ATV 68VW3 A68 (communication cardfor ATV 68)

b b b b

Automation system relaysPlug-in relays RHC

RHD/RHERHNRHR/RHT

Universal relays RUN 21, RUN 31, RUN 33

Miniature relays RXNTiming relays RE1 LA

RE7 pp1pBU

RE7 ppppMWRE8RE9

Measurement and control relays RM3 PA101RM3 PA102

RM4 JA31/JA32RM4 LA32

RM4 UA3p(2) It is recommended that suppressor blocks are mounted on the contactors. Refer to our catalogue: "Motor starter solutions - Control and protection components".




Association to be tested.

Load impedance too high to ensure reliable operation of the sensor with an ATV 08 drive(add a resistor in parallel with the load).These products are not compatible with sensors having a residual current Ir u 1.5 mA(add a resistor in parallel with the load).

b

A1

F





Operation on d.c. (continued)Type of output 3-wire, solid-stateOutput current 50 mA 100 mA 200 mASensor type XS1 D08 pA140p (1)




Supply voltage (V) 12 24 12 24 12 24 24 48

Zelio Logic smart relaysSR1 ppppBD (discrete inputs)SR1 ppppBD (analogue inputs) b b b b

Electromechanical and electronic interfacesConnection sub-bases ABE 7S16 E2B1

ABE 7S16 E2E1

Electromechanical interfacemodules

ABR 1ppp8pABR 1Ep12F

ABR 1Sp02B/2pB312BABR 2E112pABR 2S1p2B

ABR 7 S33ESolid-state interface modules ABS 2EC01Ep

ABS 2SA0pMBABS 2SC0pEB

Plug-in solid-state relays ABS 7 EC3p2ABS 7 SC1B/SC2E,ABS 7 SC3E/SC3BA,ABS 7 SA2M/SA3M

(1) When used on a rectified and smoothed 24 V supply, ensure that the maximum voltage (including ripple) is less than 30 V.Association possible.








Operation on d.c. (continued)Type of output 2-wire 2-wire, solid-state (a/c)Output current 100 mA 100 mA 200 mASensor type XS7 p 1A1 pppp XS5 pp B1 Dp pp XS4 P08 Mp230 pp


Supply voltage (V) 12 24 24 48 24 48 110 230 24 48 110 230

Zelio Logic smart relaysSR1 ppppBD (discrete inputs)SR1 ppppBD (analogue inputs)

Electromechanical and electronic interfacesConnection sub-bases ABE 7S 16E2B1

ABE 7S 16E2E1

Electromechanical interfacemodules

ABR 1ppp8pABR 1Ep12F

ABR 1Sp02B/2pB312BABR 2E112pABR 2S1p2B

ABR 7 S33E BF

BF

BF

Solid-state interface modules ABS 2EC01EpABS 2SA0pMBABS 2SC0pEB

Plug-in solid-state relays ABS 7 EC3p2ABS 7 SC1B/SC2E,ABS 7 SA2M/SC3BA,ABS 7 SC3E/SA3M





Products not compatible with sensors having a residual current Ir u 0.8 mA (add aresistor in parallel with the load).

Products not compatible with sensors having a residual current Ir u 1.5 mA (add aresistor in parallel with the load).

b

B

F









Supply voltage (V) 12 24 12 24 12 24 24 48

Nano and Micro PLCsNano PLC bases TSX 07Simulator modules TSX ACZ 03

Discrete I/O modules TSX DEZ 12D2TSX DEZ 12D2K/32D2TSX DMZ 16DTK/28DTKTSX DMZ 28DT/64DTK

F F F F

TSX DMZ 28DR G G G GCounting modules TSX CTZ pp (except c 5 V)

Premium PLCsDiscrete I/O modules TSX DEY 08D2/16D2

TSX DEY 16D3/32D3KTSX DEY 16A2 G G G GTSX DEY 16FK/32D2K/64D2KTSX DMY 28FK/28RFK

TBX CEP 1622TBX DES 1622/16C22/16F22

TBX DES 1633TBX DMS 1025/1625,TBX DMS 16C22/16C222,TBX DMS 16P22TBX EEP 08C22 (Fipio)

TBX EEP 1622 (Fipio)Momentum discrete I/O sub-bases

170 ADI 3p0 00170 ADM 350 1p/370 10170 ADM 390 p0170 EDI 346 00

170 AMM 090 00Counting modules TSX CTY 2A/4A

TSX CTY 2C

Axis control modules forservomotors (counting inputs notcompatible)

TSX CAY (drive control input)TSX CAY (auxiliary inputs)

Axis control modules for steppermotors

TSX CFY (auxiliary inputs)

Quantum PLCsDiscrete I/O modules b b b b b b b b

(1) When used on a rectified and smoothed 24 V supply, ensure that the maximum voltage (including ripple) is less than 30 V.Association possible.




These products are not compatible with sensors having a residual current Ir u 1.5 mA(add a resistor in parallel with the load).

Load with "negative logic" type operation (high level = 0 V and low level = 24 V), notcompatible with "positive logic" sensors.

b

F

G







Supply voltage (V) 12 24 24 48 24 48 110 230 24 48 110 230

Nano and Micro PLCsNano PLC bases TSX 07 F FSimulator modules TSX ACZ 03 F FDiscrete I/O modules TSX DEZ 12D2

TSX DEZ 12D2K/32D2TSX DMZ 16DTK/28DTKTSX DMZ 28DT/64DTK

A2F

A2F

A2F

A2F

TSX DMZ 28DR G G G GCounting modules TSX CTZ pp (except c 5 V)

Premium PLCsDiscrete I/O modules TSX DEY 08D2/16D2

TSX DEY 16D3/32D3KTSX DEY 16A2

TSX DEY 16FK/32D2K,TSX DEY 64D2K

A A AF

AF

TSX DMY 28FK/28RFK A A AF

AF

TBX CEP 1622 F FTBX DES 1622/16C22/16F22TBX DES 1633TBX DMS 1025/1625,TBX DMS 16C22/16C222/16P22TBX EEP 08C22 (Fipio)

TBX EEP 1622 (Fipio) F FMomentum discrete I/O sub-bases

170 ADI 3p0 00 F F170 ADM 350 1p/370 10170 ADM 390 p0

F F

170 EDI 346 00

170 AMM 090 00 F FCounting modules TSX CTY 2A/4A

TSX CTY 2C

Axis control modules forservomotors (counting inputs notcompatible)

TSX CAY (drive control input)TSX CAY (auxiliary inputs) F F

Axis control modules for steppermotors

TSX CFY (auxiliary inputs)

Quantum PLCsDiscrete I/O modules b b b b b b b b b b b b





Load impedance too high to ensure reliable operation of the sensor (add a resistor inparallel with the load).Load impedance too high to ensure reliable operation of the sensor associated with theTSX DMZ 64DTK (add a resistor in parallel with the load).


Load with "negative logic" type operation (high level = 0 V and low level = 24 V), notcompatible with "positive logic" sensors.

b

A

A2A2

F

G









Supply voltage (V) 12 24 12 24 12 24 24 48

TSX series 7 PLCsTSX 171pp/172pp,TSX DMF242A/3ppA (isolatedinputs)

TSX 171pp,TSX DMF 400 (non isolatedinputs)TSX DEF 812

Discrete input interfaces TSX DET 32 p2,TSX DET 8 12/16 12TSX DET 32 52

TSX DET 8 1p/16 1p/16 33TSX DET 8 24

Counting interface TSX AXT

Communication modules TSX DEM 241p

AS-i cabling system b b b b b b b b

Twido programmable controllersModular bases TWD LMDAppDppDiscrete I/O modules TWD DDIppDT/DDIppDK

TWD LCAAppppp(1) When used on a rectified and smoothed 24 V supply, ensure that the maximum voltage (including ripple) is less than 30 V.











Supply voltage (V) 12 24 24 48 24 48 110 230 24 48 110 230

TSX series 7 PLCsTSX 171pp/172pp,TSX DMF242A/3ppA (isolatedinputs)

F F

TSX 171pp,TSX DMF 400 (non isolatedinputs)TSX DEF 812

Discrete input interfaces TSX DET 32 p2,TSX DET 8 12/16 12TSX DET 32 52 F FTSX DET 8 1p/16 1p/16 33TSX DET 8 24

Counting interface TSX AXT

Communication modules TSX DEM 241p F F

AS-i cabling system b b b b b b b b b b b b

Twido programmable controllersModular bases TWD LMDAppDppDiscrete I/O modules TWD DDIppDT/DDIppDK

TWD LCAApppppAssociation possible.





b

F


Product association 2 Inductive proximity sensors 2

XS compatibility with other Telemecaniqueproductsa.c. circuits

Operation on a.c.Type of output 2-wire, solid-state (a/c)Output current 100 mA 200 mA 300 mASensor type XS4 P08 Mp230 pp

XS9 E 11RMB ppppXS1 M12 FA264XS4 P12 Mp230 ppXS6 12 B1 Mp ppXS8 E 1A1 ppppXSp G12 Mp230

XS1 M18 FA264XS1 M30 FA264XS4 P18 Mp230 ppXS4 P30 Mp230 ppXS6 18 B1 Mp ppXS6 30 B1 Mp ppXS8 C 1A1 ppppXS8 D 1A1 ppppXS9 C 11RMB pppp

Supply voltage (V) 24 48 110 230 24 48 110 230 24 48 110 230

Contactors (2)TeSys model d contactors LCp D09…D38

TeSys model k contactors LC1 K, LC2 K, LC7 K, LC8 KMini-contactors LC1 SK06/SKGC2

LC1 SKGC3/SKGC4Interface modules LA4 DT

Control relays CA2 KCAD

Control relays + suppressorblocks

CAD + LAD 4RCE,CAD + LAD 4VECAD + LAD 4RCU,CAD + LAD 4VU

CAD + LAD 4VGModular contactors GC 16/25/40/63 (2-pole)

GC 40/63 (3 or 4-pole)GC 100 (2-pole)

GC 100 (4-pole)GY 16/25/40/63 (2-pole)GY 40/63 (3 or 4-pole)

Automation system relaysPlug-in relays RHC/RHD/RHE

RHN 4p1pRHN 4p6pRHR/RHT

Universal relays RUN 21, RUN 31, RUN 33Miniature relays RXNTiming relays RE1

RE7RE8RE9

Measurement and control relays RM3 EA1

RM3 PA101 MWRM3 PA101 FU7RM3 PA102

RM4 JA01 b b b b b bRM4 JA31 MW, RM4 JA32 MW b b b b b b b b b b b bRM4 JA31 F/M, RM4 JA32 F/M b b b b b bRM4 LA32 MW

RM4 LA32 B/F/MRM4 LG01RM4 UA0p b b b b b bRM4 UA3p MW b b b b b b b b b b b bRM4 UA3p b b b b b b

Zelio Logic smart relaysSR1 p101FUSR1 p201FU

(2) It is recommended that suppressor blocks are mounted on the contactors. Refer to our catalogue: "Motor starter solutions - Control and protection components".Association possible.







XS compatibility with other Telemecaniqueproductsa.c. circuits

Operation on a.c. (continued)Type of output 2-wire, solid-state (a/c)Output current 100 mA 200 mA 300 mASensor type XS4 P08 Mp230 pp

XS9 E 11RMB ppppXS1 M12 FA264XS4 P12 Mp230 ppXS6 12 B1 Mp ppXS8 E 1A1 ppppXSp G12 Mp230

XS1 M18 FA264XS1 M30 FA264XS4 P18 Mp230 ppXS4 P30 Mp230 ppXS6 18 B1 Mp ppXS6 30 B1 Mp ppXS8 C 1A1 ppppXS8 D 1A1 ppppXS9 C 11RMB pppp

Supply voltage (V) 24 48 110 230 24 48 110 230 24 48 110 230

Electromechanical and electronic interfacesConnection sub-bases ABE 7S16 E2p0 F1 F1 F1Electromechanical interfacemodules

ABR 1ppp1FABR 1ppp8B/1ppp8E

ABR 1Epp1MABR 2E111M

ABR 2E11pFSolid-state interface modules ABS 2EA0pEF

ABS 2EA0pEM

Plug-in solid-state relays ABS 7 EC3p5 F2 F2 F2

Nano and Micro PLCsNano PLC bases TSX 07 30 ppp8/31 ppp8,

TSX 07 32 ppp8/33 ppp8,TSX 07 3L pp28,TSX 07 EX pp28

Discrete I/O modules TSX DEZ 08ApTSX DMZ 28AR

Premium PLCsDiscrete I/O module TSX DEY 16Ap

TBX DES 16S04

TBX DMS 16S44Momentum discrete I/O sub-base

170 ADI 540 50

170 ADM 690 50

Quantum PLCsDiscrete I/O modules b b b b b b b b b b b b

TSX series 7 PLCsTSX 172 pppppTSX DMF 344A

TSX DEF 804TSX DET 16 03/16 04TSX DET 8 02/03/05TSX DET 8 24

AS-i cabling system b b b b b b b b b b b b





The sub-base ABE 16S E20 is not compatible with sensors having a residual currentIr u 1.5 mA (add a resistor in parallel with the load).The relay ABS 7 EC3E is not compatible with sensors having a residual current Ir u1.5 mA (add a resistor in parallel with the load).

b

F1

F2


Sensors with closest functionalities 0

Substitution table 2Inductive proximity sensors 2

Replaced sensor New Osiprox sensor

Cylindrical type, d.c. supply

8 mm diameter

XS1M08DA210 XS508B1DAL2

XS1M08DA210D XS508B1DAM12

XS1M08DA210L1 XS508B1DAL5


XS1M08DA210LD XS508B1DAM12 (1)

XS1M08DA214D XS508B1CAM12

XS1M08DA214LD XS508B1CAM12 (1)

XS1M08DB210 XS508B1DBL2

XS1M08DB210D XS508B1DBM12

XS1M08DB210L1 XS508B1DBL5

XS1M08DB210LD XS508B1DAM12 (1)

XS1M08NA370 XS608B1NAL2

XS1M08NA370D XS608B1NAM12

XS1M08NA370L1 XS608B1NAL5

XS1M08NB370 XS608B1NBL2

XS1M08NB370D XS608B1NBM12

XS1M08PA370 XS608B1PAL2

XS1M08PA370D XS608B1PAM12

XS1M08PA370L1 XS608B1PAL5


XS1M08PA370LD XS608B1PAM12 (1)

XS1M08PA370S XS608B1PAM12 (2)

XS1M08PB370 XS608B1PBL2

XS1M08PB370D XS608B1PBM12

XS1M08PB370L1 XS608B1PBL5


XS1N08NA340 XS508B1NAL2

XS1N08NA340D XS508B1NAM8 (3)

XS1N08NA340L1 XS508B1NAL5


XS1N08NA340S XS508B1NAM8


XS1N08NA349D XS608B1NAM12


XS1N08NA349S XS608B1NAM12 (2)

XS1N08NB340 XS508B1NBL2

XS1N08NB340D XS508B1NBM8 (3)

XS1N08NB340S XS508B1NBM8


XS1N08NB349D XS608B1NBM12

XS1N08NB349S XS608B1NBM12 (2)

XS1N08PA340 XS508B1PAL2

XS1N08PA340D XS508B1PAM8 (3)

XS1N08PA340L1 XS508B1PAL5


XS1N08PA340LD XS508B1PAM12 (1)

XS1N08PA340S XS508B1PAM8


XS1N08PA349D XS608B1PAM12




XS1N08PA349S XS608B1PAM12 (2)

XS1N08PB340 XS508B1PBL2

XS1N08PB340D XS508B1PBM8 (3)

XS1N08PB340L1 XS508B1PBL5

XS1N08PB340S XS508B1PBM8


XS1N08PB349D XS608B1PBM12



XS1N08PB349S XS608B1PBM12 (2)





XS2N08NA340S XS608B1NAM12 (2)









XS2N08PB340S XS608B1PBM12 (2)

XS3P08NA340 XS508B1NAL2

XS3P08NA340D XS508B1NAM8 (3)


XS3P08PA340 XS508B1PAL2

XS3P08PA340D XS508B1PAM8 (3)

XS3P08PA340L1 XS508B1PAL5


12 mm diameter










XS1M12DB210L1 XS512B1DBL5

XS1M12DB210LD XS512B1DBM12 (1)






XS1M12NA370S XS612B1NAM12 (2)












XS1M12PB370LD XS612B1PAM12 (1)












XS1N12NB349L1 XS612B1NBL5

XS1N12NB349L2 XS612B1NBL10





















(1) An M12 connector replaces the 0.80 m flying lead with M12 connector.(2) An M12 connector replaces the M8 connector.(3) An M8 connector replaces the M12 connector.




Cylindrical type, d.c. supply (continued)

12 mm diameter (continued)










XS2M12PB370S XS612B1PBM12 (2)














XS3P12NA340D XS512B1NAM12



XS3P12PA340D XS512B1PAM12




18 mm diameter









XS1M18DB210D XS518B1DAM12

XS1M18DB210LD XS518B1DAM12 (1)








XS1M18NB370L1 XS618B1NBL5

XS1M18NB370L2 XS618B1NBL10








XS1M18PB370L1 XS618B1PAL5

XS1M18PB370L2 XS618B1PAL10





XS1N18NA349 XS618B1NAL2 (4)


XS1N18NA349L1 XS618B1NAL5 (4)



XS1N18NB349 XS618B1NAL2 (4)

XS1N18NB349D XS618B1NAM12 (4)





XS1N18PA349 XS618B1PAL2 (4)


XS1N18PA349L1 XS618B1PAL5 (4)


XS1N18PA349S XS618B1PAM12 (2 ) (4)




XS1N18PB349 XS618B1PBL2 (4)


XS1N18PB349L1 XS618B1PBL5 (4)


XS1N18PB349S XS618B1PBM12 (2) (4)

XS2M18DA210L2 XS612B1MAL10 (5)




























XS3P18NA370L1 XS618B1NAL5






30 mm diameter










XS1M30DB210LD XS530B1DBM12 (1)







XS1M30PA349D XS630B1PAM12 (6)



(1) An M12 connector replaces the 0.80 m flying lead with M12 connector.(2) An M12 connector replaces the M8 connector.(4) Sn = 8 mm instead of 5 mm.(5) Leakage current = 5 mA instead of 1.5 mA.(6) Sn = 6 mm instead of 7 mm.




Cylindrical type, d.c. supply (continued)












XS1N30NA349 XS630B1NAL2 (6)





XS1N30NB349 XS630B1NBL2 (6)

XS1N30NB349D XS630B1NBM12 (6)





XS1N30PA349 XS630B1PAL2 (6)




XS1N30PA349S XS630B1PAM12 (2) (6)



XS1N30PB349 XS630B1PBL2 (6)






































Cylindrical type, a.c. supply

12 mm diameter

XS1M12MA230 XS612B1MAL2

XS1M12MA230K XS612B1MAU20

XS1M12MA230L1 XS612B1MAL5




XS1M12MB230 XS612B1MBL2

XS1M12MB230K XS612B1MBU20

XS1M12MB230L1 XS612B1MBL5










XS3P12MA230 XS612B1MAL2

XS3P12MA230K XS612B1MAU20

XS3P12MA230L1 XS612B1MAL5

XS3P12MB230 XS612B1MBL2

XS3P12MB230K XS612B1MBU20

18 mm diameter





XS1M18MA239 XS618B1MAL2 (4)

XS1M18MA239K XS618B1MAU20 (4)


















(1) An M12 connector replaces the 0.80 m flying lead with M12 connector.(2) An M12 connector replaces the M8 connector.(4) Sn = 8 mm instead of 5 mm.(6) Sn = 6 mm instead of 7 mm.




Cylindrical type, a.c. supply (continued)



XS3P18MB230A XS618B1MBU20


XS3P18MB230L1 XS618B1MBL5

30 mm diameter





XS1M30MA239 XS630B1MAL2 (6)



















XS3P30MB230L1 XS630B1MBL5


(6) Sn = 6 mm instead of 7 mm.

Documents

References Inductive proximity sensors - Trinet Gruptrinetgrup.ro/cat_schneider/pdf/Detectie/2_4_Osiprox_accesories_tables.pdf · An alternating magnetic field is generated in front