Banner T30 AC Photoelectric Sensors - Clearwater Technologies Inc

T30 Series NAMUR Fixed-Field Sensors For Intrinsically Safe Operation in Hazardous Areas

Features • Intrinsically safe sensors featuring EZ-BEAM® technology; the specially designed optics and electronics provide reliable sensing without the need for adjustments • “T” style plastic housing with 30 mm threaded lens • Completely epoxy-encapsulated to provide superior durability, even in harsh sensing environments rated to IP69K • Innovative dual-indicator system takes the guesswork out of sensor performance monitoring • Advanced diagnostics to warn of marginal sensing conditions or output overload • 5 to 15V dc; constant current output

Models Far-Limit Cutoff

Models

LED

Supply Voltage

Excess Gain

Performance based on use of a 90% reflectance white test card.† 1000

T30AD9FF150 (2 m cable) 150 mm (6") T30AD9FF150Q (4-pin Euro-style QD fitting)

Infrared 880 nm

5 to 15V dc

E X C E S S G A I N

T30 NAMUR Fixed-Field

100

†Using

18% gray test card: Cutoff distance will be 95% of value shown. †Using 6% black test card: Cutoff distance will be 90% of value shown.

10

1 1 mm (0.04")

10 mm (0.4")

100 mm (4")

1000 mm (40")

DISTANCE

* A model with a QD connector requires a mating cable; see page 11.

WARNING . . . Not To Be Used for Personnel Protection Never use these products as sensing devices for personnel protection. Doing so could lead to serious injury or death. These sensors do NOT include the self-checking redundant circuitry necessary to allow their use in personnel safety applications. A sensor failure or malfunction can cause either an energized or de-energized sensor output condition. Consult your current Banner Safety Products catalog for safety products which meet OSHA, ANSI and IEC standards for personnel protection.

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]

T30 Series — NAMUR Fixed-Field Sensors Fixed-Field Mode Overview T30 Series self-contained fixed-field sensors are small, powerful, infrared diffuse mode sensors with far-limit cutoff (a type of background suppression). Their high excess gain and fixed-field technology allow them to detect objects of low reflectivity, while ignoring background surfaces.

Receiver Elements Near R1 Detector

Cutoff Distance Object B or Background

Object A Lenses

Far R2 Detector

The cutoff distance is fixed. Backgrounds and background objects must always be placed beyond the cutoff distance.

Fixed-Field Sensing – Theory of Operation

The T30FF compares the reflections of its emitted light beam (E) from an object back to the sensor’s two differently aimed detectors, R1 and R2 (see Figure 1). If the near detector (R1) light signal is stronger than the far detector (R2) light signal (see object A, closer than the cutoff distance), the sensor responds to the object. If the far detector (R2) light signal is stronger than the near detector (R1) light signal (see object B, beyond the cutoff distance), the sensor ignores the object.

Emitter

E Sensing Range Object is sensed if amount of light at R1 is greater than the amount of light at R2

Figure 1. Fixed-field concept

The cutoff distance for model T30FF NAMUR sensors is fixed at 150 millimeters (6"). Objects lying beyond the cutoff distance are usually ignored, even if they are highly reflective. However, it is possible to falsely detect a background object, under certain conditions (see Background Reflectivity and Placement). In the drawings and discussion on these pages, the letters E, R1, and R2 identify how the sensor’s three optical elements (Emitter “E”, Near Detector “R1”, and Far Detector “R2”) line up across the face of the sensor. The location of these elements defines the sensing axis (see Figure 2). The sensing axis becomes important in certain situations, such as those illustrated in Figures 5 and 6.

Sensor Setup Sensing Reliability

For highest sensitivity, position the target object for sensing at or near the point of maximum excess gain. The excess gain curve for this product is shown in the models table. Maximum excess gain occurs at a lens-to-object distance of about 40 mm (1.5"). Sensing at or near this distance will make maximum use of each sensor’s available sensing power. The background must be placed beyond the cutoff distance. (Note that the reflectivity of the background surface also may affect the cutoff distance.) Following these two guidelines will improve sensing reliability.

R1 R2

Sensing Axis

E

Background Reflectivity and Placement

Avoid mirror-like backgrounds that produce specular reflections. False sensor response will occur if a background surface reflects the sensor’s light more strongly to the near detector, or “sensing” detector (R1), than to the far detector, or “cutoff” detector (R2). The result is a false ON condition (Figure 3). To cure this problem, use a diffusely reflective (matte) background, or angle either the sensor or the background (in any plane) so the background does not reflect light back to the sensor (see Figure 4). Position the background as far beyond the cutoff distance as possible.

As a general rule, the most reliable sensing of an object approaching from the side occurs when the line of approach is parallel to the sensing axis.

Figure 2. Fixed-field sensing axis

An object beyond the cutoff distance, either stationary (and when positioned as shown in Figure 5), or moving past the face of the sensor in a direction perpendicular to the sensing axis, can cause unwanted triggering of the sensor if more light is reflected to the near detector than to the far detector. The problem is easily remedied by rotating the sensor 90° (Figure 6). The object then reflects the R1 and R2 fields equally, resulting in no false triggering. A better solution, if possible, may be to reposition the object or the sensor.

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]

T30 Series — NAMUR Fixed-Field Sensors Color Sensitivity

The effects of object reflectivity on cutoff distance, though small, may be important for some applications. It is expected that at any given cutoff setting, the actual cutoff distance for lower reflectance targets will be slightly shorter than for higher reflectance targets (see Figure-of-Merit information on page 1). This behavior is known as color sensitivity. For example, an excess gain of 1 for an object that reflects 1/10 as much light as the 90% white card is represented by the horizontal graph line at excess gain = 10. An object of this reflectivity results in a far limit cutoff of approximately 130 mm (5"), for example; thus 130 mm represents the cutoff for this sensor and target. These excess gain curves were generated using a white test card of 90% reflectance. Objects with reflectivity of less than 90% reflect less light back to the sensor, and thus require proportionately more excess gain in order to be sensed with the same reliability as more reflective objects. When sensing an object of very low reflectivity, it may be especially important to sense it at or near the distance of maximum excess gain.

Cutoff Distance

Cutoff Distance

Reflective Background

R1 = Near Detector R2 = Far Detector E = Emitter T30FF R1 R2 E

T30FF

Strong Direct Reflection to R1

Core of Emitted Beam

Reflective Background

Fixed Sensing Field

R1 R2 E

Fixed Sensing Field

Core of Emitted Beam

Strong Direct Reflection Away From Sensor

R1 = Near Detector R2 = Far Detector E = Emitter

Figure 3. Reflective background – problem

Cutoff Distance

Cutoff Distance

T30FF

Figure 4. Reflective background – solution

T30FF

R1 R2

E, R2, R1

E

Fixed Sensing Field R1 = Near Detector R2 = Far Detector E = Emitter

Fixed Sensing Field Reflective Background or Moving Object

A reflective background object in this position or moving across the sensor face in this axis and direction may cause false sensor response.

Figure 5. Object beyond cutoff – problem

E = Emitter R2 = Far Detector R1 = Near Detector

Reflective Background or Moving Object

A reflective background object in this position or moving across the sensor face in this axis will be ignored.

Figure 6. Object beyond cutoff – solution

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]

T30 Series — NAMUR Fixed-Field Sensors Specifications Supply Voltage and Current

5 to 15V dc (provided by the amplifier to which the sensor is connected)

Output

Constant current output; ≤1.2 mA in the “dark” condition and ≥2.1 mA in the “light” condition

Output Response Time

10 ms on/off (does not include amplifier response)

Sensing Beam

Infrared (880 nm)

Cutoff Distance

150 mm (6"), referenced to a 90% reflectance white test card. See excess gain curve.

Indicators

Red indicator LED on rear panel lights when the sensor sees a “light” condition.

Construction

Yellow PBT enclosure, PBT rear cover. Acrylic lens. M30xl,5 threaded lens housing with two mounting nuts supplied. Meets NEMA standards 1, 2, 3, 3S, 4, 4X, 6, 6P, 12, and 13. IEC IP67.

Connections

2 m (6.5') attached PVC covered cable or 4-pin Euro-style quick-disconnect (QD) fitting, depending on model. QD cable must be purchased separately; see page 5.

Operating Conditions

Temperature: -40° to +70° C (-40° to +158° F)

Vibration and Mechanical Shock

Meets Mil. Std. 202F requirements. Method 201A (Vibration: frequency 10 to 60 Hz max., double amplitude 0.06-inch, maximum acceleration 10G). Method 213B conditions H & I (Shock: 75G with unit operating; 100G for non-operation).

Design Standards

T30AD9 sensors comply with the following standards: DIN 19 234 NAMUR, EN 50 014 Part L 1977, EN 50 020 Part 7. 1977, Factory Mutual Research 3610, Factory Mutual Research 3611, CSA-22.2 No. 157-92 NOTE: If sensors with output characteristics according to DIN 19 234 (e.g., T30AD9 Series NAMUR sensors) are used in hazardous areas, they must be used with approved switching amplifers with intrinsically safe input circuits.

Certifications

Approvals KEMA:

EN50014, EN50020 DIN 19234 NAMUR II 1 G EEx ia IIC T6 KEMA No. EX95.C.3442 Ta -40 C° .. 70 C° 03ATEX1441X

Dimensions ø 40.0 mm (1.57")

Cabled Models

QD Models

Jam Nut (Supplied) M30 x 1.5 Thread

ø 15 mm (0.59")

45.0 mm (1.77") Red LED Alignment Indicator 51.5 mm (2.03") 11.5 mm (0.45")

66.5 mm (2.62")

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]

T30 Series — NAMUR Fixed-Field Sensors Hookups Cabled Models Hazardous Area

Entity Parameters

Non-hazardous Area

NAMUR Sensor

Associated Apparatus 1

br

2

bu

3

+

+ Sensor Power – Input

–

≤ 15V dc

4 Output

Quick-Disconnect Models Hazardous Area NAMUR Sensor

bu

Voc ≤ 15V dc Isc ≤ 35 mA Ca ≥ *C (cable) + Ci La ≥ *L (cable) + Li

Vmax = 15V dc Imax = 35 mA Ci = 0 Li = 0 Pi = 131

*C(cable) = 60 pF/ft

*L(cable) = 0.2 uH/ft

Associated apparatus may include amplifiers and barriers to monitor apparatus supply current which is the apparatus output signal. Associated apparatus must limit both supply voltage and supply current in the event of failures.

Non-hazardous Area

Power + Sensor – Input

Sensor Apparatus

HAZARDOUS AREA APPLICATION:

Associated Apparatus

br

Associated Apparatus

+ –

≤ 15V dc

Output

Quick-Disconnect (QD) Cables Style 4-pin Euro-style Straight

Model

Length

MQD9-406 MQD9-415

2 m (6.5') 5 m (15')

Dimensions

Pinout ø 15 mm (0.6")

44 mm max. (1.7")

M12 x 1

Blue Wire Brown Wire

38 mm max. (1.5")

4-pin Euro-style Right-angle

MQD9-406RA MQD9-415RA

2 m (6.5') 5 m (15')

38 mm max. (1.5")

M12 x 1 ø 15 mm (0.6")

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]

T30 Series — NAMUR Fixed-Field Sensors Mounting Brackets T30 Series sensors may also be mounted in a 30 mm clearance hole up to 15 mm (0.6") deep, using the supplied jam nut(s). • 30 mm 12-gauge, 304 stainless steel, right-angle mounting bracket with a curved mounting slot for versatility and orientation

SMB30A

• 30 mm swivel bracket • Black reinforced thermoplastic polyester

SMB30SC

• Includes stainless steel mounting and swivel locking hardware

• Clearance for M6 (1/4") hardware

38.5 mm (1.52")

45 mm (1.8")

61 mm (2.40")

30

R 40 mm (1.58")

ø 6.3 mm (0.25")*

69 mm (2.70") 6.3 mm (0.25")*

7.6 mm (0.30")

ø 30.5 mm (1.20")

Clearance for M6 (1/4") mounting hardware (not included) 50.8 mm (2.00")

M30 x 1.5 internal thread

12.7 mm (0.50")

58.7 mm (2.31") 30.0 mm (1.18")

* Use 5 mm (#10) screws to mount bracket. Drill screw holes 40.0 mm (1.58") apart. 66.5 mm (2.62")

29.0 mm (1.14")

SMB3OA BRACKET

WARRANTY:  Banner Engineering Corp. warrants its products to be free from defects for one year. Banner Engineering Corp. will repair or replace, free of charge, any product of its manufacture found to be defective at the time it is returned to the factory during the warranty period. This warranty does not cover damage or liability for the improper application of Banner products. This warranty is in lieu of any other warranty either expressed or implied. P/N 41685 rev. A

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]

T30 Sensors – ac-Voltage Series Self-contained ac-operated sensors

Features • F eaturing EZ-BEAM® technology, the specially designed optics and electronics provide reliable sensing without the need for adjustments • “ T”-style plastic housing with 30 mm threaded lens in opposed, retroreflective or fixed-field modes • C  ompletely epoxy-encapsulated to provide superior durability, even in harsh sensing environments rated to IP69K • Innovative dual-indicator system takes the guesswork out of sensor performance monitoring • 20 to 250V ac (3-wire hookup); SPST solid-state switch output, maximum load 300 mA

Models Sensing Mode

Range

LED

Output –

Opposed

Polarized Retroreflective

60 m (200')

6 m (20')

Infrared 950 nm

Visible Red 680 nm

200 mm (8") cutoff

Fixed-Field

400 mm (16") cutoff

600 mm (24") cutoff

Infrared 880 nm

Model* T303E

LO

T30AW3R

DO

T30RW3R

LO

T30AW3LP

DO

T30RW3LP

LO

T30AW3FF200

DO

T30RW3FF200

LO

T30AW3FF400

DO

T30RW3FF400

LO

T30AW3FF600

DO

T30RW3FF600

* Standard 2 m (6.5') cable models are listed. • For 9 m (30') cable: add suffix “W/30” (e.g., T303E W/30). • For 4-pin Micro-style integral QD: add suffix “Q1” (e.g., T303EQ1). A model with a QD connector requires a mating cable; see page 7.

WARNING . . . Not To Be Used for Personnel Protection Never use these products as sensing devices for personnel protection. Doing so could lead to serious injury or death. These sensors do NOT include the self-checking redundant circuitry necessary to allow their use in personnel safety applications. A sensor failure or malfunction can cause either an energized or de-energized sensor output condition. Consult your current Banner Safety Products catalog for safety products which meet OSHA, ANSI and IEC standards for personnel protection.

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]



T30 Sensors – ac-Voltage Series Fixed-Field Mode Overview

T30 Series self-contained fixed-field sensors are small, powerful, infrared diffuse mode sensors with far-limit cutoff (a type of background suppression). Their high excess gain and fixed-field technology allow them to detect objects of low reflectivity, while ignoring background surfaces. The cutoff distance is fixed. Backgrounds and background objects must always be placed beyond the cutoff distance.

Fixed-Field Sensing – Theory of Operation

The T30FF compares the reflections of its emitted light beam (E) from an object back to the sensor’s two differently aimed detectors, R1 and R2 (see Figure 1). If the near detector (R1) light signal is stronger than the far detector (R2) light signal (see object A, closer than the cutoff distance), the sensor responds to the object. If the far detector (R2) light signal is stronger than the near detector (R1) light signal (see object B, object beyond the cutoff distance), the sensor ignores the object. The cutoff distance for model T30FF sensors is fixed at 200, 400 or 600 millimeters (8", 16", or 24"). Objects lying beyond the cutoff distance are usually ignored, even if they are highly reflective. However, it is possible to falsely detect a background object, under certain conditions (see Background Reflectivity and Placement). In the drawings and discussion on these pages, the letters E, R1, and R2 identify how the sensor’s three optical elements (Emitter “E”, Near Detector “R1”, and Far Detector “R2”) line up across the face of the sensor. The location of these elements defines the sensing axis (see Figure 2). The sensing axis becomes important in certain situations, such as those illustrated in Figures 5 and 6.

Receiver Elements Near R1 Detector

Cutoff Distance Object B or Background

Object A Lenses

Far R2 Detector

Emitter

E Sensing Range Object is sensed if amount of light at R1 is greater than the amount of light at R2

Figure 1. Fixed-field concept

Sensor Setup Sensing Reliability

For highest sensitivity, position the target object for sensing at or near the point of maximum excess gain. The excess gain curves for these sensors are shown on page 5. Maximum excess gain for all models occurs at a lens-to-object distance of about 40 mm (1.5"). Sensing at or near this distance will make maximum use of each sensor’s available sensing power. The background must be placed beyond the cutoff distance. (Note that the reflectivity of the background surface also may affect the cutoff distance.) Following these two guidelines will improve sensing reliability.

R1 R2

Sensing Axis

E

Background Reflectivity and Placement

Avoid mirror-like backgrounds that produce specular reflections. False sensor response will occur if a background surface reflects the sensor’s light more strongly to the near detector, or “sensing” detector (R1), than to the far detector, or “cutoff” detector (R2). The result is a false ON condition (Figure 3). To cure this problem, use a diffusely reflective (matte) background, or angle either the sensor or the background (in any plane) so the background does not reflect light back to the sensor (see Figure 4). Position the background as far beyond the cutoff distance as possible. An object beyond the cutoff distance, either stationary (and when positioned as shown in Figure 5), or moving past the face of the sensor in a direction perpendicular to the sensing axis, can cause unwanted triggering of the sensor if more light is reflected to the near detector than to the far detector. The problem is easily remedied by rotating the sensor 90° (Figure 6). The object then reflects the R1 and R2 fields equally, resulting in no false triggering. A better solution, if possible, may be to reposition the object or the sensor.

As a general rule, the most reliable sensing of an object approaching from the side occurs when the line of approach is parallel to the sensing axis.

Figure 2. Fixed-field sensing axis

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]

T30 Sensors – ac-Voltage Series Color Sensitivity

The effects of object reflectivity on cutoff distance, though small, may be important for some applications. It is expected that at any given cutoff setting, the actual cutoff distance for lower reflectance targets will be slightly shorter than for higher reflectance targets (see Figure-of-Merit information on page 5). This behavior is known as color sensitivity. For example, an excess gain of 1 (see page 5) for an object that reflects 1/10 as much light as the 90% white card is represented by the horizontal graph line at excess gain = 10. An object of this reflectivity results in a far limit cutoff of approximately 190 mm (7.5") for the 200 mm (8") cutoff model, for example; thus 190 mm represents the cutoff for this sensor and target. These excess gain curves were generated using a white test card of 90% reflectance. Objects with reflectivity of less than 90% reflect less light back to the sensor, and thus require proportionately more excess gain in order to be sensed with the same reliability as more reflective objects. When sensing an object of very low reflectivity, it may be especially important to sense it at or near the distance of maximum excess gain.

Cutoff Distance

Cutoff Distance

Reflective Background

R1 = Near Detector R2 = Far Detector E = Emitter T30FF R1 R2 E

T30FF

Strong Direct Reflection to R1

Core of Emitted Beam

Reflective Background

Fixed Sensing Field

R1 R2 E

Fixed Sensing Field

Core of Emitted Beam

Strong Direct Reflection Away From Sensor

R1 = Near Detector R2 = Far Detector E = Emitter

Figure 3. Reflective background – problem

Figure 4. Reflective background – solution Cutoff Distance

Cutoff Distance

T30FF

T30FF R1 R2

E, R2, R1

E

Fixed Sensing Field R1 = Near Detector R2 = Far Detector E = Emitter

Reflective Background or Moving Object

Fixed Sensing Field E = Emitter R2 = Far Detector R1 = Near Detector

Reflective Background or Moving Object

A reflective background object in this position or moving across the sensor face in this axis and direction may cause false sensor response.

A reflective background object in this position or moving across the sensor face in this axis will be ignored.

Figure 5. Object beyond cutoff – problem

Figure 6. Object beyond cutoff – solution

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]



T30 Sensors – ac-Voltage Series Specifications Supply Voltage and Current

20 to 250V ac (50/60 Hz) Average current: 20 mA Peak current: 200 mA @ 20V ac, 500 mA @ 120V ac, 750 mA @ 250V ac

Supply Protection Circuitry

Protected against transient voltages

Output Configuration

SPST solid-state ac switch; three-wire hookup; light operate or dark operate, depending on model Light Operate: Output conducts when sensor sees its own (or the emitter’s) modulated light Dark Operate: Output conducts when the sensor sees dark

Output Rating

3 00 mA maximum (continuous) Fixed-Field models: derate 5 mA/°C above +50° C (+122° F) Inrush capability: 1 amp for 20 milliseconds, non-repetitive OFF-state leakage current: < 100 microamps ON-state saturation voltage: 3V @ 300 mA ac; 2V @ 15 mA ac

Output Protection Circuitry

Protected against false pulse on power-up

Output Response Time

Opposed mode: 16 milliseconds ON, 8 milliseconds OFF Other models: 16 milliseconds ON and OFF NOTE: 100 millisecond delay on power-up; outputs do not conduct during this time.

Repeatability

Opposed mode: 2 milliseconds Other models: 4 milliseconds Repeatability and response are independent of signal strength.

Indicators

Two LEDs (Green and Yellow) Green ON steady: power to sensor is ON Yellow ON steady: sensor sees light Yellow flashing: excess gain marginal (1 to 1.5x) in light condition

Construction

PBT polyester housing; polycarbonate (opposed-mode) or acrylic lens

Environmental Rating

Leakproof design rated NEMA 6P, DIN 40050 (IP69K)

Connections

2 m (6.5') attached cable, or 4-pin Micro-style quick-disconnect fitting

Operating Conditions

Temperature: -40° to +70° C (-40° to +158° F) Maximum relative humidity: 90% at 50° C (non-condensing)

Vibration and Mechanical Shock

All models meet Mil. Std. 202F requirements. Method 201A (Vibration; frequency 10 to 60 Hz, max., double amplitude 0.06" acceleration 10G). Method 213B conditions H&I (Shock: 75G with unit operating; 100G for non-operation)

Certifications

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]

T30 Sensors – ac-Voltage Series Performance Curves

Opposed Mode

100

Opposed Mode

500 mm

20"

250 mm

10"

0

G A I N

E X C E S S G A I N

0 10"

500 mm

20"

750 mm

30" 0

1m (3.3')

10 m (33')

DISTANCE

1000

Polarized Retro††

30"

250 mm

10

1 0.1 m (0.33')

††

T30 Series

750 mm

100 m (330')

45 m (150')

60 m (200')

75 m (250')

T30 Series

150 mm

6"

Polarized Retro

100 mm

Polarized Retro

30 m (100')

DISTANCE

T30 Series

100

15 m (50')

4"

50 mm

2"

0

with BRT-3 Reflector 10

0

with BRT-3 Reflector

50 mm

2"

100 mm

4"

150 mm 1 0.01 m (0.033')

6" 0

0.1 m (0.33')

1m (3.3')

DISTANCE

10 m (33')

1.5 m (5')

3.0 m (10')

4.5 m (15')

6.0 m (20')

7.5 m (25')

DISTANCE

Performance based on use of a model BRT-3 retroreflector (3" diameter). Actual sensing range may be more or less than specified, depending on the efficiency and reflective area of the retroreflector used.

Fixed-Field – 200 mm

T30 Series

Performance based on use of a 90% reflectance white test card.†

Fixed-Field – 400 mm

Opposed

1000

E X C E S S

Excess Gain

Beam Pattern

Fixed-Field – 600 mm

Excess Gain

1000

E X C E S S

T30 Series

Ø 16 mm spot size @ 35 mm focus Ø 20 mm spot size @ 200 mm cutoff

100 Fixed-field mode with 200 mm far limit cutoff

G A I N

†Using

18% gray test card: cutoff distance will be 95% of value shown. †Using 6% black test card: cutoff distance will be 90% of value shown.

10

1 1 mm (0.04")

10 mm (0.4")

1000

E X C E S S

100 mm (4")

DISTANCE

1000 mm (40")

T30 Series

Ø 17 mm spot size @ 35 mm focus Ø 25 mm spot size @ 400 mm cutoff

100 Fixed-field mode with 400 mm far limit cutoff

G A I N

†Using

18% gray test card: cutoff distance will be 90% of value shown. †Using 6% black test card: cutoff distance will be 85% of value shown.

10

1 1 mm (0.04")

10 mm (0.4")

1000

E X C E S S G A I N

100 mm (4")

DISTANCE

1000 mm (40")

T30 Series

Ø 17 mm spot size @ 35 mm focus Ø 30 mm spot size @ 600 mm cutoff

100 Fixed-field mode with 600 mm far limit cutoff

†Using

18% gray test card: cutoff distance will be 85% of value shown. †Using 6% black test card: cutoff distance will be 75% of value shown.

10

1 1 mm (0.04")

10 mm (0.4")

100 mm (4")

DISTANCE

1000 mm (40")

Focus and spot sizes are typical.

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]



T30 Sensors – ac-Voltage Series Dimensions QD Models

Cabled Models ø 40.0 mm (1.57") Jam Nut (Supplied) M30 x 1.5 Thread 45.0 mm (1.77")

ø 15 mm (0.59")

Green LED Power Indicator 51.5 mm (2.03")

Yellow LED Output Indicator 66.5 mm (2.62")

11.5 mm (0.45")

Hookups Cabled Emitters

QD Emitters (4-pin Micro-Style) rd/bk

bn

rd/wh 20-250V ac

bu

No connection

gn

All Other Cabled Models

All Other QD Models (4-pin Micro-Style) rd/bk

bn 20-250V ac

bu bk

20-250V ac

rd

Load

rd/wh rd gn

20-250V ac

Load

No Connection

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]

T30 Sensors – ac-Voltage Series



Quick-Disconnect (QD) Cables Style 4-pin Micro-style Straight

Model MQAC-406 MQAC-415 MQAC-430

Length 2 m (6.5') 5 m (15') 9 m (30')

Dimensions

Pinout ø15 mm (0.6")

44 mm max. (1.7")

ø 1/2-20UNF-2B

38 mm max. (1.5")

4-pin Micro-style Right-angle

MQAC-406RA MQAC-415RA MQAC-430RA

2 m (6.5') 5 m (15') 9 m (30')

Green Wire Red Wire Red/White Wire

Red/Black Wire

38 mm max. (1.5")

1/2-20UNF-2B ø 15 mm (0.6")

WARRANTY:  Banner Engineering Corp. warrants its products to be free from defects for one year. Banner Engineering Corp. will repair or replace, free of charge, any product of its manufacture found to be defective at the time it is returned to the factory during the warranty period. This warranty does not cover damage or liability for the improper application of Banner products. This warranty is in lieu of any other warranty either expressed or implied. P/N 121523

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]

EZ-BEAM® "S2" Series Sensors Designed for use on Sensor BUS Networks

Description

Features • Low cost and easy to use; no adjustments are necessary • Sensor selection is simply a matter of choosing a housing style and sensing mode • Models available for opposed (through-beam), polarized retroreflective, and fixed-field diffuse modes • Advanced self-diagnostics with separate alarm output; dual LED system indicates sensor performance • Solid-state outputs for direct connection to a BUS system network junction such as a Banner BUS DEPOT® • 4-pin quick disconnect connector for standard euro-style extension cables • Epoxy-encapsulated circuitry; leakproof IP67 (NEMA 6P) rating for harsh sensing environments • Brackets available for several mounting options

"S2" Series EZ-BEAM sensors are designed to connect directly to a "smart" BUS system network junction, such as the Banner BUS-DEPOT®. S2 Series sensors are internally wired to take advantage of the EZ-BEAM's marginal signal ALARM output. The ALARM output is normally open (N.O.) and conducts whenever the sensor's excess gain drops to between 1X and 1.5X in the light condition. The sensing signal output is also normally open, which means that the output conducts when light is sensed (i.e. - light operate). In order to take advantage of the second ALARM output, S2 sensors require the use of BUS DEPOT junctions which offer two channels per input. Both sensor outputs are PNP (current sourcing) for direct connection to a BUS network junction using standard 4-pin euro-style extension cables. S2 Series sensors offer all of the features and powerful sensing performance that EZBEAMs offer. The innovative dual-indicator system takes the guesswork out of sensor performance monitoring. Housings are tightly sealed and the sensor circuitry is epoxy-encapsulated for reliable duty in wet or oily sensing environments. Models are available for opposed (through-beam), polarized retroreflective and fixed-field diffuse sensing (see chart on page 2, for available ranges). As the chart on page 2 shows, there are three basic housing styles. The "S" style is a threaded barrel which is available in 18 mm or 30 mm diameters. The "Q" style offers either 25 mm or 40 mm right-angle rectangular housings. Finally, the "T" style is a patented† right-angle design available with either an 18 mm or 30 mm threaded lens. The "T" style combines the mounting ease of a barrel sensor with the low-profile advantage of a right-angle design. Several mounting options are offered, including angled brackets and split-clamp brackets. S2 series sensors may also be simply mounted through suitable clearance holes. See page 7 for more information. †

U.S. Patent #5087838

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]

S2 Series Available Sensing Modes and Ranges Family

Sensor Package

Opposed

Retro

18 mm barrel

20 m (60 ft)

2 m (79 in)

Fixed-field

S18 50 mm (2 in) 100 mm (4 in)

S30 200 mm (8 in) 30 mm barrel

60 m (200 ft)

6 m (20 ft) 400 mm (16 in)

Q25 50 mm (2 in) 25 mm rectangular

20 m (60 ft)

2 m (79 in) 100 mm (4 in)

Q40 200 mm (8 in) 40 mm rectangular

60 m (200 ft)

6 m (20 ft) 400 mm (16 in)

T18 50 mm (2 in) 18 mm right-angle

20 m (60 ft)

2 m (79 in) 100 mm (4 in)

T30 200 mm (8 in) 30 mm right-angle

60 m (200 ft)

6 m (20 ft) 400 mm (16 in)

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]

S2 Series Opposed Mode Emitter (E) and Receiver (R) Models

Range

Cable

Supply Voltage

Output Type

S186EQ S18S2P6RQ Q256EQ Q25S2P6RQ

Excess Gain

Effective Beam: 13 mm (0.5")

1000

20 m (66 ft)

4-pin Euro QD

10-30V dc

PNP

E X C E S S G A I N

S18, Q25 and T18 Series

S18, Q25 and T18 Series

1500 mm

60 in

Opposed Mode

Opposed Mode

100

1000 mm

40 in

500 mm

20 in

0 10

0

500 mm

20 in

1000 mm

40 in

1500 mm 1 .1 m .33 ft

T186EQ T18S2P6RQ

60 in 0

1m 3.3 ft

10 m 33 ft

100 m 330 ft

5m 16 ft

10 m 32 ft

15 m 48 ft

20 m 64 ft

25 m 80 ft

DISTANCE

DISTANCE

Effective Beam: 23 mm (0.9")

S306EQ S30S2P6RQ Q406EQ Q40S2P6RQ

Beam Pattern

1000

60 m (200 ft)

4-pin Euro QD

10-30V dc

PNP

E X C E S S G A I N

T306EQ T30S2P6RQ

100

S30, Q40 and T30 Series

S30, Q40 and T30 Series

750 mm

Opposed Mode

60 in

Opposed Mode

500 mm

40 in

250 mm

20 in

0 10

0

250 mm

20 in

500 mm

40 in

750 mm 1 .1 m .33 ft

1m 3.3 ft

10 m 33 ft

60 in 0

100 m 330 ft

15 m 50 ft

30 m 100 ft

DISTANCE

45 m 150 ft

60 m 200 ft

75 m 250 ft

DISTANCE

Retroreflective Mode Models

Range

Cable

Supply Voltage

Output Type

Beam Pattern

1000

S18S2P6LPQ

Q25S2P6LPQ

Excess Gain

2m (79 in)

4-pin Euro QD

10-30V dc

PNP

S18, Q25 and T18 Series

E X C E S S

S18, Q25 and T18 Series

150 mm

6 in

Polarized Retro 100 mm

Polarized Retro

100

4 in

50 mm

2 in

0 with BRT-3 Reflector

G A I N

10

1 .01 m .033 ft

T18S2P6LPQ

50 mm

2 in

100 mm

4 in

150 mm

6 in 0

.1 m .33 ft

1m 3.3 ft

0

with BRT-3 Reflector

.5 m 1.6 ft

1.0 m 3.2 ft

10 m 33 ft

1.5 m 4.8 ft

2.0 m 6.4 ft

2.5 m 8.0 ft

DISTANCE

DISTANCE

1000

S30S2P6LPQ

Q40S2P6LPQ

6m (20 ft)

T30S2P6LPQ

4-pin Euro QD

10-30V dc

PNP

E X C E S S G A I N

S30, Q40 and T30 Series

6 in

Polarized Retro 100

100 mm

4 in

50 mm

10

1 .01 m .033 ft

2 in

0

with BRT-3 Reflector

1m 3.3 ft

10 m 33 ft

0

with BRT-3 Reflector

50 mm

2 in

100 mm

4 in

150 mm

6 in 0

.1 m .33 ft

DISTANCE

Banner Engineering Corporation Clearwater Tech - Phone:

S30, Q40 and T30 Series

150 mm

Polarized Retro

1.5 m 5 ft

3.0 m 10 ft

4.5 m 15 ft

6.0 m 20 ft

7.5 m 25 ft

DISTANCE

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S2 Series Fixed-field Mode Models

Range

Cable

Supply Voltage

Output Type

Excess Gain Performance based on 90% reflectance white test card

50 mm far limit cutoff

1000

S18, Q25 and T18 Series

E X C E S S

S18S2P6FF50Q

Q25S2P6FF50Q

50 mm (2 in)

4-Pin Euro QD

10-30V dc

PNP

Fixed-field mode with 50 mm far limit cutoff

100

10

G A I N

1 .1 mm .004 in

T18S2P6FF50Q

1 mm .04 in

10 mm .4 in

100 mm 4 in

DISTANCE

100 mm far limit cutoff

1000

S18, Q25 and T18 Series

E X C E S S

S18S2P6FF100Q

Q25S2P6FF100Q

100 mm (4 in)

4-Pin Euro QD

10-30V dc

PNP

Fixed-field mode with 100 mm far limit cutoff

100

G A I N

10

1 .1 mm .004 in

T18S2P6FF100Q

1 mm .04 in

10 mm .4 in

100 mm 4 in

DISTANCE

200 mm far limit cutoff

1000

S30, Q40 and T30 Series

E X C E S S

S30S2P6FF200Q

Q40S2P6FF200Q

200 mm (8 in)

4-Pin Euro QD

10-30V dc

PNP

G A I N

100 Fixed-field mode with 200 mm far limit cutoff 10

1 1 mm .04 in

T30S2P6FF200Q

10 mm .4 in

100 mm 4 in

1000 mm 40 in

DISTANCE

400 mm far limit cutoff

1000

S30, Q40 and T30 Series

E X C E S S

S30S2P6FF400Q

Q40S2P6FF400Q

T30S2P6FF400Q

400 mm (16 in)

4-Pin Euro QD

10-30V dc

PNP

G A I N

100 Fixed-field mode with 400 mm far limit cutoff 10

1 1 mm .04 in

10 mm .4 in

100 mm 4 in

1000 mm 40 in

DISTANCE

Clearwater Tech - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.clrwtr.com - Email: [email protected]

S2 Series Product Specifications Supply Voltage and Current Opposed Mode Emitter Opposed Mode Receiver Polarized Retro Fixed-field

10 to 30V dc (10% maximum ripple); Supply current (exclusive of load current): 25 mA 20 mA 30 mA 35 mA

Supply Protection Circuitry

Protected against reverse polarity and transient voltages

Output Configuration

Sensing Output: PNP (current sourcing), light operated

Alarm Output: PNP (current sourcing), normally open and conducts whenever the sensor's excess gain drops to between 1X and 1.5X in the light condition

Output Rating

150 mA maximum (each); the total load may not exceed 150 mA; Off-state leakage current