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2LM5RM1
SENSORS
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- Manufacturer: BANNER ENGINEERING
- Product type:
- SVHC: No SVHC (15-Jan-2018)
| Delivery and price | |
|---|---|
| Units per pack | 1 |
| Price | 192.49 € |
| Current stock | 10+ |
| Lead time | 30 days |
Datasheet
## MULTI-BEAM Sensors Family **==> picture [464 x 368] intentionally omitted <==** Original Instructions p/n: 32887 Rev. A August 28, 2023 © Banner Engineering Corp. All rights reserved. **Contents.................................................................................................................................. 2** **==> picture [57 x 57] intentionally omitted <==** ## Contents ## **Chapter 1 MULTI-BEAM® Overview** Select the MULTI-BEAM Components ......................................................................................................................................................... 3 Dimensions................................................................................................................................................................................................... 4 Documents for the MULTI-BEAM Series...................................................................................................................................................... 5 ## **Chapter 2 3- and 4-Wire Sensors** Scanner Block Models.................................................................................................................................................................................. 7 Opposed Mode Scanner Block Models ................................................................................................................................................. 7 Retroreflective Scanner Block Models................................................................................................................................................... 8 Diffuse Scanner Block Models............................................................................................................................................................. 10 Convergent Scanner Block Models .................................................................................................................................................... 12 Fiber Optic Scanner Block Models ...................................................................................................................................................... 13 Ambient Light Scanner Block............................................................................................................................................................... 17 MULTI-BEAM 3- and 4-Wire Scanner Block Modifications.................................................................................................................. 18 Power Block Models................................................................................................................................................................................... 19 Power Block (DC) Models.................................................................................................................................................................... 19 Power Block (AC) Models.................................................................................................................................................................... 24 Logic Modules ............................................................................................................................................................................................ 31 Logic Modules (3- and 4-Wire) Models................................................................................................................................................ 31 Logic Module Modifications ................................................................................................................................................................. 33 ## **Chapter 3 2-Wire Sensors** Scanner Blocks........................................................................................................................................................................................... 35 Scanner Block (2-Wire) Models........................................................................................................................................................... 35 Scanner Block (2-Wire) Performance Curves...................................................................................................................................... 37 Scanner Block (2-Wire) Wiring ............................................................................................................................................................ 40 Power Block (2-wire) Models...................................................................................................................................................................... 41 Power Block (2-Wire) Wiring Diagrams ............................................................................................................................................... 41 Power Block (2-Wire) General Wiring.................................................................................................................................................. 43 Logic Modules (2-Wire) .............................................................................................................................................................................. 45 Logic Module (2-Wire) Models............................................................................................................................................................. 45 ## **Chapter 4 Product Support** Accessories and Replacement Parts for the MULTI-BEAM Family............................................................................................................ 47 Banner Engineering Corp Limited Warranty............................................................................................................................................... 49 Contact Us.................................................................................................................................................................................................. 49 2 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** Chapter Contents Select the MULTI-BEAM Components................................................................................................................................................................ 3 Dimensions.......................................................................................................................................................................................................... 4 Documents for the MULTI-BEAM Series............................................................................................................................................................. 5 ## Chapter 1 ## MULTI-BEAM® Overview A Banner MULTI-BEAM® Sensor is a compact modular self-contained photoelectric switch consisting of three components: a scanner block, a power block, and a logic module. The scanner block comprises the housing for the sensor and contains a complete modulated photoelectric amplifier, the emitter and receiver opto-elements and lenses, and space for the other modules. The power block module provides the interface between the scanner block and the external circuit. It contains a power supply for the MULTI-BEAM plus a switching device (except in emitter-only power blocks) to interface the sensor to the circuit to be controlled. The logic module interconnects the power block and scanner block both electrically and mechanically. It provides the desired timing logic function (if any) plus the ability to program the output for either light- or dark-operate. The emitters of MULTI-BEAM opposed mode emitter/receiver pairs do not require a logic module. Emitter scanner blocks are supplied with a blade-pin to interconnect the scanner block and power block. Power block and logic modules are purchased separately. This modular design, with field-replaceable power block and logic modules, permits a large variety of sensor configurations, resulting in exactly the right sensor for any photoelectric application. There are two families of MULTI-BEAM sensors: 3- and 4-wire, and 2-wire. - Three- and four-wire MULTI-BEAMs offer the greatest selection of sensor configurations. They permit either AC or DC operation and offer the fastest response times and the greatest sensing ranges. - Two-wire MULTI-BEAMs are used in AC-powered applications where simplicity and convenience of wiring are important. They are physically and electrically interchangeable with heavy-duty limit switches. The circuitry of all MULTI-BEAM components is encapsulated within rugged, corrosion-resistant PBT housings, which meet or exceed NEMA 1, 3, 12, and 13 ratings. Most MULTI-BEAM scanner blocks include Banner's patented Alignment Indicating Device (AID™), which lights a topmounted LED when the sensor sees its own modulated light source and pulses the LED at a rate proportional to the received light signal. Most MULTI-BEAM sensor assemblies are UL listed and certified by CSA (see power block listings). All MULTIBEAM components (except power block models 2PBR and 2PBR2) are solid-state for unlimited life. ## Select the MULTI-BEAM Components MULTI-BEAM sensors are made up of three components: scanner block, power block, and logic module. This is true for all MULTI-BEAMs with the exception of opposed mode emitter units which require only a power block (no logic module). **==> picture [32 x 78] intentionally omitted <==** ## **WARNING:** - **Do not use this device for personnel protection** - Using this device for personnel protection could result in serious injury or death. - This device does not include the self-checking redundant circuitry necessary to allow its use in personnel safety applications. A device failure or malfunction can cause either an energized (on) or de-energized (off) output condition. If you have any questions about selecting MULTI-BEAM components, please contact your Banner sales engineer or Banner's applications department. August 28, 2023 © Banner Engineering Corp. All rights reserved. 3 MULTI-BEAM Sensors Family **==> picture [115 x 139] intentionally omitted <==** **----- Start of picture text -----**<br> Logic module<br>d<br>Q<br>AS<P,4<br>J PG<br>NSO® ay] Sieeg<br>Power block<br>**----- End of picture text -----**<br> 1. Determine which family of MULTI-BEAM sensors is appropriate for your application: 3- and 4-wire or 2-wire. 2. Decide which scanner block (within the selected family) is best for the application. The guidelines in the catalog introduction will help you to determine the best sensing mode. Then narrow the choice by comparing the specifications listed in the following charts and on the pages referenced in the charts. - Choose a power block and logic module to complete the MULTI-BEAM assembly. 3. Choose a power block and logic module to complete the MULTI-BEAM assembly. Components snap together without interwiring to form a complete photoelectric sensing system that meets your exact requirements while maintaining the simplicity of a self-contained sensor. Other MULTI-BEAM products include the Edgeguide System (datasheet p/n 03506) and the Optical Data Transmitter (datasheet p/n 03321). ## Dimensions All measurements are listed in millimeters [inches], unless noted otherwise. August 28, 2023 © Banner Engineering Corp. All rights reserved. 4 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** **==> picture [280 x 280] intentionally omitted <==** **----- Start of picture text -----**<br> Status Indicator LED<br>(except emitters)<br>Access to<br>Sensitivity Adjustment<br>40 mm<br>[1.6"]<br>53 mm [2.1"]<br>Lens Centerline<br>114 mm<br>[4.5"] 94 mm<br>[3.7"]<br>60.0 mm<br>[2.36"]<br>7.6 mm<br>[0.30"]<br>5.1 mm<br>1/2" – 14 NPSM [0.20"]<br>Conduit Entrance<br>5 mm (#10) Screw 30.0 mm<br>Clearance (4) [1.18"]<br>**----- End of picture text -----**<br> ## Documents for the MULTI-BEAM Series ## Scanner Blocks - MULTI-BEAM Series 3-Wire and 4-Wire Scanner Blocks (Opposed), p/n 03492 - MULTI-BEAM Series 3-Wire and 4-Wire Scanner Blocks (Diffuse), p/n 03495 - MULTI-BEAM Series 3-Wire and 4-Wire Scanner Blocks (Convergent), p/n 03494 - MULTI-BEAM Series 3-Wire and 4-Wire Scanner Blocks (Retroreflective), p/n 03493 - MULTI-BEAM Series 3-Wire and 4-Wire Scanner Blocks (Glass Fiber Optic), p/n 03496 - MULTI-BEAM Series 2-Wire Scanner Blocks, p/n 03498 - MULTI-BEAM Series Ambient Light Scanner Blocks, p/n 03497 ## Power Blocks - MULTI-BEAM Series 3-Wire and 4-Wire AC Power Blocks, p/n 03501 - MULTI-BEAM Series 3-Wire and 4-Wire DC Power Blocks, p/n 03499 - MULTI-BEAM Series 2-Wire AC Power Blocks, p/n 03508 ## Logic Modules - MULTI-BEAM Series 3-Wire and 4-Wire Logic Modules, p/n 03304 - MULTI-BEAM Series 2-Wire Logic Modules, p/n 03507 ## Other - MULTI-BEAM Series Optical Edgeguide System, p/n 03506 - MULTI-BEAM Series Optical Data Transmitter System, p/n 03321 August 28, 2023 © Banner Engineering Corp. All rights reserved. 5 **==> picture [57 x 57] intentionally omitted <==** ## _Blank page_ 6 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** Chapter Contents Scanner Block Models......................................................................................................................................................................................... 7 Power Block Models.......................................................................................................................................................................................... 19 Logic Modules ................................................................................................................................................................................................... 31 ## Chapter 2 ## 3- and 4-Wire Sensors Three- and four-wire MULTI-BEAMs offer the greatest selection of sensor configurations. They permit either AC or DC operation and offer the fastest response times and the greatest sensing ranges. ## Scanner Block Models ## Opposed Mode Scanner Block Models Opposed mode MULTI-BEAMs consist of an emitter and receiver, which are sold separately. They provide the highest excess gain and the longest sensing range of all sensing models, and are recommended for use whenever possible. **==> picture [53 x 33] intentionally omitted <==** **OPPOSED** Sensing takes place when an object breaks the light beam. Both infrared and visible red types are available. All models have Banner's exclusive AID™ alignment system. SBE/SBR1 . This opposed pair has the highest gain available at 1-millisecond response. **==> picture [500 x 47] intentionally omitted <==** **----- Start of picture text -----**<br> Models Range Performance Beam<br>SBE Emitter<br>Response Time: 1 ms<br>45 m (150 ft) Infrared, 940 nm (Beam diameter of 1 inch)<br>SBR1 Receiver Repeatability: 0.03 ms<br>**----- End of picture text -----**<br> SBED/SBRD1 . With a fast response and small effective beam, this pair will detect objects as small as 1/4-inch in crosssection and moving at up to 10 feet per second. This is the best choice for repeatability of position sensing. **==> picture [500 x 47] intentionally omitted <==** **----- Start of picture text -----**<br> Models Range Performance Beam<br>SBED Emitter<br>Response Time: 1 ms<br>3 m (10 ft) Infrared, 880 nm (Beam diameter of 0.12 inch)<br>SBRD1 Receiver Repeatability: 0.03 ms<br>**----- End of picture text -----**<br> SBEX/SBRX1 . This pair is the best choice for opposed sensing in extremely dirty environments. Use these models for outdoor applications and all applications requiring an opposed range of 100 feet or more. You may also use these models side-by-side for long-distance mechanical convergence sensing. Alignment is difficult beyond 400 feet. **==> picture [500 x 47] intentionally omitted <==** **----- Start of picture text -----**<br> Models Range Performance Beam<br>SBEX Emitter<br>Response Time: 10 ms<br>200 m (700 ft) Infrared, 940 nm (Beam diameter of 1 inch)<br>SBRX1 Receiver Repeatability: 0.7 ms<br>**----- End of picture text -----**<br> SBEV/SBRX1 . SBEV has a visible red beam for easiest alignment and system monitoring. **==> picture [500 x 47] intentionally omitted <==** **----- Start of picture text -----**<br> Models Range Performance Beam<br>SBEV Emitter<br>Response Time: 10 ms<br>30 m (100 ft) Visible Red, 650 nm (Beam diameter of 1 inch)<br>SBRX1 Receiver Repeatability: 0.1 ms<br>**----- End of picture text -----**<br> SBEXD/SBRXD1 . A wide beam angle and high gain for the most forgiving emitter-receiver alignment. August 28, 2023 © Banner Engineering Corp. All rights reserved. 7 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** **==> picture [500 x 47] intentionally omitted <==** **----- Start of picture text -----**<br> Models Range Performance Beam<br>SBEXD Emitter<br>Response Time: 10 ms<br>9 m (30 ft) Infrared, 880 nm (Beam diameter of 0.12 inch)<br>SBRXD1 Receiver Repeatability: 0.7 ms<br>**----- End of picture text -----**<br> ## Scanner Block Performance Curves (Opposed Mode) **==> picture [500 x 418] intentionally omitted <==** **----- Start of picture text -----**<br> Excess Gain Beam Pattern Excess Gain Beam Pattern<br>1000 1000<br>SBE / SBR1 SBED / SBRD1<br>1500 mm SBE/SBR1Opposed Mode 60.0 in 300 mm SBED/SBRD1Opposed Mode 12.0 in<br>100 1000 mm 40.0 in 100 200 mm 8.0 in<br>500 mm 20.0 in 100 mm 4.0 in<br>0 0 0 0<br>500 mm 20.0 in 100 mm 4.0 in<br>10 1000 mm 40.0 in 10 200 mm 8.0 in<br>1500 mm 60.0 in 300 mm 12.0 in<br>0 0<br>1 1<br>0.33 m1 ft 3.3 m10 ft 100 ft33 m 1000 ft330 m DISTANCE 0.033 m0.1 ft 0.33 m1 ft 3.3 m10 ft 100 ft33 m DISTANCE<br>Distance Distance<br>1000 1000<br>SBEX / SBRX1 SBEV / SBRX1<br>1500 mm SBEX/SBRX1 60.0 in 15” SBEV/SBRX1<br>Opposed Mode<br>100 1000 mm 40.0 in 100 10”<br>500 mm 20.0 in 5”<br>0 0 0”<br>500 mm 20.0 in<br>10 10 5”<br>1000 mm 40.0 in<br>1500 mm 60.0 in 10”<br>15”<br>0<br>1 1<br>0 ft 25 ft 50 ft 75 ft 100 ft 150 ft<br>0.33 m1 ft 3.3 m10 ft 100 ft33 m 1000 ft330 m DISTANCE 0.33 m1 ft 3.3 m10 ft 100 ft33 m 1000 ft330 m DISTANCE<br>Distance Distance<br>1000<br>SBEXD/SBRXD1<br>750 mm SBEXD/SBRXD1 30.0 in<br>Opposed Mode<br>100 500 mm 20.0 in<br>250 mm 10.0 in<br>0 0<br>250 mm 10.0 in<br>10 500 mm 20.0 in<br>750 mm 30.0 in<br>0<br>1<br>0.033 m 0.33 m 3.3 m 33 m DISTANCE<br>0.1 ft 1 ft 10 ft 100 ft<br>Distance<br>Excess Gain Excess Gain<br>Excess Gain Excess Gain<br>Excess Gain<br>**----- End of picture text -----**<br> ## Retroreflective Scanner Block Models **==> picture [53 x 32] intentionally omitted <==** **==> picture [21 x 6] intentionally omitted <==** **----- Start of picture text -----**<br> RETRO<br>**----- End of picture text -----**<br> Retroreflective mode MULTI-BEAMs combine the emitter and receiver into one unit. A retroreflective target is used to return the emitted light to the receiver along the same optical axis. Sensing occurs when an object passes between the sensor and the reflector, interrupting the beam. A variety of retroreflective materials are available, see "Accessories and Replacement Parts for the MULTI-BEAM Family" on page 47. August 28, 2023 © Banner Engineering Corp. All rights reserved. 8 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** **==> picture [500 x 222] intentionally omitted <==** **----- Start of picture text -----**<br> Models Performance Beam Application Notes<br>Range : 0.15 m to 9 m (6 in to 30 ft) A visible red beam makes alignment very easy. SBLV1 is the first<br>choice for most retroreflective applications. Not for use in dirty<br>SBLV1 Response Time : 1 ms on/off Visible Red, 650 nm environments. Instead, use opposed mode, or models SBL1 and<br>SBLX1. Do not locate retroreflector closer than 152 mm (6 in) from<br>Repeatability : 0.3 ms sensor.<br>Range : 0.3 m to 4.5 m (12 in to 15 ft)<br>Uses anti-glare filter for immunity to direct reflections from shiny<br>SBLVAG1 Response Time : 1 ms on/off Visible Red, 650 nm objects. Use only with models BRT-3 or BRT-1.5 retroreflective<br>targets. Use only in clean environments. Do not locate<br>Repeatability : 0.3 ms retroreflector closer than 305 mm (12 in) from sensor.<br>Range : 0.025 m to 9 m (1 in to 30 ft) Use where invisible beam is advantageous (for example, security<br>applications or film processing). First choice for retroreflective<br>SBL1 Response Time : 1 ms on/off Infrared, 940 nm sensing in slightly or moderately dirty environments. Do not use<br>when object to break the beam has a shiny surface, unless the<br>Repeatability : 0.3 ms angle of light to the surface can be predicted.<br>Range : 3 m to 22 m (10 ft to 75 ft) with<br>one BRT-3; 3 m to 30 m (10 ft to 100<br>Highest gain available in a retroreflective sensor. Use for all<br>ft) with three BRT-3 targets<br>SBLX1 Infrared, 880 nm applications requiring more than 9 m (30 ft) range where opposed<br>Response Time : 10 ms on/off mode sensors cannot be used. Objects must pass at a distance of<br>at least 3 m (10 ft) from the sensor to be reliably sensed.<br>Repeatability : 1.5 ms<br>**----- End of picture text -----**<br> ## Scanner Block Performance Curves (Retroreflective) **==> picture [500 x 359] intentionally omitted <==** **----- Start of picture text -----**<br> Excess Gain Beam Pattern<br>1000<br>CEX 100 SBLV1 64 SBLV1<br>ES with BRT-1 1" NI 2<br>S reflector with BRT-3 3"reflector CH 0<br>GA 10 ES 2<br>I 4<br>N with BRT-3 reflector<br>with 6<br>BRT-T<br>tape<br>1 0 ft 6 ft 12 ft 18 ft 24 ft 32 ft<br>.1 FT 1 FT 10 FT 100 FT DISTANCE TO REFLECTOR<br>DISTANCE<br>1000<br>3 SBLVAG1<br>E SBLVAG1<br>X 2<br>C 100 I<br>E N 1<br>SS CH 0<br>E with BRT-3 reflector<br>GAI 10 S 12<br>N 3<br>1 0 ft 3 ft 6 ft 9 ft 12 ft 15 ft<br>.1 FT 1 FT 10 FT 100 FT DISTANCE TO REFLECTOR<br>DISTANCE<br>**----- End of picture text -----**<br> Continued on page 10 August 28, 2023 © Banner Engineering Corp. All rights reserved. 9 MULTI-BEAM Sensors Family Continued from page 9 **==> picture [57 x 57] intentionally omitted <==** **==> picture [500 x 360] intentionally omitted <==** **----- Start of picture text -----**<br> Excess Gain Beam Pattern<br>1000<br>EX SBL1 6 SBL1<br>C 100 4<br>ES with BRT-1 1" with BRT-3 3"reflector NI 2<br>S reflector CH 0 with BRT-3 reflector<br>GA 10 ES 2<br>I 4<br>N with<br>BRT-T 6<br>tape<br>1 0 ft 6 ft 12 ft 18 ft 24 ft 32 ft<br>.1 FT 1 FT 10 FT 100 FT DISTANCE TO REFLECTOR<br>DISTANCE<br>1000<br>SBLX1<br>EX with three BRT-3 3" 3020 SBLX1 with one BRT-3 reflector<br>CES 100 reflectors NI 10<br>S CH 0<br>E<br>G with one S 10<br>AI I 10 BRT-3 3"reflector 20<br>N<br>30<br>0 ft 25 ft 50 ft 75 ft 100 ft 125 ft<br>1<br>1 FT 10 FT 100 FT 1000 FT DISTANCE TO REFLECTOR--FEET<br>DISTANCE<br>**----- End of picture text -----**<br> ## Diffuse Scanner Block Models **==> picture [54 x 32] intentionally omitted <==** **==> picture [25 x 5] intentionally omitted <==** **----- Start of picture text -----**<br> DIFFUSE<br>**----- End of picture text -----**<br> As a general rule regarding background objects in diffuse sensing, verify that the distance to the nearest background object is at least three times the distance from the sensor to the object to be sensed. For example, if a product passes one inch from an SBD1 sensor, the nearest background object should be at least three inches further away. Models Specifications Application Description Range: 30 cm (12 in) The SBD1 model is a short-range diffuse mode sensor with a relatively wide Response: 1 ms on/off field of view. It loses gain rapidly near the end of its range. As a result, its SBD1 Short Range, Fast response to background objects is suppressed. Use caution when applying Repeatability: 0.3 ms Response any diffuse mode sensor if background reflectivity exceeds the reflectivity of the object to be sensed. Beam: infrared, 940 nm Range: 60 cm (24 in) The SBDL1 model has a longer range than SBD1, but with less response to Response: 1 ms on/off SBDL1 Intermediate Range, Fast objects passing the sensor at close range, and greater sensitivity to Repeatability: 0.3 ms Response background objects. Models SBD1 and SBDL1 are identical except for their upper cover (lens) assembly (SBD1 uses UC-D; SBDLl uses UC-L). Beam: infrared, 940 nm Continued on page 11 August 28, 2023 © Banner Engineering Corp. All rights reserved. 10 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** Continued from page 10 Models Specifications Application Description Range: 2 m (6 ft) The SBDX1 model is used for diffuse (proximity) mode applications when Response: 10 ms on/off there is no requirement for less than 10 ms response and where there are no SBDX1 Long Range, for Lowbackground objects to falsely return light. The SBX1 has a high excess gain Repeatability: 1.5 ms Reflectivity Objects for reliable detection of most materials with low reflectivity which pass within 10 in (25 cm) of the sensor. Beam: infrared, 880 nm Range: 60 cm (24 in) The SBDX1MD model has a wide beam angle for forgiving alignment to shiny objects and provides detection of clear or translucent glass or plastics. It has Response: 10 ms on/off SBDX1MD Wide Beam Angle for high excess gain at close range, with fast fall-off of gain near the maximum Repeatability: 1.5 ms Clear Objects sensing distance for optical suppression of reflective background. This model may be created from model SBDX1 by substituting upper cover (lens) model Beam: infrared, 880 nm UC-DMB. The SBDX1MD model has a wide beam angle for forgiving alignment to shiny objects and provides detection of clear or translucent glass or plastics. It has high excess gain at close range, with fast fall-off of gain near the maximum sensing distance for optical suppression of reflective background. This model may be created from model SBDX1 by substituting upper cover (lens) model UC-DMB. Scanner Block Performance Curves (Diffuse) **==> picture [500 x 477] intentionally omitted <==** **----- Start of picture text -----**<br> Excess Gain - SBD1 Beam Pattern - SBD1<br>1000<br>SBD1 0.3<br>E<br>CX 100 (Range based on 90%reflectance white I 0.2 SBD1<br>E test card) N 0.1<br>S C<br>S H 0<br>GA 10 ES 0.1<br>I<br>N 0.2<br>0.3<br>1<br>0.1 IN 1 IN 10 IN 100 IN 0<br>DISTANCE DISTANCE TO 90% WHITE TEST CARD--INCHES<br>Excess Gain - SBDL1 Beam Pattern - SBDL1<br>1000<br>SBDL1 0.75<br>EX (Range based on 90% 0.5<br>CESS 100 reflectance whitetest card) NCHI 0.250 SBDL1<br>E<br>G S 0.25<br>A 10<br>I 0.5<br>N<br>0.75<br>1<br>0.1 IN 1 IN 10 IN 100 IN 0<br>DISTANCE DISTANCE TO 90% WHITE TEST CARD--INCHES<br>Excess Gain - SBDX1 Beam Pattern - SBDX1<br>1000<br>(Range based on 90% 3<br>reflectance white SBDX1<br>EX test card) 2<br>CE 100 SBDX1 NI 1<br>S C<br>S H 0<br>E<br>GA 10 S 1<br>I 2<br>N<br>3<br>1<br>1 IN 10 IN 100 IN 1000 IN 0<br>DISTANCE DISTANCE TO 90% WHITE TEST CARD--INCHES<br>**----- End of picture text -----**<br> Continued on page 12 August 28, 2023 © Banner Engineering Corp. All rights reserved. 11 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** ## Continued from page 11 **==> picture [500 x 160] intentionally omitted <==** **----- Start of picture text -----**<br> Excess Gain - SBDX1MD Beam Pattern - SBDX1MD<br>1000<br>(Range based on 90% 1.5<br>reflectance white SBDX1MD<br>EX test card) 1<br>CE 100 SBDX1MD NI 0.5<br>S C<br>S H 0<br>E<br>GA 10 S 0.5<br>NI 1<br>1.5<br>1<br>1 IN 10 IN 100 IN 1000 IN 0<br>DISTANCE DISTANCE TO 90% WHITE TEST CARD--INCHES<br>**----- End of picture text -----**<br> ## Convergent Scanner Block Models Convergent mode MULTI-BEAM sensors combine the emitter and receiver into one unit. Optics produce a sensing "spot" at a fixed distance (focus point) in front of the lens. **==> picture [53 x 32] intentionally omitted <==** **==> picture [41 x 6] intentionally omitted <==** **----- Start of picture text -----**<br> CONVERGENT<br>**----- End of picture text -----**<br> Convergent mode sensing is an ideal choice for position control of transparent products and for detecting products that are only a fraction of an inch away from another reflective surface. Convergent sensing is also a good second choice (after opposed mode sensing) for precise position control of opaque materials. All models have Banner's exclusive AID™ alignment system. **==> picture [500 x 351] intentionally omitted <==** **----- Start of picture text -----**<br> Models Focus Beam Application Notes<br>1.5 mm (0.06 in) dia, visible red spot, for precise positioning, edge-<br>guiding, and small parts detection. Some products larger than 1<br>inch tall may be sensed against an immediate background, like<br>SBCV1 Focus : 38 mm (1.5 in) 650 nm visible red parts on a conveyor. Excellent for high-contrast, registration-<br>sensing applications (except red on white). Use with LM6-1 logic<br>Repeatability : 0.3 ms module for speed detection sensing of gear teeth, pulley hubs, or<br>chain links.<br>Response Time : 1 ms<br>3 mm (0.12 in) dia, visible green spot. Use to detect color<br>SBCVG1 560 nm visible green differences (for example, color registration marks), including red-<br>on-white combinations.<br>Focus : 38 mm (1.5 in)<br>SBC1 Repeatability : 0.3 ms<br>Response Time: 1 ms<br>Infrared LED light source provides higher gain for reliable sensing<br>Focus : 100 mm (4 in) of products of low reflectivity, while controlling sensing depth of<br>field. Does not offer the same precision possible with visible light<br>SBC1-4 Repeatability : 0.3 ms 940 nm infrared models. Good for sensing clear materials within the sensor's depth<br>of field, and for reliably counting the flow of radiused products that<br>Response Time: 1 ms are kept at a fixed distance from the sensor (for example, bottles<br>against a conveyor guide rail).<br>Focus : 150 mm (6 in)<br>SBC1-6 Repeatability : 0.3 ms<br>Response Time: 1 ms<br>Focus : 38 mm (1.5 in)<br>These models offer the greatest optical gain available in any<br>SBCX1 Repeatability : 1.5 ms reflective mode sensor. They can reliably detect most non-<br>reflective black materials in applications where opposed mode<br>Response Time: 10 ms<br>880 nm infrared sensing is not possible (for example, inked web break monitoring).<br>Focus : 100 mm (4 in) The high power of these models gives them a wide depth of field<br>and a large sensing spot. As a result, they cannot easily ignore<br>SBCX1-4 Repeatability : 1.5 ms objects in the background or foreground, and cannot be used for<br>precise position control (use model SBCV1).<br>Response Time: 10 ms<br>Continued on page 13<br>**----- End of picture text -----**<br> August 28, 2023 © Banner Engineering Corp. All rights reserved. 12 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** **==> picture [500 x 69] intentionally omitted <==** **----- Start of picture text -----**<br> Continued from page 12<br>Models Focus Beam Application Notes<br>Focus : 150 mm (6 in)<br>SBCX1-6 Repeatability : 1.5 ms<br>Response Time : 10 ms<br>**----- End of picture text -----**<br> ## Scanner Block Performance Curves (Convergent) Distances are measured using a 90% white test card. **==> picture [500 x 258] intentionally omitted <==** **----- Start of picture text -----**<br> Excess Gain Beam Pattern Excess Gain Beam Pattern<br>1000 1000<br>(Range based on 90%reflectance white .12” SBCVG1 .12”<br>100 test card) .08”.04” SBCV1 100 (Range based on 90%reflectance white .08”.04” SBCVG1<br>SBCV1 0 test card) 0<br>.04” .04”<br>10<br>.08” 10 .08”<br>.12” .12”<br>10.1 Distance (in) 1 10 100 0 Distance (in) 1.5 10.1 1 10 100 0 Distance (in)<br>Distance (in)<br>1000 1000<br>SBCX1 SBCX1-4<br>(Range based on 90%reflectance white .12” SBCX1-6 .24”<br>100 test card) .08” 100 .16” SBCX1-6<br>.04” .08” SBCX1<br>SBC1 0 0<br>SBCX1-4<br>10 SBC1-4 .04”.08” SBC1 SBC1-4 10 .08”.16”<br>.12” (Range based on .24”<br>10.1 1 SBC1-610 100 0 1.5 Distance (in) 3.0 4.5 6.0 7.5 10.1 90% reflectance white test card) 1 10 100 0 Distance (in)<br>Distance (in) Distance (in)<br>Excess Gain Excess Gain<br>Excess Gain Excess Gain<br>**----- End of picture text -----**<br> ## Fiber Optic Scanner Block Models SBEF and SBRF1 : Use with individual glass fiber optic assemblies in lieu of model SBF1 where it is inconvenient to run fibers from a single scanner block. SBEXF and SBRXF1 : Use in place of model SBFX1 for long-range opposed fiber optic sensing. Or use where high excess gain is required and it is difficult to run the fibers to both sides of the process from a single scanner block. **==> picture [52 x 13] intentionally omitted <==** **----- Start of picture text -----**<br> GLASS FIBER<br>TWO SENSORS<br>**----- End of picture text -----**<br> **==> picture [500 x 77] intentionally omitted <==** **----- Start of picture text -----**<br> Models Performance Beam<br>SBEF Emitter Response Time: 1 ms<br>SBRF1 Receiver Repeatability: 0.03 ms<br>Opposed Mode Pairs, Infrared, 880 nm<br>SBEXF Emitter Response Time: 10 ms<br>SBRXF1 Receiver Repeatability: 0.7 ms<br>**----- End of picture text -----**<br> August 28, 2023 © Banner Engineering Corp. All rights reserved. 13 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** SBFX1 is the first choice for glass fiber optic applications, except in fiber optic retroreflective applications or where faster response speed or visible light area a requirement. Model SBFX1 contains both emitter and receiver and thus accepts either one bifurcated fiber optic assembly or two individual fiber optic cables. The excess gain of model SBFX1 is the high available in the photoelectric industry. As a result, opposed individual fibers operate reliably in many very hostile environments. Also, special miniature bifurcated fiber optic assemblies with bundle sizes as small as 0.020 inches (0.5 mm) in diameter may be used successfully with model SBFX1 for diffuse mode sensing. The excess gain curves and beam patterns illustrate response with standard 0.060 **GLASS FIBER** inch (1.5 mm) diameter and 0.12 inch (3 mm) diameter bundles. Response for smaller or larger bundle sizes may be interpolated. Note: Opposed range shown are meant to illustrate excess gain only and are limited by fiber length. Use scanner block models SBEXF and SBRXF1 for long-range opposed fiber optic sensing. **==> picture [500 x 47] intentionally omitted <==** **----- Start of picture text -----**<br> Models Performance Beam<br>Response Time: 10 ms<br>SBFX1 Opposed or Diffuse Mode, Infrared, 880 nm<br>Repeatability: 1.5 ms<br>**----- End of picture text -----**<br> SBFV1 Visible Red Light Source supplies visible red light to the emitter half of a glass fiber optic photoelectric system. Visible light sensors have less optical energy compared to infrared systems. There are, however, some sensing situations that require visible light wavelengths to realize adequate optical **GLASS FIBER** contrast. Opposed fibers using visible red light are used to reliably sense translucent materials (plastic bottles) that appear transparent to infrared opposed sensors. Fiber assembly model BT13S used with a model L9 or L16F lens makes an excellent visible light sensing system for retroreflective code reading as well as for many short-range retroreflective applications, such as retro sensing across a narrow conveyor. When combined with a bifurcated fiber, model SBFV1 may be used for color registration sensing for applications where there is a large difference between the two colors, for example, black on white. For combinations of red on white, however, the visible green light source of model SBFVG1 is needed. Visible light emitters are also helpful for visual system alignment and maintenance. Models Performance Beam SBFV1 Response Time: 1 ms Opposed, Retroreflective, or Diffuse Mode, Visible Red, 650 Repeatability: 0.3 ms nm SBFVG1 Visible Green Light Source for Color Sensing (Registration Control) . Convergent beam sensors like model SBCVG1 are often used for color registration sensing. However, there are some registration applications where the use of bifurcated fiber optics is beneficial. Fiber optics are able to fit into tight **GLASS FIBER** locations that are too small for a convergent sensor. Fibers also allow a choice of image size. It is important to create an image size that is smaller than the registration mark to maximize optical contrast and to ease sensor response requirements. Fibers allow a match of the light image to the geometry of the registration mark. Scanner block model SBFVG1 will sense most bold color differences, including red on white. Use only power blocks that switch dc (for example, PBT, PBP, PBO, and PBAT) for fast response. Models Performance Beam Response Time: 1 ms SBFVG1 Diffuse Mode, Visible Green, 560 nm Repeatability: 0.3 ms August 28, 2023 © Banner Engineering Corp. All rights reserved. 14 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** SBF1 High-Speed Scanner Block . Fiber optics are often used to sense small parts. Small parts or narrow profiles that move at a high rate of speed can require sensors with fast response times for reliable detection. High-speed fiber optics sensors are ideal for sensing gear or sprocket teeth or other targets in **GLASS FIBER** applications involving counters or shift registers for position control. Selection of the fiber optic sensing tip should involve matching the effective beam of the fiber to the profile of the part to be sensed to maximize the time that the part is sensed and/or the time between adjacent parts. Combining the best selection of fiber tip geometry with a high speed sensor will result in a highly repeatable position sensing system. The model BT13S fiber optic assembly used with a model L9 or L16F lens and a high speed scanner block is an excellent system for retroreflective code reading or for almost any short range retroreflective sensing application. Response time of a MULTI-BEAM sensor is also a function of the power block. For this reason, use only power blocks that switch DC (PBT, PBP, PBO, PBAT, etc) to take advantage of the scanner block's fast response time. Models Performance Beam SBF1 Response Time: 1 ms Opposed, Retroreflective, or Diffuse Mode, Repeatability: 0.3 ms Infrared, 940 nm SBF1MHS Very High-Speed Scanner Block is the model SBF1 modified for highspeed (300 µs) response. It may be used in either fiber optic opposed or fiber optic diffuse mode. Note that the faster response comes at the expense of lower gain (see excess gain curves for both models and MHS modification note). **==> picture [30 x 4] intentionally omitted <==** **----- Start of picture text -----**<br> GLASS FIBER<br>**----- End of picture text -----**<br> Models Performance Beam SBF1MHS Response Time: 300 µs Opposed or Diffuse Mode, Infrared, 940 nm Repeatability: 100 µs ## Scanner Block Performance Curves (Fiber Optic) **==> picture [498 x 133] intentionally omitted <==** **----- Start of picture text -----**<br> Excess Gain Beam Pattern Excess Gain Beam Pattern<br>1000 1000<br>SBEF & SBRF1 SBEXF & SBRXF1<br>L9 Lens Opposed ModeIT23S Fibers 300 mm SBEF/SBRF1Opposed Mode 12.0 in Opposed ModeIT23S Fibers 24” SBEXF & SBRXF1<br>100 200 mm 8.0 in 100 16”<br>100 mm 4.0 in 8”<br>0 0 L9 Lens L16F Lens 0 with IT23S fibersand L16F lenses<br>100 mm 4.0 in<br>10 200 mm 8.0 in 10 8”<br>L16F Lens 300 mm 12.0 in No Lens 16”<br>No Lens 24”<br>0<br>1 1 0 ft 20 ft 40 ft 60 ft 80 ft 100 ft<br>0.03 m 0.3 m 3 m 33 m DISTANCE<br>0.1 ft 1 ft 10 ft 100 ft DISTANCE<br>Distance DISTANCE<br>Excess Gain<br>**----- End of picture text -----**<br> **==> picture [474 x 138] intentionally omitted <==** **----- Start of picture text -----**<br> 1000 1000<br>SBFX1 SBFX1<br>IT13S Fibers Opposed ModeIT23S Fibers 150 mm SBFX1 6.0 in .15” SBFX1<br>Opposed Mode<br>100 100 mm IT23S Fibers 4.0 in 100 .1”<br>50 mm 2.0 in<br>.05”<br>0 IT13S Fibers 0 BT23S<br>0<br>50 mm 2.0 in<br>10 100 mm 4.0 in 10 .05” BT13S<br>IT23S Fibers 150 mm 6.0 in IT23S Fibers .1”<br>IT13S Fibers .15”<br>0<br>1 1<br>0<br>DISTANCE DISTANCE TO 90% WHITE TEST CARD--INCHES<br>DISTANCE DISTANCE<br>Continued on page 16<br>**----- End of picture text -----**<br> August 28, 2023 © Banner Engineering Corp. All rights reserved. 15 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** **==> picture [500 x 571] intentionally omitted <==** **----- Start of picture text -----**<br> Continued from page 15<br>Excess Gain Beam Pattern Excess Gain Beam Pattern<br>1000 SBFV1 1000<br>Opposed Mode 37.5 mm Opposed ModeSBFV1 1.5 in SBFV1 6” SBFV1 Retroreflective mode<br>100 25.0 mm W/IT23S Fibers 1.0 in Retroreflective mode,with BRT-3 reflector 4 BT13S fibers<br>12.5 mm 0.5 in 100 2”<br>12.5 mm0 W/IT13S Fibers 00.5 in with L16F lens, 0 withL9 lenses withL16F lenses<br>10 25.0 mm 1.0 in BT13S fiber 2”<br>10 4”<br>37.5 mm 1.5 in<br>with L9 lens, 6” with BRT-3 reflector<br>0 BT13S fiber<br>1 0 ft 4 ft 8 ft 12 ft 16 ft 20 ft<br>DISTANCE 1 10 FT 100 FT DISTANCE<br>DISTANCE DISTANCE<br>1000 1000<br>Diffuse mode SBFV1 1.8 mm SBFV1Diffuse Mode 0.075 in Diffuse mode SBFVG1 1.8 mm SBFVG1 0.075 in<br>100 (Range based on90% reflectance 1.2 mm0.6 mm BT23S Fiber 0.050 in0.025 in 100 (Range based on90% reflectance 1.2 mm0.6 mm 0.050 in0.025 in<br>white test card) 0 BT13S Fiber 0 white test card) 0 0<br>0.6 mm 0.025 in 0.6 mm 0.025 in<br>10 BT23S fibers 1.2 mm 0.050 in 10 1.2 mm BT23S Fiber 0.050 in<br>1.8 mm 0.075 in BT23S 1.8 mm 0.075 in<br>fiber<br>BT13S fiber s 0 0<br>1 DISTANCE 1 DISTANCE<br>DISTANCE DISTANCE<br>1000 1000<br>SBF1<br>100 L9 Lens Opposed ModeIT23S Fibers 75 mm50 mm25 mm SBF1Opposed Mode 3 in2 in1 in 100 SBF1 Retroreflective mode,with BRT-3 reflectorand BT13S fibers 6”4” SBF1 with BT13S fibersand BRT-3 reflector<br>2”<br>0 IT13S IT23S 0 L16F LENS<br>0<br>25 mm 1 in<br>10 No Lens L16F Lens 50 mm75 mm 2 in3 in 10 withL9 withL16Flenses 2”4”6” L9 LENS<br>1 0 lenses<br>1 0 ft 4 ft 8 ft 12 ft 16 ft 20 ft<br>DISTANCE DISTANCE<br>DISTANCE DISTANCE<br>1000 1000<br>SBF1 SBF1MHS<br>100 (Range based on 90% reflectanceDiffuse mode 0.65 mm1.9 mm1.3 mm Diffuse ModeSBF1 0.075 in0.050 in0.025 in 100 Opposed Mode 75 mm50 mm25 mm SBF1MHSOpposed Mode 3 in2 in1 in<br>white test card) 0 BT13S BT23S 0 0 IT13S IT23S 0<br>0.65 mm 0.025 in 25 mm 1 in<br>10 1.3 mm 0.050 in 10 50 mm 2 in<br>withBT23S fibers 1.9 mm 0.075 in 75 mm 3 in<br>with<br>BT13Sfibers 0 1 0<br>1 DISTANCE<br>0.1 in 1 in 10 in 100 in DISTANCE<br>DISTANCE DISTANCE<br>Continued on page 17<br>EXCESS GAIN<br>EXCESS GAIN EXCESS GAIN<br>EXCESS GAIN<br>EXCESS GAIN<br>**----- End of picture text -----**<br> August 28, 2023 © Banner Engineering Corp. All rights reserved. 16 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** **==> picture [500 x 160] intentionally omitted <==** **----- Start of picture text -----**<br> Continued from page 16<br>Excess Gain Beam Pattern Excess Gain Beam Pattern<br>1000<br>SBF1MHS<br>SBF1MHS<br>(Diffuse mode, 1.95 mm Diffuse Mode 0.075 in<br>100 ranges based on 1.30 mm 0.050 in<br>90% reflectance 0.65 mm 0.025 in<br>white test card)<br>0 BT13S BT23S 0<br>0.65 mm 0.025 in<br>10 with BT23S 1.30mm 0.050 in<br>fiber 1.95 mm 0.075 in<br>with BT13S 0<br>fiber<br>1 DISTANCE<br>.01 IN .1 IN 1 IN 10 IN<br>DISTANCE<br>EXCESS GAIN<br>**----- End of picture text -----**<br> ## Ambient Light Scanner Block A Banner MULTI-BEAM Ambient Light Receiver is a compact modular self-contained photoelectric switch that is operated by sunlight or an incandescent, fluorescent, infrared, or laser light source. A common application involves mounting the scanner block underneath a roller conveyor, with the sensor pointing upwards between the rollers at the overhead factory lighting. Any objects passing over the sensor would then cast a shadow, resulting in an output (dark operate). Ambient receivers are used with LM5-14 delay logic to sense daylight for outdoor lighting control. These sensors can also sense the large amounts of infrared light (heat energy) which is emitted by hot or molten glass, metal, or plastic during processing of these materials. NOTE: Ambient light receiver scanner blocks also work with 2-wire AC power blocks and logic modules. However, the light/dark operate functions are reversed when using 2-wire operation. The circuitry of all MULTI-BEAM components is encapsulated within rugged, corrosion-resistant PBT polyester housings that meet or exceed NEMA 1, NEMA 3, NEMA 12, and NEMA 13 ratings. MULTI-BEAM ambient light receiver scanner blocks have a top-mounted red indicator LED that lights whenever a light level sufficient to cause a change in the output is being sensed. All MULTI-BEAM scanner blocks are totally solid-state for unlimited life. ## Ambient Light Receiver Scanner Block Models **==> picture [500 x 101] intentionally omitted <==** **----- Start of picture text -----**<br> Model Number Amplifier Response Optical Response Diagram<br>SBAR1 Normal Gain<br>Object Incandescent Source<br>10 ms on/off Ultraviolet through near infrared<br>SBAR1GH High Gain (includes all visible wavelengths)<br>**----- End of picture text -----**<br> Model SBAR1 is for general applications, while model SBAR1GH is a high-gain version and is about twenty times more sensitive to light as compared to the SBAR1. The range at which either model senses a light source depends on both the intensity of the light source and the contrast in intensity between the source and the rest of the ambient light in the viewing area. August 28, 2023 © Banner Engineering Corp. All rights reserved. 17 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** **==> picture [250 x 133] intentionally omitted <==** **----- Start of picture text -----**<br> Functional schematic<br>Sensitivity<br>Regulator No connection A<br>CW<br>Dark<br>10 K Light<br>Output to B<br>680 Ω Logic Module<br>+9 V DC<br>C<br>Receiver<br>Common<br>D<br>**----- End of picture text -----**<br> ## Ambient Light Receiver Scanner Block (Glass Fiber Optic) Model **==> picture [500 x 101] intentionally omitted <==** **----- Start of picture text -----**<br> Model Number Amplifier Response Optical Response Diagram<br>SBAR1GHF High Gain 10 ms on/off Wavelengths from visible blue<br>through near infrared<br>**----- End of picture text -----**<br> Model SBAR1GHF is identical to model SBAR1GH except that it is equipped with an upper cover assembly (model UC-RF) which allows an individual glass fiber optic assembly to be attached to the receiver optoelement. This model is used for ambient light detection in locations which are either too confined or too hot for the mounting of a complete scanner block. A typical application involves sensing product presence or counting during processing of red-hot or molten glass or metal. The addition of an L9, L16F, L16FAL, or L16FSS lens to a threaded fiber assembly (for example, IT23S) can narrow the angle of light acceptance to less than the angle of the SBAR1 lens. The high gain amplifier of model SBAR1GHF helps to offset light losses which are experienced with fiberoptic light pipes. ## NOTE: Glass fibers do not efficiently pass ultraviolet wavelengths. **==> picture [169 x 10] intentionally omitted <==** **----- Start of picture text -----**<br> Direct Sensing of Radiant Infrared Energy<br>**----- End of picture text -----**<br> **==> picture [107 x 60] intentionally omitted <==** **----- Start of picture text -----**<br> Kiln<br>Hot Glass Bottle<br>Flow<br>**----- End of picture text -----**<br> **==> picture [97 x 36] intentionally omitted <==** ## MULTI-BEAM 3- and 4-Wire Scanner Block Modifications The following are common modifications to MULTI-BEAM 3- and 4-wire scanner blocks. They are not stocked but are available via special order. Zero Hysteresis Modification "MZ" . Amplifier hysteresis may be removed from 3- and 4-wire scanner blocks when attempting to sense very small signal changes (contrasts less than 3). This modification is designated by adding the suffix August 28, 2023 © Banner Engineering Corp. All rights reserved. 18 MULTI-BEAM Sensors Family "MZ" (modified zero hysteresis). Verify all variables affecting the sensor's optical response remain constant before ordering the zero hysteresis modification. High-Speed Modification "MHS" . Scanner blocks with a 1-millisecond response may be modified for a 300-microsecond (0.3 ms) response. This modification is designated by adding the suffix "MHS" to the scanner block model number (for example, SBF1MHS). The MHS modification reduces the available excess gain by about 50% and also decreases the sensor's immunity to some forms of electrical noise. ## Power Block Models ## Power Block (DC) Models |Models|Input|Output|Specifications|Certifications|Certifications| |---|---|---|---|---|---| |PBT|10 V DC to 30 V DC at less than 60<br>mA (current draw depends on<br>scanner block used). 10% max.<br>ripple.|One open-collector NPN<br>transistor. Current flows from<br>the transistor to the negative||CE|Quna| |PBT48(inactive)|44 V DC to 52 V DC at less than 60<br>mA (current draw depends on<br>scanner block used). 10% max.<br>ripple.|the transistor to the negative<br>side of the power supply. 250<br>mA max.|On-state voltage drop of<br>less than 1 V DC.<br>Off-state leakage current<br>less than 10 microamps.|CE|| |PBT2|10 V DC to 30 V DC at less than 60<br>mA (current draw depends on<br>scanner block used). 10% max.<br>ripple.|Two open-collector NPN<br>transistors: one normally<br>open, one normally closed.<br>250 mA max. for each<br>output.|||| |PBP|10 V DC to 30 V DC at less than 60<br>mA (current draw depends on<br>scanner block used). 10% max.<br>ripple.|One open-collector PNP<br>transistor. Current flows from<br>the positive side of the power<br>supply to the transistor. 250<br>mA max.|||| |PBP48(inactive)|44 V DC to 52 V DC at less than 60<br>mA (current draw depends on<br>scanner block used). 10% max.<br>ripple.|||ce|©| |PBT-1|10 V DC to 30 V DC at less than 60<br>mA (current draw depends on<br>scanner block used). 10% max.<br>ripple.|N/A|N/A|CE|| |PBT48-1(inactive)|44 V DC to 52 V DC at less than 60<br>mA (current draw depends on<br>scanner block used). 10% max.<br>ripple.||||| ## PBT and PBT48 Wiring PBT is the most commonly used DC power block. Its output is an NPN transistor, which sends current to the negative side of the power supply. The load is connected between the output and the positive side of the power supply. The switching capacity is 250 mA. There is no connection to terminal #4. PBT48 has exactly the same configuration as the PBT, but for 48 V DC systems. ## Wiring of PBT and PBT48 **==> picture [123 x 92] intentionally omitted <==** **----- Start of picture text -----**<br> + -<br>V dc<br>(See Specifications)<br>LOAD 3 4<br>1 2<br>**----- End of picture text -----**<br> August 28, 2023 © Banner Engineering Corp. All rights reserved. 19 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** ## PBT2 Wiring PBT2 provides two NPN outputs: one normally open, and one normally closed (equivalent to SPDT relay). The normally closed output may be used when a load must de-energize when the MULTI-BEAM operates (for example, normally closed one-shot). NOTE: Both outputs are open when DC power is removed. **==> picture [121 x 128] intentionally omitted <==** **----- Start of picture text -----**<br> Wiring of PBT2<br>+ -<br>10 to 30V dc<br>LOAD<br>LOAD 3 4<br>1 2<br>**----- End of picture text -----**<br> ## PBP and PBP48 Wiring PBP is similar to model PBT, except that it provides a PNP type output transistor. PNP outputs are frequently required when interfacing to logic systems and programmable logic controllers (PLCs) which require a positive source of DC voltage to generate an input condition. This type of interface may also be accomplished by using PBT with a pull-up resistor installed between transistors #1 and #3. PBP48 has exactly the same configuration as the PBP, but for 48 V DC systems. Wiring of PBP and PBP48 **==> picture [122 x 119] intentionally omitted <==** **----- Start of picture text -----**<br> + -<br>V dc<br>(See Specifications)<br>LOAD<br>3 4<br>1 2<br>**----- End of picture text -----**<br> ## PBT-1 and PBT48-1 Wiring These are power blocks for emitter scanner blocks only (models SBE, SBED, SBEX, SBEV, SBEXD, SBEF, SBEXF). Emitter assemblies do not require logic modules. Wiring of PBT-1 and PBT48-1 **==> picture [123 x 120] intentionally omitted <==** **----- Start of picture text -----**<br> + -<br>V dc<br>(See Specifications)<br>1 2<br>**----- End of picture text -----**<br> August 28, 2023 © Banner Engineering Corp. All rights reserved. 20 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** ## Power Block (DC) General Wiring ## Wiring to a Programmable Controller (requiring an NPN current) **==> picture [164 x 104] intentionally omitted <==** **----- Start of picture text -----**<br> 1<br>P<br>2<br>r<br>3 I<br>o<br>4 N<br>g.<br>5 P<br>PBT 6 U<br>PBT2 C<br>7 T<br>3 4 8 S t<br>r<br>1 2 dc com<br>+10 l.<br>30V dcto dc +<br>**----- End of picture text -----**<br> Use power blocks with NPN outputs to interface to PLCs and other logic devices requiring a current sink at the inputs. Connect the output of the power block (terminal #3) to any input of the PLC. Also, connect the negative of the MULTIBEAM power supply (terminal #2) to the negative of the PLC power supply. ## Wiring to a Programmable Controller (requiring a PNP current) **==> picture [167 x 103] intentionally omitted <==** **----- Start of picture text -----**<br> 1<br>P<br>2<br>r<br>3 I<br>o<br>4 N<br>g.<br>5 P<br>PBP 6 U C<br>7 T<br>t<br>3 4 8 S<br>r<br>1 2 dc com<br>+10 l.<br>30V dcto dc+<br>**----- End of picture text -----**<br> Use power blocks with PNP outputs to interface to PLCs and other logic devices requiring a current source at the inputs. Connect the output of the power block (terminal #3) to any input of the PLC. Also, connect the negative of the MULTIBEAM power supply (terminal #2) to the negative of the PLC power supply. ## Wiring to DC Relay or Solenoid (using NPN output) **==> picture [163 x 153] intentionally omitted <==** **----- Start of picture text -----**<br> + -<br>10 to 30V dc: PBT, PBT2<br>44 to 52V dc: PBT48<br>PBT<br>PBT2<br>PBT48<br>LOAD 3 4<br>1 2<br>**----- End of picture text -----**<br> When using power blocks with current NPN outputs, simple loads connect between the power block output (terminal #3) and the positive supply (terminal #1). August 28, 2023 © Banner Engineering Corp. All rights reserved. 21 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** **==> picture [500 x 180] intentionally omitted <==** **----- Start of picture text -----**<br> Wiring to DC Relay or Solenoid (using PNP output)<br>+ -<br>10 to 30V dc: PBP<br>44 to 52V dc: PBP48<br>When using power blocks with current PNP outputs, simple<br>loads connect between the power block output (terminal #3)<br>PBP<br>PBP48 and DC common (terminal #2).<br>LOAD<br>3 4<br>1 2<br>**----- End of picture text -----**<br> Any number of MULTI-BEAMs may be connected in parallel to one load to create LIGHT-OR (light operate mode) or DARKOR (dark operate mode) multiple sensor logic. In most situations, MULTI-BEAM DC power blocks cannot wire in series. However, addition of an interposing relay with a normally closed contact or a Banner logic module will permit AND logic with a parallel sensor array. ## NOTE: MULTI-BEAM DC power blocks cannot be wired in series. **==> picture [458 x 170] intentionally omitted <==** **----- Start of picture text -----**<br> Parallel Wiring to a Common Load (requiring NPN current) Parallel Wiring to a Common Load (requiring PNP current)<br>+ - + -<br>+10 to 30V dc 10 to 30V dc<br>PBT PBT<br>PBT2 PBT2<br>LOAD PBP PBP<br>LOAD<br>3 4 3 4<br>3 4 3 4<br>1 2 1 2<br>1 2 1 2<br>**----- End of picture text -----**<br> **==> picture [163 x 157] intentionally omitted <==** **----- Start of picture text -----**<br> Wiring to Logic Gate<br>Use pullup resistor<br>to logic supply<br>+5V to 30V dc<br>logic supply<br>PBT<br>PBT2<br>3 4<br>1 2<br>(-) dc 10 to 30V dc<br>+ -<br>*<br>*<br>**----- End of picture text -----**<br> A logic zero (0 V DC) is applied to the gate input when the MULTI-BEAM output is energized. When de-energized, a logic one is applied. The logic supply must be common to the MULTI-BEAM supply negative. August 28, 2023 © Banner Engineering Corp. All rights reserved. 22 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** Wiring of DC Emitter **==> picture [67 x 119] intentionally omitted <==** **----- Start of picture text -----**<br> PBT-1<br>1 2<br>10 to 30V dc<br>+ -<br>**----- End of picture text -----**<br> MULTI-BEAM emitter-only scanner blocks use DC power block models PBT-1 or PBT48-1. These power blocks connect directly across the DC supply, as shown. Emitter models: SBE, SBED, SBEX, SBEV, SBEXD, SBEF. ## Wiring to MAXI-AMP Logic Module **==> picture [207 x 98] intentionally omitted <==** **----- Start of picture text -----**<br> PBT<br>PBT2<br>CL3RA 3 4<br>CL3RB<br>CL5RA 1 2<br>CL5RB<br>4 3<br>5 2<br>6 1<br>7 11<br>8 10<br>9<br>**----- End of picture text -----**<br> The NPN output(s) of MULTI-BEAM power block models PBT and PBT2 may be connected directly to the input of CLseries MAXI-AMP modules. A MAXI-AMP which is powered by AC voltage offers a DC supply with enough capacity to power one MULTI-BEAM sensor, as shown in this wiring diagram. When emitter/receiver pairs are used, the emitter should be powered from a separate power source (for example, using PBA-1, etc.). ## Wiring to B-Series Logic (MRB chassis) **==> picture [166 x 136] intentionally omitted <==** **----- Start of picture text -----**<br> 7 6<br>8 5<br>1 4<br>2 3<br>+15V dc<br>PBT<br>7 6 PBT2<br>8 B-series 5 3 4<br>1 Module 4 1 2<br>2 3<br>120 Vac<br>MRB<br>**----- End of picture text -----**<br> The NPN output(s) of MULTI-BEAM power block models PBT and PBT2 may be connected directly to the input (terminal #5) or to the auxiliary input (terminal #3) of any Banner B-series logic model. The MULTI-BEAM is powered by the MRB chassis as shown. Additional logic may be added on a longer chassis. Banner PLUG-LOGIC modules may also be used. Wiring to MICRO-AMP Logic (model MPS-15 chassis) **==> picture [165 x 130] intentionally omitted <==** **----- Start of picture text -----**<br> NO<br>7 Micro- 6<br>81 LogicAmp 54 NC<br>2 3<br>MODEL MPS-15 PBT<br>PBT2<br>3 4<br>1 2<br>Relay<br>10 to 30V dc<br>+ -<br>120 N N<br>Vac O C C<br>**----- End of picture text -----**<br> The NPN output(s) of MULTI-BEAM power block models PBT and PBT2 may be connected directly to the primary input (terminal #7) or the other inputs of MICRO-AMP logic modules. The following logic modules may be used: MA4-2 (one shot) MA5 (on/off delay) MA4G (4-input AND) MA4L (latch) August 28, 2023 © Banner Engineering Corp. All rights reserved. 23 MULTI-BEAM Sensors Family **==> picture [163 x 165] intentionally omitted <==** **----- Start of picture text -----**<br> Wiring to Counter<br>a<br>PBT<br>PBT2<br>Count or reset input RB<br>3 4<br>Common 1 2<br>Se<br>10 to 30V dc<br>co + -<br>**----- End of picture text -----**<br> Most counters, totalizers, rate meters, etc., including the battery-powered LCD types, accept the NPN output of MULTI-BEAM power block models PBT and PBT2 as an input. Counters which are powered by AC line voltage usually offer a low voltage DC supply with enough capacity to power one MULTI-BEAM (≥10 V DC at ≥60 mA). ## Power Block (AC) Models |Models|Input|Certifications|Output|Specifications| |---|---|---|---|---| |PBA|105–130 V AC, 50/60 Hz|C€<br>Gg.|SPST solid-state switch for AC, ¾<br>A maximum (derated to ½ at 70<br>°C). 10 A maximum inrush for one<br>second or 30 A for one AC cycle<br>(non-repeating).|On-state voltage drop of less than<br>2.5 V AC at full load.<br>Off-state leakage current less than<br>100 µA.<br>Response Time: Add 8.3 ms to the<br>off-time response of the scanner<br>block| |PBB|210–250 V AC, 50/60 Hz|||| |PBD(inactive)|22–28 V AC, 50/60 Hz|||| |PBD-2|11–13 V AC, 50/60 Hz|N/A||| |PBAT|105–130 V AC, 50/60 Hz|c€<br>Gg.|SPST isolated solid-state switch;<br>100 mA maximum (no inrush<br>capacity), 200 V DC maximum,<br>140 V AC maximum.|On-state voltage drop of less than<br>3 V at full load.<br>Off-state leakage current less than<br>100 µA.| |PBBT(inactive)|210–250 V AC, 50/60 Hz||SPST isolated solid-state switch;<br>100 mA maximum (no inrush<br>capacity), 350 V DC maximum,<br>250 V AC maximum.|| |PBA-1|105–130 V AC, 50/60 Hz|c€<br>Gg.|N/A|N/A| |PBB-1|210–250 V AC, 50/60 Hz|||| |PBD-1(inactive)|22–28 V AC, 50/60 Hz|||| |PBO(inactive)|105–130 V AC, 50/60 Hz|Ce<br>Gg.|SPST isolated optically coupled<br>transistor switch (will switch DC<br>only); 50 mA maximum, 30 V DC<br>maximum.|On-state saturation voltage less<br>than 1 V at 2 mA, less than 1.3 mA<br>at 50 mA.<br>Off-state leakage current less than<br>10 µA.| |PBOB(inactive)|210–250 V AC, 50/60 Hz|||| August 28, 2023 © Banner Engineering Corp. All rights reserved. 24 MULTI-BEAM Sensors Family **==> picture [491 x 275] intentionally omitted <==** **----- Start of picture text -----**<br> Continued from page 24<br>Models Input Certifications Output Specifications<br>C€<br>PBAM (inactive) 105–130 V AC, 50/60 Hz 8 V DC at 8 mA maximum (short N/A<br>circuit proof).<br>Gg.<br>SPST isolated solid-state switch;<br>normally closed, ¾ A maximum<br>(derated to ½ A at 70 °C). 10 A<br>maximum inrush for one second or<br>30 A for one AC cycle (non<br>repeating).<br>NOTE: The<br>CE output of On-state voltage drop of less than 2.5 V AC at full load.<br>PBAQ 105–130 V AC, 50/60 Hz the PBAQ<br>will not Off-state leakage current less than<br>conduct 100 µA.<br>G- when<br>power is<br>removed<br>from<br>terminal #1<br>or #2.<br>**----- End of picture text -----**<br> ## PBA, PBB, PBD, and PBD-2 Power Blocks The PBA, PBB, PBD, and PBD-2 power blocks are the most commonly used for AC operation. They are intended to switch the same AC voltage as is used to power the MULTI-BEAM sensor. However, the output of all four blocks is rated for 250 V AC maximum, and is able to switch a voltage which is different than the supply as long as both AC circuits share a common neutral. For example, a PBA could switch a 24 V AC door chime, etc. Observe local codes when mixing AC voltages in a wiring chamber. The blocks are designed to handle the inrush current of AC inductive loads like motor starters and solenoids. The holding current specification of any inductive load should not exceed the 750 mA output rating. There is no minimum load requirement. The power blocks will interface directly to all AC programmable controller inputs. All contain built-in transient suppression to prevent false turn-on or damage from inductive loads and line spikes. Outputs of multiple power blocks may be wired in series or parallel for the AND logic function and the OR logic function. ## Wiring of PBA, PBB, PBD, and PBD-2 **==> picture [122 x 91] intentionally omitted <==** **----- Start of picture text -----**<br> L1 L2<br>V ac<br>(See Specifications)<br>3 4 LOAD<br>1 2<br>**----- End of picture text -----**<br> ## Wiring to Simple AC Load The AC voltage is connected to terminals #1 and #2 to provide power to the MULTI-BEAM. The solid-state output switch behaves as if there were a contact between terminals #3 and #4. L1 is most conveniently applied to terminal #3 by jumpering terminals #1 and #3 inside the MULTI-BEAM. The outputs of all five power block models are rated for 250 V AC maximum and can switch an AC voltage that is different from the supply as long as both AC circuits share a common neutral. Observe local wiring codes when mixing AC voltages in a common wiring chamber. August 28, 2023 © Banner Engineering Corp. All rights reserved. 25 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** Because the output switch is a solid-state device, contact continuity cannot be checked by means of an ohmmeter, continuity tester, etc. To check the functioning of the output switch, a load must be installed and tested along with the MULTI-BEAM. **==> picture [32 x 68] intentionally omitted <==** CAUTION: The output switch could be destroyed if the load becomes a short circuit (that is, if L1 and L2 are connected directly across terminals #3 and #4). NOTE: Output switching capacity is ¾ A maximum. See also "Power Block (AC) General Wiring" on page 28 for additional wiring setups. ## PBAT and PBBT Power Blocks Power block models PBAT and PBBT have an isolated solid-state output switch which may be used to switch either AC or DC. The switch is rated at 100 mA maximum, and there is no capacity for inrush. As a result, these power blocks should not be used to switch AC inductive loads. However, 100 mA is enough capacity to switch many inductive DC loads like small relays and solenoids. Models PBAT and PBBT interface directly to all AC programmable controller inputs. NOTE: Because the saturation voltage of these power blocks is typically greater than 1 volt, they should not be used to interface 5 V DC logic circuits such as TTL. Instead, use special-order power block model PBOL or PBOBL. **==> picture [107 x 9] intentionally omitted <==** **----- Start of picture text -----**<br> Wiring of PBAT and PBBT<br>**----- End of picture text -----**<br> **==> picture [126 x 88] intentionally omitted <==** **----- Start of picture text -----**<br> L1 L2<br>V ac<br>(See Specifications)<br>V ac/dc<br>LOAD<br>3 4<br>1 2<br>**----- End of picture text -----**<br> ## PBA-1, PBB-1, and PBD-1 Power Blocks The PBA-1, PBB-1, and PBD-1 power blocks are used to power emitter-only scanner blocks (models SBE, SBED, SBEX, SBEV, SBEXD, SBEF, SBEXF). Models PBA-1, PBB-1, and PBD-1 save the cost of the output circuitry that must be included in other power block models (these other power blocks may, however, be used to power emitter-only scanner blocks, with the output switching circuitry going unused). Emitter assemblies do not require logic modules. **==> picture [144 x 105] intentionally omitted <==** **----- Start of picture text -----**<br> Wiring of PBA-1, PBB-1 and PBD-1<br>L1 L2<br>V dc<br>(See Specifications)<br>1 2<br>**----- End of picture text -----**<br> Wiring to AC Emitter--MULTI-BEAM emitter-only AC power blocks connect directly across the AC line. Emitter models: SBE, SBED, SBEX, SBEV, SBEXD, SBEF, and SBEXF. August 28, 2023 © Banner Engineering Corp. All rights reserved. 26 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** ## PBO and PBOB Power Blocks The PBO and PBOB power blocks are designed to interface an electronic circuit (or control) at a low DC voltage level, but where there is no DC supply voltage available to power the MULTI-BEAM. Because the output is isolated it may be wired to either source or sink current, and multiple units may be wired in either series or parallel. The output of model PBO or PBOB will directly interface Banner component system logic modules. ## Wiring of PBO and PBOB **==> picture [120 x 130] intentionally omitted <==** **----- Start of picture text -----**<br> L1 L2<br>V ac<br>(See Specifications)<br>+<br>V dc<br>LOAD<br>3 4<br>1 2<br>**----- End of picture text -----**<br> NOTE: The 1-volt saturation prevents direct interfacing to 5-volt logic systems such as TTL. For these low-voltage interfaces, use instead special order model PBOL or PBOBL. Wiring to Counter--Power block models PBO and PBOB are designed to power the MULTI-BEAM with AC voltage and to permit the sensor output to interface with low-voltage DC circuits and devices. A common situation involves inputting to battery-powered LCD totalizers, rate meters, etc. The output switch is the transistor of an optical coupler, which may be connected to switch DC common to the count input. Polarity must be observed. ## PBAM Power Blocks Model PBAM is a special-purpose power block that is powered by 120 V AC, and provides a low-level source of DC output voltage when the sensor's output is energized. It is used primarily to power low-voltage audio tone annunciators such as SONALERTS. The PBAM may also provide a signal to many types of logic devices. The output is approximately 8 V DC when energized, and the output impedance is 1 K ohm (short circuit proof). The output is totally isolated from the AC supply voltage, and may be used to provide an input signal to many line-powered or batterypowered electronic totalizers. Wiring of PBAM **==> picture [124 x 99] intentionally omitted <==** **----- Start of picture text -----**<br> L1 L2<br>V ac<br>+<br>Low Voltage<br>Sonalert<br>-<br>3 4<br>1 2<br>**----- End of picture text -----**<br> ## PBAQ Power Blocks Model PBAQ is identical to model PBA except that the solid-state output contact is normally closed instead of normally open. It is used where it is necessary to have the load de-energize when something is sensed (for example, one shot pulse to deenergize load). When no timing logic is involved, model LM3 can program any power block for normally open or normally closed operation via the light/dark operate jumper. NOTE: Model PBAQ is not compatible with logic module models LM5 and LM5-14. For normally closed on-delay logic, use PBA with LM5R and reverse the light/dark function. NOTE: The output of the PBAQ will not conduct when power is removed from terminal #1 or #2. August 28, 2023 © Banner Engineering Corp. All rights reserved. 27 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** ## Wiring of PBAQ **==> picture [124 x 118] intentionally omitted <==** **----- Start of picture text -----**<br> L1 L2<br>V ac<br>3 4 LOAD<br>1 2<br>**----- End of picture text -----**<br> ## Wiring to Simple AC Load The AC voltage is connected to terminals #1 and #2 to provide power to the MULTI-BEAM. The solid-state output switch behaves as if there were a contact between terminals #3 and #4. L1 is most conveniently applied to terminal #3 by jumpering terminals #1 and #3 inside the MULTI-BEAM. The outputs of all five power block models are rated for 250 V AC maximum, and can switch an AC voltage which is different from the supply as long as both AC circuits share a common neutral. Observe local wiring codes when mixing AC voltages in a common wiring chamber. Because the output switch is a solid-state device, contact continuity cannot be checked by means of an ohmeter, continuity tester, etc. To check the functioning of the output switch, a load must be installed and tested along with the MULTI-BEAM. **==> picture [32 x 68] intentionally omitted <==** CAUTION: The output switch could be destroyed if the load becomes a short circuit (that is, if L1 and L2 are connected directly across terminals #3 and #4). ## NOTE: Output switching capacity is ¾ A maximum. See also "Power Block (AC) General Wiring" on page 28 for additional wiring setups. ## Power Block (AC) General Wiring AC voltage is connected to terminals #1 and #2 to provide power to the MULTI-BEAM. The solid-state output switch behaves as if there were a contact between terminals #3 and #4. L1 is most conveniently applied to terminal #3 by jumpering terminals #1 and #3 inside the MULTI-BEAM. **==> picture [122 x 140] intentionally omitted <==** **----- Start of picture text -----**<br> Wiring to a Simple AC Load<br>L1 L2<br>VAC<br>(See Specifications)<br>PBA<br>PBB<br>PBD<br>PBD2<br>PBAQ<br>3 4 LOAD<br>1 2<br>**----- End of picture text -----**<br> The outputs of all five power block models are rated for 250 V AC maximum, and can switch an AC voltage which is different from the supply as long as both AC circuits share a common neutral. Observe local wiring codes when mixing AC voltages in a common wiring chamber. Since the output switch is a solid-state device, contact continuity cannot be checked by means of an ohmmeter, continuity tester, etc. To check the functioning of the output switch, a load must be installed and tested along with the MULTI-BEAM. CAUTION: The output switch could be destroyed if the load becomes a short circuit (i.e., if L1 and L2 are connected directly across terminals #3 and #4). NOTE: This connection diagram depicts the output switch as a normally open contact. Model PBAQ actually has a normally closed output switch. Continued on page 29 August 28, 2023 © Banner Engineering Corp. All rights reserved. 28 MULTI-BEAM Sensors Family Continued from page 28 **==> picture [57 x 57] intentionally omitted <==** **==> picture [498 x 504] intentionally omitted <==** **----- Start of picture text -----**<br> Wiring to an AC Emitter<br>L1 L2<br>VAC<br>MULTI-BEAM emitter-only AC power blocks connect directly across<br>the AC line, as shown.<br>Emitter models: SBE, SBED, SBEX, SBEV, SBEXD, SBEF, and<br>SBEXF.<br>1 2<br>Wiring in Parallel with Other MULTI-BEAMs<br>L1 L2<br>V ac<br>(See Specifications)<br>Any number of 3- and 4-wire MULTI-BEAM power block outputs may<br>PBAPBB be connected in parallel to a load.<br>PBD<br>PBD2PBAQ Parallel sensor connection is usually used to yield OR logic (that is, if<br>an event occurs at any sensor, the load is energized). The total off-<br>3 4 state leakage current through the load is the sum of the leakage<br>1 2 current of the individual power blocks. However, the maximum leakage<br>current of MULTI-BEAM 3- and 4-wire AC power blocks is only 100<br>µA.<br>PBA<br>PBB As a result, the installation of an artificial load resistor in parallel with<br>PBDPBD2 the load is necessary only for a large number of sensors wired in<br>PBAQ parallel to a light load.<br>3 4 LOAD<br>1 2<br>**----- End of picture text -----**<br> Continued on page 30 August 28, 2023 © Banner Engineering Corp. All rights reserved. 29 MULTI-BEAM Sensors Family Continued from page 29 **==> picture [57 x 57] intentionally omitted <==** ## Wiring in Series with Other MULTI-BEAMs **==> picture [492 x 119] intentionally omitted <==** **----- Start of picture text -----**<br> L1 L2<br>V ac<br>(See Specifications)<br>MULTI-BEAM 3- and 4-wire AC power blocks may be wired in series<br>PBA with each other for the AND logic function. The total voltage drop<br>PBB across the series will be the sum of the individual voltage drops across<br>PBD<br>PBD2 each power block (approximately 3 V per block).<br>PBAQ<br>3 4 3 4 LOAD With most loads, 10 or more power blocks may be wired in series.<br>1 2 1 2<br>**----- End of picture text -----**<br> ## Wiring in Parallel with Contacts or Switches **==> picture [466 x 122] intentionally omitted <==** **----- Start of picture text -----**<br> L1 L2<br>V ac<br>(See Specifications)<br>CR Any number of hard contacts may be wired in parallel with one or<br>more MULTI-BEAM 3- and 4-wire power blocks.<br>PBA All models have less than 100 µA (0.1 mA) of off-state leakage<br>PBBPBD current. The load operates when either the contacts close or the<br>PBD2 MULTI-BEAM output is energized.<br>PBAQ<br>3 4 CR<br>START STOP<br>1 2<br>**----- End of picture text -----**<br> Any number of hard contacts may be wired in parallel with one or more MULTI-BEAM 3- and 4-wire power blocks. ## Wiring in Series with Contacts or Switches **==> picture [124 x 119] intentionally omitted <==** **----- Start of picture text -----**<br> L1 L2<br>V ac<br>(See Specifications)<br>PBA<br>PBB<br>PBD<br>PBD2<br>PBAQ<br>3 4 LOAD<br>1 2<br>**----- End of picture text -----**<br> Terminals #3 and #4 of MULTI-BEAM 3- and 4-wire power blocks may be connected in series with one or more hard contacts. The load operates only when all contacts are closed and the MULTIBEAM output is energized. ## Wiring to a Programmable Logic Controller (PLC) **==> picture [167 x 106] intentionally omitted <==** **----- Start of picture text -----**<br> AC “hot” AC neutral<br>L1 L2 1<br>V ac P<br>(See Specifications) 2 I r<br>3 N o<br>PBA Hookuptypical 4 P g.<br>PBBPBD 8 inputsfor all 5 UT C<br>PBD2PBAQ 6 S t<br>7 r<br>3 4 8 l.<br>1 2 neutral<br>**----- End of picture text -----**<br> Interfacing to a PLC I/O is direct with MULTI-BEAM 3- and 4-wire AC power blocks. All models have less than 100 µA (0.1 mA) of off-state leakage current. If you have a question on wiring to a particular brand of PLC, contact Banner Engineering. Continued on page 31 August 28, 2023 © Banner Engineering Corp. All rights reserved. 30 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** Continued from page 30 ## Wiring to a Counter **==> picture [121 x 116] intentionally omitted <==** **----- Start of picture text -----**<br> PBO<br>Common PBOB<br>Count or reset input<br>3 4<br>1 2<br>VAC<br>L1 L2<br>**----- End of picture text -----**<br> Power block models PBO and PBOB are designed to power the MULTI-BEAM with AC voltage and to permit the sensor output to interface with low-voltage DC circuits and devices. A common situation involves inputting to battery-powered LCD totalizers, rate meters, etc. The output switch is the transistor of an optical coupler, which may be connected to switch DC common to the count input. Polarity must be observed. ## Logic Modules ## Logic Modules (3- and 4-Wire) Models In the table below, the signal represents the light condition (in LIGHT operate) or the dark condition (in DARK operate), and the output represents the energized condition of the solid-state output switch (power block). Delay refers to the time delay before the output operates, and hold refers to the time that the output remains on after the event has occurred. **==> picture [500 x 391] intentionally omitted <==** **----- Start of picture text -----**<br> Functional schematic<br>Off<br>On<br>Processed Logic Signal<br>A<br>to Power Block<br>Dark Off<br>Signal from Light Light/Dark On<br>B<br>Scanner Block Operate Circuit<br>(Jumper for D.O.)<br>+8 V dc<br>C<br>CW CW In<br>Timer<br>Adjustments Timer Circuit<br>+ +<br>Out<br>D<br>Common<br>Model Function Description of Logic<br>on-off LM1 is an on-off logic modules that causes the power block output to follow the action of the<br>scanner block: when the scanner block sees a LIGHT signal, the output is energized; when<br>LM1 OUTPUT the scanner block sees a DARK signal, the output is de-energized. This is LIGHT operate<br>mode. If the application calls for DARK operate mode, the LM1 may be used with normally-<br>SIGNAL closed power blocks, such as PBAQ or PBT2.<br>The LM2 provides flip-flop or toggling action of the power block output, such that each time<br>the scanner block changes from a DARK state to a LIGHT state, the output changes state.<br>alternate action The output remains in the last state until another change occurs. Some example applications<br>for the LM2 are:<br>LM2 OUTPUT • Operating a diverter gate that splits a production line into two lines<br>• Operating room lighting by breaking a photoelectric beam<br>SIGNAL ◦ If the lights are OFF, breaking the beam turns them ON<br>◦ If the lights are ON, breaking the beam turns them OFF<br>**----- End of picture text -----**<br> Continued on page 32 August 28, 2023 © Banner Engineering Corp. All rights reserved. 31 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** **==> picture [500 x 604] intentionally omitted <==** **----- Start of picture text -----**<br> Continued from page 31<br>Model Function Description of Logic<br>on-off The LM3 is an on-off logic module that has the ability to be programmed for either LIGHT<br>operate or DARK operate. It comes with a jumper wire installed: with the jumper in place, the<br>LM3 OUTPUT output is DARK operated; with the jumper removed, the output is LIGHT operated. The LM3<br>is the most commonly used logic module when no timing function is desired, particularly if it is<br>SIGNAL not known at the time of ordering which operate mode (LIGHT or DARK) will be needed.<br>one-shot (retriggerable)<br>HOLD HOLD The LM4-2 provides a one-shot (or single-shot) output pulse each time there is a transition<br>from LIGHT to DARK (jumper installed) or from DARK to LIGHT (jumper removed). The<br>LM4-2 OUTPUT output pulse time range is from 0.01 seconds to 1 second. The duration of the pulse is independent of the duration of the input signal. The timing of the LM4-2 restarts each time<br>SIGNAL that the input signal is removed and then reapplied. This is a retriggerable one shot. This<br>feature may be applied to some rate sensing applications (use LM6-1 for true rate sensing).<br>Setable time range: 0.1 to 1 second.<br>one-shot (non-retriggerable) The LM4-2NR provides a one-shot (or single shot) output pulse each time there is a transition<br>HOLD HOLD from LIGHT to DARK (jumper installed) or from DARK to LIGHT (jumper removed). The<br>output pulse time range is from 0.01 seconds to 1 second. The duration of the pulse is<br>LM4-2NR OUTPUT independent of the duration of the input signal. The output pulse of the LM4-2NR must<br>complete before it recognizes another input transition. This is called a non-retriggerable one<br>SIGNAL shot, which sometimes offers an advantage in indexing or registration control applications<br>Setable time range: 0.1 to 1 second. where multiple input signals are possible during advance of the product.<br>on-delay The LM5 is a true on-delay logic module. The input signal must be present for a<br>predetermined length of time before the output is energized. The output then remains<br>DELAY energized until the input signal is removed. If the input signal is not present for the<br>predetermined time period, no output occurs. If the input signal is removed momentarily, and<br>LM5 OUTPUT then reestablished, the timing function starts over again from the beginning. A LIGHT/DARK<br>operate selection jumper wire is included. The standard time range is 0.15 seconds to 15<br>SIGNAL seconds (field adjustable), and other ranges are available. The LM5 is often used to detect<br>jams on a conveyor line, where a beam broken for longer than a preset period of time implies<br>Setable time range: 1.5 to 15 seconds. a product jammed in the light beam.<br>off-delay The LM5R is an off-delay logic module, similar to the LM5, except that timing begins on the<br>trailing edge of the input signal. When the input occurs, the output is immediately energized; if<br>HOLD HOLD the input is then removed, the output remains energized for the adjustable predetermined<br>time period, then de-energizes. If the input is removed but then re-established while the<br>LM5R OUTPUT timing is holding the output energized, a new output cycle is begun. The LM5R can be used<br>to tell when no products have broken a beam for a predetermined length of time, therefore<br>SIGNAL indicating a jam or an empty reservoir upstream. A LIGHT/DARK operate selection jumper<br>wire is included. Timing range is 0.15 seconds to 15 seconds, and optional ranges are<br>Setable time range: 1.5 to 15 seconds. available.<br>on- & off-delay The LM5-14 combines the function of an on-delay and an off-delay into one logic module.<br>When the signal is present for more than the on-delay time, the output energizes. The off-<br>DELAY HOLD delay circuit is now active, and holds the output on even if the input signal disappears for<br>short periods of time. If the input signal is gone for longer than the off-delay time, the output<br>LM5-14 OUTPUT finally drops out. The most common use for the LM5-14 is to control fill level, for example in a<br>bin: when the bin is full, a beam is broken, and a predetermined time later, the flow is<br>SIGNAL stopped. After the level has fallen below the beam for a time, the flow is restarted. The time<br>delays control the high and low levels. Each delay is independently adjustable for 0.15<br>Setable time range: 1.5 to 15 seconds. seconds to 15 seconds.<br>limit timer The LM5T limit timer combines the function of on-off logic and on-delay logic. As long as the<br>signal is present for only short periods of time, the output follows the action of the input signal.<br>HOLD If the input signal is present for longer than the predetermined time, the output de-energizes.<br>The output only re-energizes when the input signal is removed and then reestablished.<br>LM5T OUTPUT Interval timers are used to operate loads which must not run continuously for long periods of<br>time, such as intermittent duty solenoids and conveyor motors. The LM5T may be used to run<br>SIGNAL a supermarket checkout conveyor, always bringing the product up to the scanner beam and<br>then stopping the motor. When the last item is removed, the motor times out and stops.<br>Setable time range: 1.5 to 15 seconds. Timing range is 0.15 seconds to 15 seconds.<br>Continued on page 33<br>**----- End of picture text -----**<br> August 28, 2023 © Banner Engineering Corp. All rights reserved. 32 MULTI-BEAM Sensors Family **==> picture [494 x 608] intentionally omitted <==** **----- Start of picture text -----**<br> |||||| |---|---|---|---|---| |Continued from page 32| |Model|Function|Description of Logic| |The LM6-1 is a true overspeed or underspeed sensing logic module that monitors signals| |from a scanner block and continuously calculates the time between input signals, and| |rate sensor| |compares that time with the reference set by the HOLD potentiometer. A jumper allows the| |mode to be changed from overspeed (jumper installed) to underspeed (jumper removed).| |In the overspeed mode, the output will drop if the preset rate is exceeded.| |LM6-1|OUTPUT|—_|In the underspeed mode, the output remains energized until the input rate drops below the| |SIGNAL|maT|=|#$3 Lmee|preset. The output will not pulse at low speeds, as retriggerable one-shots do. A DELAY| |adjustment allows the LM6-1 to ignore data for the first several seconds after power is| |Setable rate: 60 to 1200 pulses per minute.|applied, to permit the rate to accelerate to operating speed without false underspeed outputs.| |The sensing rate may be adjusted from 60 pulses to 1200 pulses per minute (0.05 seconds to| |1 second per pulse), and the power-up inhibit from 1 second to 15 seconds.| |The LM8 is a repeat cycle timing module with independently adjustable delay and hold times.| |When an input signal is received from the scanner block, a delay period begins during which| |there is no output. If the signal remains, the delay period is followed by a hold period, during| |repeat cycler|which the output is energized. If the signal still remains, the hold period times out, releasing| |the output and starting a new delay period. This sequence continues indefinitely until the input| |signal is removed. The LM8 is used in edgeguide and other registration control schemes| |DELAY|rie|>||HOLD|where it is desired to pulse the correction motor to avoid overcorrection that might occur with| |LM8|OUTPUT|a continuous output. Both time ranges are independently adjustable from 0.15 seconds to 15| |seconds.| |SIGNAL|—| |Setable time range: 1.5 to 15 seconds.|NOTE:|Use of the LIGHT/DARK operate jumper is reversed: remove| |for DARK, leave in place for LIGHT.| |delayed one-shot|The LM8-1 is a delayed one-shot that functions like two individual one-shots, with the end of| |the first initiating the second. When an input signal occurs, a delay period is initiated, during| |DELAY|HOLD|DELAY|HOLD|which time the output is not energized. After the delay, the output is energized for the hold| |period, then de-energized. No further action takes place unless the signal is removed and| |LM8-1|OUTPUT|then reestablished. This sequence is independent of the duration of the input signal. The| |LM8-1 is frequently used to sense a product, and then act on that product a short time later| |SIGNAL|i|—Sl(ise|when it is clear of the inspection station. An example might be to inspect cartons for open| |flaps, and to eject the faulty cartons when they have completely passed the inspection point.| |Setable time range: 1.5 to 15 seconds.|Both time ranges are adjustable from 0.15 seconds to 15 seconds.| |The LM8A incorporates both a delay and a hold time, except that the delay is a true on-delay| |(this differs slightly from the LM8-1). If the input signal does not last for the total duration of| |on-delay one-shot|the delay time, no output action occurs. If the delay time passes, the one-shot output occurs,| |regardless of what happens to the input signal. Removing the input signal and reapplying it| |DELAY|HOLD|begins a new cycle. The LM8A is used to eject a part that has remained in the sensor beam| |longer than the delay time (for instance, a jammed part). Both time ranges are independently| |LM8A|OUTPUT|adjustable from 0.15 seconds to 15 seconds.| |et| |SIGNAL|=|§$MPwvD[| |NOTE:|Use of the LIGHT/DARK operate jumper is reversed: remove| |Setable time range: 1.5 to 15 seconds.|for DARK, leave in place for LIGHT.| |The LM10 is a fixed-count divide-by-ten logic module, with neither timing nor LIGHT/DARK| |÷10 counter|operate functions. When power is first applied, the output is OFF. With each dark-to-light| |transition, the LM10 enters one count in its memory. After five counts, the output is energized,| |and it remains energized until the tenth count. It then de-energizes, and the sequence| |LM10|continues. The LM10 is intended for product counting applications using programmable logic| |OUTPUT|=|controllers (PLC) or computers, where the scan time of the input section of the controller is| |too slow to permit catching high speed count rates. It may also be used with| |SIGNAL|mrt tTr|ttt) )|electromechanical totalizers, which suffer from this same slow response. In operation, the| |registered count must be multiplied by ten to get the true count (ambiguity of five).| |LMT is a plug-in test logic module for use when troubleshooting MULTI-BEAM sensors. It| |contains LED indicator lights in place of the timing potentiometers and a miniature switch in| |place of the LIGHT/DARK operate jumper. The indicator lights display the operation of the| |LMT Test|scanner block and power block to verify proper functioning. The switch permits manual| |Logic|operation of the load to verify the output switching circuit. The step-by-step testing procedure| |included with the LMT allows a MULTI-BEAM to be completely tested without removing it from| |ele|the installation, and, if there is a faulty scanner block, power block, or logic module, the LMT will identify it.| **----- End of picture text -----**<br> ## Logic Module Modifications The time ranges of any MULTI-BEAM logic module may be factory modified. Time range modification is often necessary to improve the setability of the timing function. Some time range modifications are carried in stock. Other time range August 28, 2023 © Banner Engineering Corp. All rights reserved. 33 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** modifications may be quoted. When ordering modified logic modules, add the letter M after the model number, followed by the maximum time desired (in seconds). The table below lists possible modifications. **==> picture [500 x 107] intentionally omitted <==** **----- Start of picture text -----**<br> Model Number Suffix Setable Time Range<br>M.01 0.001 seconds to 0.01 seconds<br>M.1 0.01 seconds to 0.1 seconds<br>M.5 0.05 seconds to 0.5 seconds<br>M1 0.1 seconds to 1 second<br>M5 0.5 seconds to 5 seconds<br>M15 1.5 seconds to 15 seconds<br>**----- End of picture text -----**<br> - For logic modules with a single timing function , specify the maximum desired time in seconds (for example, LM5M5 indicates an LM5 on-delay with the delay time adjustable up to 5 seconds). - For logic modules with dual timing functions , specify the maximum desired delay and hold time in seconds (for example, LM5-14M1M5 indicates an LM5-14 on-off delay with an on-delay adjustable up to 1 second and an off-delay adjustable up to 5 seconds). Always specify both timing ranges, even if only one is to be modified. - For fixed timing , the letter F should always be followed by the desired time, in seconds (for example, LM5MF1 would be an LM5 on-delay with a fixed 1 second delay time). For fractions of seconds, use decimal equivalents, such as LM5MF.5, LM5MF.01, etc. August 28, 2023 © Banner Engineering Corp. All rights reserved. 34 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** ## Chapter Contents Scanner Blocks ................................................................................................................................................................................................. 35 Power Block (2-wire) Models............................................................................................................................................................................. 41 Logic Modules (2-Wire) ..................................................................................................................................................................................... 45 ## Chapter 3 ## 2-Wire Sensors The components of the MULTI-BEAM 2-wire family of modular self-contained sensors are physically identical to the 3- & 4- wire components. However, the 2-wire components are designed to wire directly in series with an AC load, exactly like a limit switch. This design makes the 2-wire MULTI-BEAM impossible to wire backward. MULTI-BEAM 2-wire scanner blocks with their 10-millisecond response time have approximately the same optical performance as the 1-millisecond 3- & 4- wire scanner block models. The off-state leakage current of 2-wire MULTI-BEAM sensors is less than 1 milliamp, the lowest value of any 2-wire photoelectric sensor. This makes the MULTI-BEAM 2-wire photoelectric device the most probable device to interface directly with AC inputs of programmable logic controllers (PLCs). ## Scanner Blocks MULTI-BEAM 2-wire sensors connect in series with an AC load, exactly like a heavy-duty limit switch. Models are offered in all sensing modes, including glass fiber optic. All have 10 ms on-off response time and built-in protection against false pulse on power-up. The circuitry of all MULTI-BEAM components is encapsulated within rugged, corrosion-resistant PBT polyester housings that meet or exceed NEMA 1, 3, 12, and 13 ratings. MULTI-BEAM 2-wire scanner blocks include Banner's exclusive, patented Alignment Indicating Device (AID™) system, which lights a top-mounted LED when the sensor sees its modulated light source and pulses at a rate proportional to the strength of the received light signal. ## Scanner Block (2-Wire) Models Models Performance Sensing Mode Description SBE The 2SBR1 receiver model is used with the SBE emitter, the same emitter used with the 1 ms 3- & 4-wire receiver model SBR1. The response time, however, is determined by the receiver, and is 10 ms. This pair will work reliably in slightly dirty (average manufacturing plant) conditions up to 18 m (60 ft) opposed, and outdoors Range: 45 m (150 ft) up to 6.1 m (20 ft). When more distance (or excess gain) is required, use 3- & 4- wire receiver model SBRX1 with the SBEX emitter. The 2SBR1 will not work with Response: 10 ms on/off the visible emitter SBEV. Use opposed mode sensors as a first choice in any Repeatability: 0.03 ms application, except where the material to be sensed is translucent to light or so small that it will not break the effective beam diameter. The SBE emitter uses a 3- & 2SBR1 Beam: infrared, 940 nm 4-wire power block. Power blocks for use with SBE include models PBA-1, PBB-1, **OPPOSED** PBD-1, PBT-1, and PBT48-1 (see datasheet 03508). Effective Beam: 25 mm (1 in) diameter NOTE: Users must purchase one emitter and one receiver for opposed mode sensors . Model 2SBL1 is the retroreflective mode scanner block in the 2-wire MULTI-BEAM family. It has the same excellent optical performance as model SBL1 in the 3-& 4- Range: 2.5 cm to 9 m ( 1 in to 30 ft) wire family. If the application calls for breaking a retroreflective beam with shiny objects such as metal cans or cellophane-wrapped packages, mount the 2SBL1 Response: 10 ms on/off 2SBL1 and its retroreflector at an angle of 10 degrees or more to the shiny surface to Repeatability: 2.5 ms eliminate an direct reflections from the object itself, or consider using 3- & 4-wire **RETRO** scanner block model SBLVAG1. Alternatively, the MAXI-BEAM, VALU-BEAM, and Beam: infrared, 940 nm MINI-BEAM families offer 2-wire AC visible and polarized retroreflective models. The gain falls off at very close sensing ranges, so much so that retroreflectors cannot be used reliably closer than one inch from the sensor. Continued on page 36 August 28, 2023 © Banner Engineering Corp. All rights reserved. 35 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** **==> picture [500 x 275] intentionally omitted <==** **----- Start of picture text -----**<br> Continued from page 35<br>Models Performance Sensing Mode Description<br>Focus at: 38 mm (1.5 in) These convergent mode 2-wire scanner blocks are identical in performance to their<br>3- & 4-wire equivalents, except for the 10 ms response time. They are designed for<br>Response: 10 ms on/off 2-wire applications where background objects might be seen by proximity mode<br>2SBC1 sensors, or where the precision of a small focused image is important (for example,<br>Repeatability: 2.5 ms edge-guiding or position control).<br>Beam: infrared, 940 nm Model 2SBC1 provides much more excess gain at its focus point as compared to<br>the diffuse mode sensors. Convergent mode sensors are preferable to diffuse<br>Focus at: 10 cm (4 in) mode sensors if the distance from the sensor to the object to be detected can be<br>CONVERGENT kept constant. Models 2SBC1 and 2SBC1-4 may be derived from retro model<br>Response: 10 ms on/off 2SBL1 by exchange of the upper cover assembly. Model 2SBC1 uses upper cover<br>2SBC1-4 UC-C, and model 2SBC1-4 uses upper cover model UC-C4.<br>Repeatability: 2.5 ms<br>These may be interchanged. A 152 mm (6 in) convergent model may be created<br>Beam: infrared, 940 nm from either model by substituting upper cover UC-C6.<br>Range: 30 cm (12 in)<br>Response: 10 ms on/off<br>2SBD1 Models 2SBD1 and 2SBDX1 diffuse (proximity) mode scanner blocks are identical<br>Repeatability: 2.5 ms except for their lenses. Model 2SBD1 uses upper cover model UC-D, and the<br>2SBDX1 uses UC-L . While the UC-L lens extends the range to over 762 mm (30<br>Beam: infrared, 880 nm in), it creates a dip in the excess gain at closer ranges. As a result, the 2SBDX1<br>may sense a dark colored object at 254 mm (10 in), but it may not see it at all at 51<br>Range: 76 cm (30 in) mm (2 in).<br>DIFFUSE<br>Response: 10 ms on/off If the application is not completely defined, either scanner block may be ordered,<br>2SBDX1 along with the complementary upper cover as an accessory.<br>Repeatability: 2.5 ms<br>Beam: infrared, 880 nm<br>**----- End of picture text -----**<br> Continued on page 37 August 28, 2023 © Banner Engineering Corp. All rights reserved. 36 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** **==> picture [500 x 245] intentionally omitted <==** **----- Start of picture text -----**<br> Continued from page 36<br>Models Performance Sensing Mode Description<br>Scanner block 2SBF1 combines the simplicity of 2- wire configuration with the<br>sophistication and versatility of optical fibers. The infrared source of this model will<br>work with any Banner glass fiber optic assembly, except bifurcated assemblies with<br>bundle diameters less than 1.59 mm (1/16 in). Since fibers are frequently used for<br>sensing small parts, fast response time is often a consideration.<br>If the application requires response near the 10 ms specification of the 2SBF1,<br>consider the faster 3- & 4-wire model SBF1. For complete information on glass fiber<br>optic assemblies, see www.bannerengineering.com.<br>Range: see Performance Curves The following fiber optic cables and lenses are commonly used with the model<br>2SBF1 scanner block:<br>Response: 10 ms on/off<br>2SBF1 IT13S: L16F:<br>Repeatability: 2.5 ms GLASS FIBER Individual assembly 25 mm (1.0 in) diameter lens<br>Beam: infrared, 880 nm 1.5 mm (0.06 in) diameter BT13S:<br>fiber bundle<br>Bifurcated assembly<br>IT23S: 1.5 mm (0.06 in) diameter<br>Individual assembly fiber bundles<br>3 mm (0.12 in) diameter fiber BT23S:<br>bundle<br>Bifurcated assembly<br>L9: 3 mm (0.12 in) diameter fiber<br>12 mm (0.5 in) diameter lens bundles<br>**----- End of picture text -----**<br> ## Scanner Block (2-Wire) Performance Curves **==> picture [498 x 17] intentionally omitted <==** **----- Start of picture text -----**<br> Opposed<br>**----- End of picture text -----**<br> **==> picture [421 x 206] intentionally omitted <==** **----- Start of picture text -----**<br> Beam Pattern<br>Excess Gain<br>1000<br>SBE / 2SBR1 SBE/2SBR1<br>1500 mm 60.0 in<br>Opposed Mode<br>1000 mm 40.0 in<br>100<br>500 mm 20.0 in<br>0 0<br>500 mm 20.0 in<br>10<br>1000 mm 40.0 in<br>1500 mm 60.0 in<br>1<br>0.33 m 3.3 m 33 m 330 m 0 9 m 18 m 27 m 36 m 45 m<br>1 ft 10 ft 100 ft 1000 ft 30 ft 60 ft 90 ft 120 ft 150 ft<br>Distance DISTANCE<br>Excess Gain<br>**----- End of picture text -----**<br> August 28, 2023 © Banner Engineering Corp. All rights reserved. 37 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** Retroreflective **==> picture [420 x 193] intentionally omitted <==** **----- Start of picture text -----**<br> Excess Gain Beam Pattern<br>1000<br>2SBL1 6”<br>2SBL1<br>E 4”<br>X with BRT-3 reflector<br>CE 100 with BRT-1 1" with BRT-3 3" 2”<br>S reflector reflector<br>S 0<br>G 2”<br>A 10<br>I 4”<br>N with<br>BRT-T<br>6”<br>tape<br>1<br>0 6 ft 12 ft 18 ft 24 ft 32 ft<br>DISTANCE DISTANCE TO REFLECTOR<br>**----- End of picture text -----**<br> **==> picture [498 x 16] intentionally omitted <==** **----- Start of picture text -----**<br> Convergent<br>**----- End of picture text -----**<br> **==> picture [498 x 416] intentionally omitted <==** **----- Start of picture text -----**<br> Excess Gain Beam Pattern<br>1000<br>.12”<br>(Range based on 90%<br>reflectance white .08”<br>test card)<br>100 .04”<br>0<br>2SBC1<br>.04” 2SBC1<br>10 2SBC1-4<br>2SBC1-4 .08”<br>.12”<br>1<br>0.1 1 10 100 0 1.5 3.0 4.5 6.0 7.5<br>Distance (in) Distance (in)<br>Diffuse<br>Excess Gain<br>Beam Pattern<br>1000<br>2SBD1 .6”<br>E<br>X Range based on 90% .4”<br>C 100 reflectance white<br>E test card .2” 2SBD1<br>S<br>S 0<br>G .2”<br>A 10<br>I .4”<br>N<br>.6”<br>1<br>0 3 6 9 12 15<br>100 IN<br>DISTANCE TO 90% WHITE TEST CARD (in)<br>DISTANCE<br>Excess Gain<br>**----- End of picture text -----**<br> **==> picture [72 x 8] intentionally omitted <==** **----- Start of picture text -----**<br> Continued on page 39<br>**----- End of picture text -----**<br> August 28, 2023 © Banner Engineering Corp. All rights reserved. 38 MULTI-BEAM Sensors Family Continued from page 38 Diffuse **==> picture [57 x 57] intentionally omitted <==** **==> picture [416 x 196] intentionally omitted <==** **----- Start of picture text -----**<br> Excess Gain<br>Beam Pattern<br>1000<br>2SBDX1 .75” 2SBDX1<br>E<br>X .5”<br>Range based on 90%<br>C 100 reflectance white<br>E test card .25”<br>S<br>S 0<br>G .25”<br>A 10<br>I .5”<br>N<br>.75”<br>1 0 8 16 24 32 40<br>.1 IN 1 IN 10 IN 100 IN<br>DISTANCE DISTANCE TO 90% WHITE TEST CARD (in)<br>**----- End of picture text -----**<br> **==> picture [498 x 17] intentionally omitted <==** **----- Start of picture text -----**<br> Fiber Optic (glass fibers)<br>**----- End of picture text -----**<br> **==> picture [498 x 389] intentionally omitted <==** **----- Start of picture text -----**<br> Excess Gain - Opposed<br>Beam Pattern - Opposed<br>1000<br>2SBF1 2SBF1<br>E 6”<br>X L9 Lens Opposed ModeIT23S Fibers opposed mode<br>C 4”<br>E 100<br>2”<br>S<br>S 0 IT23S fibers,<br>no lenses<br>G 10 2”<br>A L16F Lens<br>I 4”<br>N No Lens with IT23S fibers<br>6” and L9 lenses<br>1<br>0.03 m 0.3 m 3 m 33 m<br>0.1 ft 1 ft 10 ft 100 ft 0 2 ft 4 ft 6 ft 8 ft 10 ft<br>DISTANCE DISTANCE<br>Excess Gain - Retroreflective Beam Pattern - Retroreflective<br>1000<br>Retroreflective mode, 6” with BT13S fibers<br>2SBF1 with BRT-3 reflector 2SBF1 and BRT-3 reflector<br>and BT13S fibers<br>4”<br>100<br>2”<br>L16F LENS<br>0<br>with 2”<br>10<br>L16F<br>lenses 4”<br>with L9 LENS<br>L9<br>lenses 6”<br>1<br>.1 FT 1 FT 10 FT 100 FT 0 ft 4 ft 8 ft 12 ft 16 ft 20 ft<br>DISTANCE DISTANCE<br>EXCESS GAIN<br>**----- End of picture text -----**<br> Continued on page 40 August 28, 2023 © Banner Engineering Corp. All rights reserved. 39 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** ## Continued from page 39 **==> picture [498 x 16] intentionally omitted <==** **----- Start of picture text -----**<br> Fiber Optic (glass fibers)<br>**----- End of picture text -----**<br> **==> picture [424 x 201] intentionally omitted <==** **----- Start of picture text -----**<br> Excess Gain - Diffuse Beam Pattern - Diffuse<br>1000<br>2SBF1 .075<br>Diffuse mode<br>.05 2SBF1<br>100 (Range based on 90% reflectance IN .025 BT13S<br>white test card) C<br>H 0<br>E<br>10 S .025<br>with BT23S<br>BT23S fibers .05<br>with<br>BT13S .075<br>fibers<br>1<br>0.1 in 1 in 10 in 100 in<br>0 0.5 1.0 1.5 2.0 2.5<br>DISTANCE<br>DISTANCE TO 90% WHITE TEST CARD--INCHES<br>EXCESS GAIN<br>**----- End of picture text -----**<br> ## Scanner Block (2-Wire) Wiring MULTI-BEAM 2-wire sensors wire in series with an appropriate load. This combination, in turn, wires directly across the AC line. A 2-wire sensor may be connected exactly like a mechanical limit switch. Basic Wiring of 2-Wire MULTI-BEAM **==> picture [102 x 95] intentionally omitted <==** **----- Start of picture text -----**<br> L1 L2<br>1 2 Load<br>**----- End of picture text -----**<br> The MULTI-BEAM remains powered when the load is off by a residual current that flows through the load. This off-state leakage current is always less than 1 mA. The effect of this leakage current depends upon the characteristics of the load. The voltage that appears across the load in the off-state is equal to the leakage current of the sensor multiplied by the resistance of the load: Voff = 1 mA × Rload . If this resultant off-state voltage is less than the guaranteed turn-off voltage of the load, the interface is direct. If the off-state voltage causes the load to stay on, connect an artificial load resistor in parallel with the load to lower its effective resistance. Most loads, including most programmable logic controller (PLC) inputs, will interface to 2-wire sensors with 1 mA leakage current without needing an artificial load resistor. There is no polarity requirement. Either wire may connect to terminal #1 and the other to terminal #2. **==> picture [32 x 38] intentionally omitted <==** CAUTION: All three components of a MULTI-BEAM 2-wire sensor will be destroyed if the load becomes a short circuit. August 28, 2023 © Banner Engineering Corp. All rights reserved. 40 MULTI-BEAM Sensors Family ## Functional Schematic ## Power Block (2-wire) Models MULTI-BEAM 2-wire power block models 2PBA, 2PBB, and 2PBD contain a low-voltage power supply that uses a unique circuit to take a very small leakage current through the load and convert it to the dc power required to run the scanner block and logic module. They also contain the solid-state switch that operates the load, and a transient suppression circuit to prevent false operation from high voltage spikes on the incoming line. They are completely solid-state for unlimited operating life. Model 2PBR is a 4-wire power block that works with 2-wire scanner blocks and logic modules and offers an SPST "hard" contact for switching heavy AC or DC loads. Model 2PBR2, also for use with 2-wire scanner blocks and logic modules, uses a 3- or 4-wire connection with SPDT "hard" contacts for switching heavy AC loads. NOTE: MULTI-BEAM 2-wire AC power blocks are color-coded black. |Models|Operating Voltage|Outputs|Specifications|Certifications| |---|---|---|---|---| |2PBA|105 to 130 V AC;<br>50/60 Hz|SPST solid-state switch, 3/4 amp<br>maximum (derated to 1/2 amp at<br>70 °C). 10 amps maximum<br>inrush for 1 second (non-<br>repeating).|On-State Voltage Drop: Less than 10<br>V<br>Leakage Current: Less than 1 mA<br>(resistive or inductive loads)|LISTED<br>@:| |2PBB(inactive)|210 to 250 V AC;<br>50/60 Hz|||| |2PBD(inactive)|22 to 28 V AC; 50/60<br>Hz|||N/A| |2PBR|105 to 130 V AC;<br>50/60 Hz|SPST electromechanical relay<br>contact.|Contact Rating: 250 V AC max, 30 V<br>DC max, 5 amps max (resistive load);<br>install MOV across contact if switching<br>an ac inductive load.<br>Closure time: 20 ms<br>Release time: 20 ms<br>Maximum Switching Speed: 20<br>operations/second<br>Mechanical Life: 10,000,000<br>operations|N/A| ## Power Block (2-Wire) Wiring Diagrams ## 2PBA, 2PBB, and 2PBD Power Blocks MULTI-BEAM 2-wire power blocks wire directly in series with an AC load, exactly like a limit switch. The response time of 2- wire power blocks is determined by the scanner block, whose response time is 10 ms on/off. A built-in false pulse protection circuit holds the output OFF for 10 ms after power is initially applied to the power block. MULTI-BEAM 2-wire power blocks August 28, 2023 © Banner Engineering Corp. All rights reserved. 41 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** will operate from –40 to 70 °C (–40 to 158 °F). Resistive loads must be less than 15,000 ohms and inductive loads must be greater than 1.2 watts (10 mA). **NOTE:** Output has a maximum load capacity of 3/4 A, a maximum resistive load of 15 kOhms, and a minimum inductive load of 1.2 watts (10 mA). **==> picture [92 x 7] intentionally omitted <==** **----- Start of picture text -----**<br> Functional Schematics<br>**----- End of picture text -----**<br> **==> picture [367 x 161] intentionally omitted <==** **----- Start of picture text -----**<br> Load 1 A<br>on<br>off<br>No Connection B<br>2<br>+8 V dc<br>C<br>+<br>− Common<br>D<br>**----- End of picture text -----**<br> ## 2PBR and 2PBR2 Power Blocks Model 2PBR actually requires a 4-wire connection and model 2PBR2 requires a 3- or 4-wire connection, even though they only work with 2-wire scanner blocks and logic modules. Both are powered by 120 V AC across terminals #1 and 2. The 2PBR offers an SPST "hard" relay contact between terminals #3 and 4. Model 2PBR2 is an SPDT version, with both contacts common to terminal #1: terminal #3 is a normally open output, and terminal #4 is normally closed. These configurations allow MULTI-BEAM sensors to directly interface large loads which draw more than 3/4 amp like clutches, brakes, large contactors, and small motors. Model 2PBR can switch both AC and DC loads; model 2PBR2 switches the AC line voltage to an AC load (see connection diagrams). The 2PBR and 2PBR2 also eliminate the problem of voltage drop from series strings of sensors operating lowvoltage AC loads. Install an appropriate value MOV (metal oxide varistor) transient suppressor across the power block relay contacts when switching an AC inductive device. **==> picture [500 x 182] intentionally omitted <==** **----- Start of picture text -----**<br> Functional Schematic<br>Connections<br>L1 L2 1 3 A<br>V ac<br>on<br>V ac/dc off<br>CR<br>Load<br>No Connection B<br>3 4 CR<br>2 4<br>1 2 +6 V dc<br>C<br>+<br>− Common<br>D<br>**----- End of picture text -----**<br> Continued on page 43 August 28, 2023 © Banner Engineering Corp. All rights reserved. 42 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** Continued from page 42 **==> picture [500 x 182] intentionally omitted <==** **----- Start of picture text -----**<br> Functional Schematic<br>Connections Signal from<br>L1 L2 1 3 Logic Module A<br>on<br>off<br>Load AC Supply Relay Contact5 Amp Max. Drive<br>Voltage Circuit<br>No Connection B<br>4 CR<br>3 4 Load 2<br>+6 V DC<br>C<br>1 2<br>Regulated +<br>Power Supply − Common<br>D<br>**----- End of picture text -----**<br> ## Power Block (2-Wire) General Wiring **==> picture [118 x 156] intentionally omitted <==** **----- Start of picture text -----**<br> 2-Wire MULTI-BEAMs in Parallel<br>L1 L2<br>1 2<br>1 2 Load<br>**----- End of picture text -----**<br> Multiple 2-wire MULTI-BEAMs may be wired together in parallel to a load for OR or NAND logic functions. When sensors are wired in parallel, the off-state leakage current through the load is equal to the sum of the leakage currents of the individual sensors. Consequently, loads with high resistance, like small relays and electronic circuits, may require artificial load resistors. Two-wire MULTI-BEAM sensors have a 100 ms power-up delay for protection against false outputs. When 2-wire MULTI-BEAMs are wired together in parallel, any power block with an energized output robs all the other power blocks of the current they need to operate. When the energized output drops, there will be a 0.1 second delay before any other MULTI-BEAM can energize. As a result, the load may momentarily drop out. Two-wire MULTI-BEAM sensors cannot wire in series with other 2-wire sensors unless power block model 2PBR is used. If series connection of 2-wire ac sensors is required, consider models within the VALU-BEAM or MINI-BEAM families. MULTI-BEAM 2-wire sensors wire in series with an appropriate load. This combination, in turn, wires directly across the ac line. A 2-wire sensor may be connected exactly like a mechanical limit switch. **==> picture [133 x 108] intentionally omitted <==** **----- Start of picture text -----**<br> Basic Wiring of 2-Wire MULTI-BEAM<br>L1 L2<br>1 2 Load<br>**----- End of picture text -----**<br> The MULTI-BEAM remains powered when the load is off by a residual current that flows through the load. This off-state leakage current is always less than 1 mA. The effect of this leakage current depends upon the characteristics of the load. The voltage that appears across the load in the off-state is equal to the leakage current of the sensor multiplied by the resistance of the load: Voff = 1 mA × Rload . If this resultant off-state voltage is less than the guaranteed turn-off voltage of the load, the interface is direct. If the off-state voltage causes the load to stay on, connect an artificial load resistor in parallel with the load to lower its effective resistance. Most loads, including most programmable logic controller (PLC) inputs, will interface to 2-wire sensors with 1 mA leakage current without needing an artificial load resistor. There is no polarity requirement. Either wire may connect to terminal #1 and the other to terminal #2. **==> picture [32 x 38] intentionally omitted <==** CAUTION: All three components of a MULTI-BEAM 2-wire sensor will be destroyed if the load becomes a short circuit. August 28, 2023 © Banner Engineering Corp. All rights reserved. 43 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** |2-Wire MULTI-BEAM with Series Contacts<br>L1<br>L2<br>Load<br>1<br>2|When 2-wire MULTI-BEAM sensors are connector in series with mechanical switch or relay<br>contacts, the sensor receives power to operate only when all the contacts are closed.<br>The false-pulse protection circuit of the MULTI-BEAM causes a 0.1 second delay between<br>the time that the last contact closes and the time that the load energizes.| |---|---| ## 2-Wire MULTI-BEAM with Parallel Contacts |L1<br>L2<br>Load<br>1<br>2|Two-wire MULTI-BEAM sensors may be wired in parallel with mechanical switch or relay<br>contacts. The load energizes when any of the contacts close or the sensor output is<br>energized.<br>When a contact is closed, it shunts the operating current away from the MULTI-BEAM.<br>As a result, when all the contacts are open, the MULTI-BEAM's 0.1 second power-up delay<br>may cause a momentary drop-out of the load.| |---|---| **==> picture [500 x 325] intentionally omitted <==** **----- Start of picture text -----**<br> Photoelectric Latch with Manual Reset<br>L1 L2<br>The 1CR relay will latch on whenever the 2-wire MULTI-BEAM output is energized.<br>The 1CR is reset when the normally-closed button switch is pressed.<br>Latch<br>1 2 1CR<br>1CR Reset<br>2-Wire MULTI-BEAM to Programmable<br>Logic Controller (PLC)<br>(ac “hot”) (ac neutral)<br>L1 L2 MULTI-BEAM 2-wire sensors operate with very low (1 mA) off-state leakage current. As a<br>result, they will interface directly to most PLCs without needing an artificial load resistor.<br>If the off-state voltage (1 mA × the input resistance of the PLC) is higher than the PLC<br>sensing threshold, install a 10 kOhm to 15 kOhm, 5-watt resistor for each 2-wire sensor.<br>The resistor connects between the input terminal and ac neutral.<br>If you have a question about wiring a specific brand of PLC, contact the Banner<br>Applications Department during normal business hours.<br>1 2<br>**----- End of picture text -----**<br> August 28, 2023 © Banner Engineering Corp. All rights reserved. 44 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** ## Logic Modules (2-Wire) The logic module interconnects the power block and scanner block both electrically and mechanically using a unique bladeand-socket connector concept. It also provides the LIGHT/DARK operate function (except in the LM1) and the timing functions, all of which are fully adjustable. All MULTI-BEAM 2-wire logic modules are color-coded black, and are for use only in MULTI-BEAM 2-wire sensors. The time ranges specified for the logic modules are standard time ranges. For additional time ranges, see "MULTI-BEAM 3- and 4- Wire Scanner Block Modifications" on page 18. ## Functional Schematic **==> picture [292 x 165] intentionally omitted <==** **----- Start of picture text -----**<br> Off<br>On<br>A Processed Logic Signal<br>to Power Block<br>Dark Off<br>B Signal from Light Light/Dark On<br>Scanner Block Operate Circuit<br>+8 V dc (Jumper for D.O.)<br>C<br>CW CW In<br>Timer<br>Adjustments Timer Circuit<br>+ +<br>Out<br>D<br>Common<br>**----- End of picture text -----**<br> ## Logic Module (2-Wire) Models In the table below, the signal represents the light condition (in LIGHT operate) or the dark condition (in DARK operate), and the output represents the energized condition of the solid-state output switch (power block). Delay refers to the time delay before the output operates, and hold refers to the time that the output remains on after the event has occurred. Model Function Description **on-off** The 2LM3 is an on/off logic module that has the ability to be programmed for either 2LM3 **OUTPUT** LIGHT or DARK operate. It comes with a jumper wire installed. With the jumper in place, the output is DARK operate; with the jumper removed, the output is LIGHT **SIGNAL** operate. Use the 2LM3 when no timing function is desired. **one-shot (retriggerable)** The 2LM4-2 provides a one-shot (single shot) pulse each time there is a transition **HOLD HOLD** from LIGHT to DARK (jumper installed) or from DARK to LIGHT (jumper removed). The output pulse time range is from 0.01 seconds to 1 second. The duration of the 2LM4-2 (inactive) **OUTPUT** output pulse is independent of the duration of the input signal. The timing of the 2LM4-2 restarts each time the input signal is removed and then reapplied. This is **SIGNAL** referred to as a retriggerable one-shot, and this feature may be applied to some rate **Setable time range: 0.1 to 1 second.** sensing applications. **on-delay** The 2LM5 is a true on-delay logic module. The input signal must be present for a **DELAY** predetermined length of time before the output is energized. The output then remains energized until the input signal is removed. If the input signal is not present 2LM5 **OUTPUT** for the predetermined time period, no output occurs. If the input signal is removed momentarily and then reestablished, the timing function starts over again from the **SIGNAL** beginning. The standard time range is 0.15 seconds to 15 seconds (field adjustable), and other ranges are available. **Setable time range: 1.5 to 15 seconds.** Continued on page 46 August 28, 2023 © Banner Engineering Corp. All rights reserved. 45 MULTI-BEAM Sensors Family ## Continued from page 45 Model Function Description **off-delay** The 2LM5R us an off-delay logic module, similar to the 2LM5, except that timing **HOLD HOLD** begins on the trailing edge of the input signal. When the input occurs, the output is immediately energized; if the input is then removed, the output remains energized 2LM5R **OUTPUT** for the adjustable predetermined time period, then de-energizes. If the input is mune ine removed but then reestablished while the timing is holding the output energized, a **SIGNAL** kk mn new output cycle is begun. The LIGHT/DARK operate jumper wire option is included. Timing range is 0.15 seconds to 15 seconds, and optional ranges are available. **Setable time range: 1.5 to 15 seconds. on- & off-delay** The 2LM5-14 combines the function of an on-delay and an off-delay into one logic **DELAY HOLD** module. When the signal is present for more than the output on-delay time, the output energizes. The off-delay circuit is now active, and holds the output on even if 2LM5-14 **OUTPUT** = the input signal disappears for short periods of time. If the input signal is gone for **SIGNAL** it longer than the off-delay time, the output finally drops out. The time delays can control high and low levels in flow control applications. Each delay is independently **Setable time range: 1.5 to 15 seconds.** adjustable for 0.15 seconds to 15 seconds. **limit timer** The 2LM5T limit timer combines the function of on/off logic and on-delay logic. As **HOLD** long as the signal is present for only short periods of time, the output follows the action of the input signal. If the input signal is present for longer than the 2LM5T (inactive) **OUTPUT** -_—_ predetermined time, the output de-energizes. The output re-energizes only when the **SIGNAL** yt input signal is removed and then reestablished. Interval timers are used to operate loads which must not run continuously for long periods of time, such as intermittent duty solenoids and conveyor motors. Timing range is 0.15 seconds to 15 seconds. **Setable time range: 1.5 to 15 seconds.** Model LMT is a plug-in test logic module for use in troubleshooting MULTI-BEAM sensors. It contains LED indicator lights in place of the timing potentiometers and a miniature switch in place of the LIGHT/DARK operate jumper. The indicator lights display the operation of the scanner block and power block to verify proper LMT Test Logic functioning, and the switch permits manual operation of the load to verify the output switching circuit. The step-by-step testing procedure included with the LMT allows a 6 je MULTI-BEAM to be completely tested without removing it from the installation, and if there is a faulty scanner block, power block, or logic module, the LMT identifies it. August 28, 2023 © Banner Engineering Corp. All rights reserved. 46 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** ## Chapter Contents Accessories and Replacement Parts for the MULTI-BEAM Family................................................................................................................... 47 Banner Engineering Corp Limited Warranty...................................................................................................................................................... 49 Contact Us......................................................................................................................................................................................................... 49 ## Chapter 4 ## Product Support ## Accessories and Replacement Parts for the MULTI-BEAM ## Family An upper cover consists of the optical element for the MULTI-BEAM that is built into a gasketed cover for the upper portion of the scanner block. Upper covers may be ordered as replacement parts or for modifying the optical response of a particular model scanner block. The following upper cover assemblies are standard and stocked. Other special variations may be quoted. Stainless steel hardware is included with each cover. ## Upper covers **==> picture [500 x 225] intentionally omitted <==** **----- Start of picture text -----**<br> Model Description<br>UC-C 1.5 inch (38 mm) focus, glass lenses<br>UC-C4 4 inch (10 cm) focus, glass lenses<br>UC-C6 6 inch (15 cm) focus, glass lenses<br>UC-D Flat vinyl lens for short range and/or wide beam angle.<br>Used on: SBD1 SBED SBRD1 SBEXD SBRXD1 2SBD1<br>UC-DMB MB = Modified with Baffle; for short-range proximity mode with SBDX1.<br>Used on SBDX1MD<br>UC-F Fits all Banner fiberoptic assemblies.<br>Used on: SBF1, SBF1MHS, SBFX1, SBFV1, 2SBF1.<br>UC-EF For fiberoptic emitter-only scanner blocks.<br>Used on: SBEF SBEXF<br>UC-RF For fiberoptic receiver-only scanner blocks.<br>Used on: SBRF1 SBRXF1 SBAR1GHF<br>Used on: SBE SBEV SBEX SBR1 SBRX1 SBL1 SBLV1, SBLX1, SBDL1, SBDX1, SBAR1, SBAR1GH, 2SBR1, 2SBL1,<br>UC-L<br>2SBDX1, 3GA5-14, EM3T-1M, R1T3<br>UC-LAG Anti-glare (polarizing) filter for retroreflective sensing of shiny objects.<br>Used on SBLVAG1<br>**----- End of picture text -----**<br> Special upper covers used in special sensing environments **==> picture [500 x 62] intentionally omitted <==** **----- Start of picture text -----**<br> Model Description<br>UC-DJ Identical to UC-D, but with addition of plastic dust cover to prevent accumulation of dust/dirt in lens area.<br>UC-LJ Adds plastic dust cover to UC-L. Used when sensor is mounted facing up (used to prevent dust/dirt buildup on lens).<br>UC-LG Replaces UC-L in sensing locations where highly caustic materials are present (e.g. acid vapor or splash). Glass lens.<br>**----- End of picture text -----**<br> ## Lower covers for all MULTI-BEAM scanner blocks **==> picture [500 x 55] intentionally omitted <==** **----- Start of picture text -----**<br> Model Description<br>LCMB Standard replacement cover for all scanner blocks. Includes gaskets and four stainless steel mounting screws.<br>LCMBMTA "MTA" = Modified Timing Access. Gasketed nylon screw covers for logic module timing adjustments. Includes gaskets and<br>four stainless steel mounting screws.<br>**----- End of picture text -----**<br> Mounting brackets August 28, 2023 © Banner Engineering Corp. All rights reserved. 47 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** - SMB700 • Right-angle mounting bracket • 11 gauge zinc-plated steel • 70 mm wide by 60 mm deep x 60 mm high • Includes a cable gland assembly and lock washer ## SMB700SS - Right-angle mounting bracket - • 11 gauge stainless steel • 70 mm wide by 60 mm deep x 60 mm high **==> picture [59 x 64] intentionally omitted <==** **==> picture [59 x 64] intentionally omitted <==** - SMB700F • Flat mounting bracket • 11 gauge stainless steel • 70 mm x 110 mm ## SMBLS - Two-part bracket assembly that allows adjustment in three directions - Two 11-gauge zinc-plated steel right-angle brackets that fasten together so that they rotate relative to each other - • The MULTI-BEAM wiring base attaches to the upper bracket and slots are provided for vertical adjustment - • The bottom bracket is a modified version of the SMB700. Assembly hardware and a cable gland are included ## SMB700M - Heavy-duty 1/4-inch (6mm) zinc-plated steel bracket - Allows the MULTI-BEAM to retrofit to installations of MLS8 or MLS9 sensors - • Includes cable gland and lock washer ## SMB700P - Heavy duty 1/4-inch (6mm) zinc-plated steel bracket - Allows the MULTI-BEAM to retrofit to installations of 42RLU and 42RLP sensors - • Includes cable gland and lock washer **==> picture [54 x 68] intentionally omitted <==** ## RF1-2NPS - Cable gland assembly for MULTI-BEAMs - • Includes cord grips for 0.1 to 0.4-inch diameter cable • Bracket lock washer is also included ## MBC-4 and MBCC-412 - MBC-4 is a 4-pin male industrial-duty connector that threads into the base of all MULTI-BEAMs - MBCC-412 is a 12-foot long (3.6 m) "SJT" type cable that is interchangeable with standard industry types of several different manufacturers August 28, 2023 © Banner Engineering Corp. All rights reserved. 48 MULTI-BEAM Sensors Family **==> picture [57 x 57] intentionally omitted <==** ## Banner Engineering Corp Limited Warranty Banner Engineering Corp. warrants its products to be free from defects in material and workmanship for one year following the date of shipment. Banner Engineering Corp. will repair or replace, free of charge, any product of its manufacture which, at the time it is returned to the factory, is found to have been defective during the warranty period. This warranty does not cover damage or liability for misuse, abuse, or the improper application or installation of the Banner product. THIS LIMITED WARRANTY IS EXCLUSIVE AND IN LIEU OF ALL OTHER WARRANTIES WHETHER EXPRESS OR IMPLIED (INCLUDING, WITHOUT LIMITATION, ANY WARRANTY OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE), AND WHETHER ARISING UNDER COURSE OF PERFORMANCE, COURSE OF DEALING OR TRADE USAGE. This Warranty is exclusive and limited to repair or, at the discretion of Banner Engineering Corp., replacement. IN NO EVENT SHALL BANNER ENGINEERING CORP. BE LIABLE TO BUYER OR ANY OTHER PERSON OR ENTITY FOR ANY EXTRA COSTS, EXPENSES, LOSSES, LOSS OF PROFITS, OR ANY INCIDENTAL, CONSEQUENTIAL OR SPECIAL DAMAGES RESULTING FROM ANY PRODUCT DEFECT OR FROM THE USE OR INABILITY TO USE THE PRODUCT, WHETHER ARISING IN CONTRACT OR WARRANTY, STATUTE, TORT, STRICT LIABILITY, NEGLIGENCE, OR OTHERWISE. Banner Engineering Corp. reserves the right to change, modify or improve the design of the product without assuming any obligations or liabilities relating to any product previously manufactured by Banner Engineering Corp. Any misuse, abuse, or improper application or installation of this product or use of the product for personal protection applications when the product is identified as not intended for such purposes will void the product warranty. Any modifications to this product without prior express approval by Banner Engineering Corp will void the product warranties. All specifications published in this document are subject to change; Banner reserves the right to modify product specifications or update documentation at any time. Specifications and product information in English supersede that which is provided in any other language. For the most recent version of any documentation, refer to: www.bannerengineering.com. For patent information, see www.bannerengineering.com/patents. ## Contact Us Banner Engineering Corp. headquarters is located at: 9714 Tenth Avenue North | Minneapolis, MN 55441, USA | Phone: + 1 888 373 6767 For worldwide locations and local representatives, visit www.bannerengineering.com. August 28, 2023 © Banner Engineering Corp. All rights reserved. 49 ## LinkedIn Twitter Facebook © 2023. All rights reserved. www.bannerengineering.com
Updated at June 9, 2026
Founded in 1966, Banner Engineering is a globally recognized leader in the design and manufacture of industrial automation products. The company is renowned for developing innovative, high-quality solutions that improve operational efficiency, safeguard personnel, and optimize manufacturing processes across a diverse range of industries. Our extensive selection of Banner Engineering components prominently features their industry-leading sensing technologies. We offer a comprehensive array of precision light sensors engineered for accurate detection and measurement in demanding environments. Complementing this core sensing portfolio is a robust offering of automation signaling devices, including visual signal indicator units and essential accessories, which provide clear and immediate communication of machine status. Beyond primary sensing and indication solutions, our range encompasses critical components for broader process control and machine safety. This includes advanced process controllers, reliable pressure sensors and transducers, and dependable safety relays. Supported by a variety of purpose-built sensor accessories and fiber optic lead assemblies, Banner Engineering delivers the durable, high-performance technologies required to build and maintain sophisticated automated systems.
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