SM2A312LVQD

MINI-BEAM® AC Voltage Series Sensor Datasheet Self-contained photoelectric sensors • • • • 24 to 240 V AC with solid-state outputs Signal strength or output indicator 2 m or 9 m integral cable, Micro-style quick-disconnect fitting 18 mm threaded lens mount on some models 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 deenergized (off) output condition. Models Model1 Sensing Mode SMA31E Opposed Emitter SM2A31R Opposed Receiver SMA31EL Opposed Emitter - Long Range SM2A31RL Opposed Receiver - Long Range SMA31EPD Opposed Emitter Clear Plastic Detection 0 to 300 mm (0 to 12 in) SM2A31RPD Opposed Receiver Clear Plastic Detection Actual range varies, depending upon the light transmission properties of the plastic material being sensed. SM2A312LV Non-Polarized Retroreflective 5 m (15 ft) SM2A312LVAG Polarized Retroreflective 50 mm to 2 m (2 in to 7 ft) SM2A312LP Extended-Range Polarized Retroreflective 10 mm to 3 m (0.4 in to 10 ft) SM2A312D SM2A312DBZ SM2A312W Diffuse Divergent Diffuse Range 3 m (10 ft) Infrared, 880 nm 30 m (100 ft) 300 mm (12 in) 16 mm (0.65 in) Focus 43 mm (1.7 in) Focus 16 mm (0.65in) Focus SM2A312CV2 43 mm (1.7 in) Focus SM2A312CVG 16 mm (0.65 in) Focus SM2A312F SM2A312FV SM2A312FP Glass Fiber Optic Infrared, 880 nm 130 mm (5 in) SM2A312C2 Convergent Visible red, 650 nm 380 mm (15 in) SM2A312C SM2A312CV LED Infrared, 880 nm Visible red, 650 nm Visible green, 560 nm Infrared, 880 nm Range varies, depending on sensing mode and fiber optics used. Plastic Fiber Optic Visible red, 650 nm 1 Standard 2 m (6.5 ft) cable models are listed. • To order the 9 m (30 ft) cable model, add the suffix “W/30” (for example, SMA31E W/30). • To order the 3-pin Micro-style QD model, add the suffix “QD” (for example, SMA31EQD). Original Document 69942 Rev. G 3 September 2020 69942 MINI-BEAM® AC Voltage Series Sensor Overview 1. Adjustment Indicator Device (AID) 2. Gain (sensitivity) adjustment screw 3. Light/dark operate select switch 1 Adjust clockwise for light operate (outputs conduct when sensing light is received) and counterclockwise for dark operate (outputs conduct when sensing light is not received). 2 3 Installation Instructions Wiring Diagrams The output type for all models is SPST solid-state 2-wire. Emitters with Attached Cable All Other Models with Attached Cable 1 3 Key 1. Brown 3. Blue 1 24–240 V ac 3 Emitters with Quick Disconnect (3-pin Micro-Style) 24–240 V ac Load All Other Models with Quick Disconnect (3-pin Micro-Style) rd/bk rd/wh rd/bk 24-240V ac gn rd/wh 24-240V ac Load gn Mount the Device 1. If a bracket is needed, mount the device onto the bracket. 2. Mount the device (or the device and the bracket) to the machine or equipment at the desired location. Do not tighten the mounting screws at this time. 3. Check the device alignment. 4. Tighten the mounting screws to secure the device (or the device and the bracket) in the aligned position. Sensor Alignment Note: Follow proper electronic shock discharge (ESD) precautions when adjusting the Gain potentiometer or the LO/DO switch. Note: When turning the Light/Dark Operate Select switch, be careful not to damage the small tabs on the switch. 1. Using line-of-sight, position the MINI-BEAM sensor to its emitter (opposed-mode sensing) or to its target (all other sensing modes). When using a retroreflective sensor, the target is the retroreflector (“retro target”). For diffuse or convergent sensing modes, the target is the object to be detected. 2 www.bannerengineering.com - Tel: + 1 888 373 6767 P/N 69942 Rev. G MINI-BEAM® AC Voltage Series Sensor 2. Apply power to the sensor (and to the emitter, if using the opposed mode). 3. Using a small, flat-blade screwdriver, turn the 15-turn Gain control to maximum (the clockwise end of rotation). The Gain control is clutched at both ends to avoid damage, and will “free-wheel” when either endpoint is reached. If the MINI-BEAM sensor is receiving its light signal, the red LED Alignment indicator is ON and flashing at a rate proportional to the signal strength (a faster flash rate = more signal). 4. Move the sensor (or move the retro target, if applicable) up-down-right-left, including angular rotation, to find the center of the movement zone within which the LED indicator remains ON. Reducing the Gain setting reduces the size of the movement zone and enables more precise alignment. 5. Repeat the alignment motions after each Gain reduction. 6. When optimum alignment is achieved, mount the sensor, and the emitter or retro target, if applicable, securely in that position. 7. Increase the Gain to maximum. 8. Test the sensor by placing the object to be detected in the sensing position, then removing it. The Alignment indicator LED turns ON when the sensing beam is established (Light condition), and turns OFF when the beam is broken (Dark condition). If the Alignment indicator LED stays ON for both sensing conditions, see the following tips for each sensing mode. Opposed Mode Alignment jec Ob Emitter Flooding occurs when a portion of the sensing beam passes around the object to be sensed. Burn-through occurs when a portion of the emitter’s light energy passes through a thin or translucent object, and is sensed by the receiver. To correct either problem, do one or more of the following to reduce the light energy: • Reduce the Gain adjustment on the receiver • Add an aperture to one or both lenses (MINI-BEAM apertures, available from Banner, fit neatly inside the lens assembly) • Intentionally misalign the emitter and receiver t Receiver Note: • • Light condition: sensor output is ON when there is no object in the beam Dark condition: sensor output is ON when there is an object in the beam Diffuse Mode Alignment t jec Ob If the Alignment LED does not go OFF when the object is removed from the beam, the sensor is probably detecting light reflected from some background object. To remedy this problem: • Reduce the reflectivity of the background by painting the surface(s) flat-black, scuffing any shiny surface, or drilling a large hole, directly opposite the diffuse sensor • Move the sensor closer to the object to be detected and reduce the Gain adjustment. Rule of thumb for diffuse sensing: The distance to the nearest background object should be at least three times the sensing distance Note: • • P/N 69942 Rev. G www.bannerengineering.com - Tel: + 1 888 373 6767 Light condition: sensor output is ON when there is no object in the beam Dark condition: sensor output is ON when there is an object in the beam 3 MINI-BEAM® AC Voltage Series Sensor Retroreflective Mode Alignment A highly reflective object may reflect enough light back to a retroreflective sensor to allow that object to slip through the beam, without being detected. This problem is called proxing, and the following methods may be used to correct it: • Position the sensor and retro target so the beam will not strike a shiny surface perpendicular to the sensor lens • Reduce the Gain adjustment • Add a polarizing filter (for model SM2A312LV) tro Re t e g r Ta Note: • • Light condition: sensor output is ON when there is no object in the beam Dark condition: sensor output is ON when there is an object in the beam Convergent Mode Alignment The sensing energy of a convergent mode sensor is concentrated at the specified focus point. Convergent mode sensors are less sensitive to background reflections, compared with diffuse mode sensors. However, if background reflections are a problem: • Skew the sensor position at a 10° to 25° angle to eliminate direct reflections from shiny background surfaces • Reduce the reflectivity of the background by painting the surface(s) flat-black, scuffing any shiny surface, or drilling a large hole, directly opposite the sensor • Reduce the Gain adjustment w Lo vity ti flec ound e R gr ck a B t jec Ob Note: • • Light condition: sensor output is ON when there is no object in the beam Dark condition: sensor output is ON when there is an object in the beam Installing the Glass Fibers in MINI-BEAMs Retaining Clip O-ring 1. Install the O-ring (supplied with the fiber) on each fiber end, as shown in the drawing. 2. While pressing the fiber ends firmly into the ports on the sensor front, slide the U-shaped retaining clip (supplied with the sensor) into the slot in the sensor's barrel, until it snaps into place. 4 www.bannerengineering.com - Tel: + 1 888 373 6767 P/N 69942 Rev. G MINI-BEAM® AC Voltage Series Sensor Installing Plastic Fibers on a MINI-BEAM Follow these instructions to install plastic fibers into your sensor. MINI-BEAMS may have either a fiber gripper or a clamp screw. MINI-BEAM and ECONO-BEAM sensors for use with plastic fiber optic assemblies include sensors with the letters FP in their model number. MINI-BEAM "FP1" Sensor Gripper Unlock Lock Adapters for 0.25- and 0.5-mm fibers Trimmed fiber control ends Sensor Face Slide Fibers & Bushings into Ports Sensor Face Plastic fiber Receiver port Fiber Bushings (supplied with fiber) Tighten Clamp Screw to Secure Fiber Plastic fiber Emitter port 0.25" Unterminated Plastic Fibers Figure 1. MINI-BEAM with fiber grippers Figure 2. MINI-BEAM with clamp screws 1. Prepare the sensor ends of the fibers (see Cut the Plastic Fiber on p. 5). 2. Prepare the sensor for the fibers. • For models with a fiber gripper: Unlock the fiber gripper as shown in the figure and apply the appropriate fiber adaptors to the fiber, if needed. • For models with a clamp screw: Loosen the clamp screw on the sensor face. 3. Insert the plastic fibers. • For models with a fiber gripper: Gently insert the prepared fiber ends into the ports as far as they will go. • For models with a clamp screw: Align the fiber ends flush with the ends of the bushings as shown. Hold the bushings to the fibers and slide both into the sensor ports. Push the fiber an additional 1 inch through the bushing. 4. Lock in the fibers. • For models with a fiber gripper: Slide the fiber gripper back to lock, as shown in the figure. • For models with a clamp screw: Tighten the clamp screw to secure the fibers. Cut the Plastic Fiber An unterminated plastic fiber is designed to be cut by the customer to the length required for the application. To facilitate cutting, a Banner model PFC-4 cutting device is supplied with this fiber. 1. Locate the non-terminated end, and determine the length of fiber required for the application. 2. Lift the top of the cutter to open the cutting ports. 3. Insert the non-terminated end through one of the four large cutting ports on the PFC-4 cutter so that the excess fiber protrudes from the back of the cutter. 4. Double-check the fiber length, and close the cutter until the fiber is cut. 5. Gently wipe the cut ends of the fiber with a clean, dry cloth to remove any contamination. Note: Do not use solvents or abrasives on any exposed optical fiber. Do not use a cutting port more than once. The blade may tend to dull after one cut. P/N 69942 Rev. G www.bannerengineering.com - Tel: + 1 888 373 6767 5 MINI-BEAM® AC Voltage Series Sensor Specifications Supply Voltage and Current 24 to 240 V AC (50/60 Hz), 250 V AC maximum Supply Protection Circuitry Protected against transient voltages Output Configuration SPST SCR solid-state relay with either normally closed or normally open contact (light/dark operate selectable); 2-wire wiring Output Rating Minimum load current 5 mA; maximum steady-state load capability 300 mA to 50 °C ambient (122 °F) 100 mA to 70 °C ambient (158 °F) Inrush capability: 3 amps for 1 second (non repetitive); 10 amps for 1 cycle (non repetitive) OFF-state leakage current: less than 1.7 mA rms ON-state voltage drop: ≤ 5 V at 300 mA load, ≤ 10 V at 15 mA load Output Protection Circuitry Protected against false pulse on power-up Output Response Time Opposed: 2 millisecond on and 1 millisecond off Non-Polarized and Polarized Retro, Convergent, and Plastic Fiber Optic: 4 milliseconds on and off Diffuse and Glass Fiber Optic: 8 milliseconds on and off OFF response time specification does not include load response of up to 1/2 ac cycle (8.3 milliseconds). Response time specification of load should be considered when important. Repeatability Opposed: 0.3 milliseconds Non-Polarized and Polarized Retro, Convergent, and Plastic Fiber Optic: 1.3 milliseconds Diffuse and Glass Fiber Optic: 2.6 milliseconds Response time and repeatability specifications are independent of signal strength. Indicators Red indicator LED on rear of sensor is ON when the load is energized Construction Reinforced thermoplastic polyester housing, totally encapsulated, o-ring sealing, acrylic lenses, stainless steel screws Connections PVC-jacketed 2-conductor 2 m (6.5 ft) or 9 m (30 ft) cables, or 3-pin Microstyle QD fitting; QD cables available separately Application Notes Overload conditions can destroy ac MINI-BEAM sensors. Directly wiring sensor without load series, across hot and neutral will damage sensor (except emitter models). Low-voltage use requires careful analysis of the load to determine if the sensor’s leakage current or on-state voltage will interfere with proper operation of the load. The false-pulse protection feature may cause momentary drop-out of the load when the sensor is wired in series or parallel with mechanical switch contacts. Note: 300 millisecond delay on power-up. Required Overcurrent Protection Operating Conditions –20 °C to +70 °C (–4 °F to +158 °F) 90% at +50 °C maximum relative humidity (non-condensing) WARNING: Electrical connections must be made by qualified personnel in accordance with local and national electrical codes and regulations. Environmental Rating Meets NEMA standards 1, 2, 3, 3S, 4, 4X, 6, 12, and 13; IEC IP67 Certifications Overcurrent protection is required to be provided by end product application per the supplied table. Overcurrent protection may be provided with external fusing or via Current Limiting, Class 2 Power Supply. Supply wiring leads < 24 AWG shall not be spliced. For additional product support, go to www.bannerengineering.com. Supply Wiring (AWG) Required Overcurrent Protection (Amps) 20 5.0 22 3.0 24 2.0 26 1.0 28 0.8 30 0.5 Performance Curves for SM31Ex Emitter and SM31Rx Receiver Models 1000 SM31E & SM31R SMA31E & SM2A31R 12.0 in 200 mm Opposed Mode 8.0 in 100 mm 4.0 in 0 0 100 mm 4.0 in 200 mm 8.0 in 300 mm Opposed Mode 100 1.2 m 4 ft 1.8 m 6 ft 2.4 m 8 ft 3.0 m 10 ft Effective Beam: 3.5 mm SM31EL & SM31RL SMA31EL & SM2A31RL 30.0 in 500 mm Opposed Mode 20.0 in 10.0 in 0 10 0 250 mm 10.0 in 500 mm 20.0 in 750 mm 1 .01 m .033 ft .10 m .33 ft Distance 1.0 m 3.3 ft 10 m 33 ft Excess Gain Curve for SM31EL/RL 1000 750 mm 250 mm 12.0 in 0.6 m 2 ft Distance 6 SM31E & SM31R SMA31E & SM2A31R Excess Gain 300 mm 0 Beam Pattern for SM31EL/RL SM31EL & SM31RL SMA31EL & SM2A31RL Opposed Mode Excess Gain Excess Gain Curve for SM31E/R Beam Pattern for SM31E/R 100 10 30.0 in 0 6m 20 ft 12 m 40 ft 18 m 60 ft 24 m 80 ft 30 m 100ft Distance 1 0.1 m 0.33 ft 1.0 m 3.3 ft 10 m 33 ft 100 m 330 ft Distance Effective Beam: 13 mm www.bannerengineering.com - Tel: + 1 888 373 6767 P/N 69942 Rev. G MINI-BEAM® AC Voltage Series Sensor Performance Curves for the SM312Lx Retroreflective Models Excess Gain Curve for SM312LVxx Beam Pattern for SM312LVxx 1.0 in 0 0 25 mm 1.0 in With BRT-3 Reflector 50 mm 2.0 in 75 mm 60 mm Retroreflective Mode 100 1m 3 ft 2m 6 ft 3m 9 ft 4m 12 ft 20 mm 0.8 in 40 mm 1.6 in With BRT-3 Reflector 0 10 m 33 ft .6 m 2 ft 1.2 m 4 ft 1.8 m 6 ft 2.4 m 8 ft 100 With BRT-3 Reflector 10 2.4 in 1 .01 m 0.03 ft 3.0 m 20 ft Distance Distance 0.1 m 0.3 ft 1m 3 ft 10 m 30 ft Distance SM312LVAG SM2A312LVAG 3.0 in Retroreflective Mode 2.0 in 25 mm 1.0 in 0 0 25 mm 1.0 in 50 mm 2.0 in With BRT-3 Reflector 75 mm 1.2 m 4 ft 1.8 m 6 ft 2.4 m 8 ft Excess Gain 50 mm .6 m 2 ft 1.0 m 3.3 ft 1.6 in 1000 SM312LVAG SM2A312LVAG 0 .10 m .33 ft SM312LP SM2A312LP Retroreflective Mode 0 60 mm 1 .01 m .033 ft 5m 15 ft 2.4 in 0.8 in 0 10 Distance 75 mm 40 mm 20 mm With BRT-3 Reflector 3.0 in 0 SM312LP SM2A312LP Retroreflective Mode Excess Gain 2.0 in Retroreflective Mode 25 mm SM312LV SM2A312LV 3.0 in Excess Gain 50 mm 1000 1000 SM312LV SM2A312LV 75 mm Excess Gain Curve for SM312LP Beam Pattern for SM312LP Retroreflective Mode 100 With BRT-3 Reflector 10 3.0 in 1 .01 m .033 ft 3.0 m 10 ft Distance .10 m .33 ft 1.0 m 3.3 ft 10 m 33 ft Distance Performance Curves for the SM312Dx and SM312W Diffuse Models 1000 SM312D, SM2A312D SM312D, SM2A312D Diffuse Mode 0.6 in 10 mm 0.4 in 5 mm 0.2 in 0 0 5 mm 0.2 in 10 mm 0.4 in 15 mm 0.6 in 0 75 mm 3.0 in 150 mm 6.0 in 225 mm 9.0 in Diffuse Mode 100 Excess Gain 15 mm 1 1 mm .04 in 300 mm 375 mm 12.0 in 15.0 in Distance 0.4 in 5 mm 0.2 in 0 5 mm 0.2 in 10 mm 0.4 in 15 mm 0.6 in 0 75 mm 3.0 in 150 mm 6.0 in 225 mm 9.0 in Distance P/N 69942 Rev. G Diffuse Mode 100 mm 4 in 1000 mm 40 in 1000 15.0 mm 0.6 in 7.5 mm 0.3 in 0 7.5 mm 0.3 in 15.0 mm 0.6 in 22.5 mm 0.9 in 0 25 mm 1.0 in 50 mm 2.0 in 75 mm 3.0 in Distance SM312W SM2A312W 0.9 in 100 mm 125 mm 4.0 in 5.0 in Diffuse Mode 100 10 1 1 mm .04 in 10 mm .4 in 100 mm 4 in 1000 mm 40 in Distance 1000 SM312DBZ SM2A312DBZ 0.6 in 10 mm 0 10 mm .4 in Distance 300 mm 375 mm 12.0 in 15.0 in Diffuse Mode 100 Excess Gain SM312DBZ, SM2A312DBZ Diffuse Mode 15 mm SM312W, SM2A312W 22.5 mm 0 10 Excess Gain Curve for SM312W Beam Pattern for SM312W Excess Gain Excess Gain Curve for SM312Dx Beam Pattern for SM312Dx 10 1 1 mm .04 in 10 mm .40 in 100 mm 4.0 in 1000 mm 40 in Distance www.bannerengineering.com - Tel: + 1 888 373 6767 7 MINI-BEAM® AC Voltage Series Sensor Performance Curves for the SM312Cx Convergent Models SM312C, SM2A312C 0.15" 2.5 mm 0.10" 1.2 mm 0.05" 0 0 1.2 mm 0.05" 2.5 mm 0.10" 3.8 mm Convergent Mode 100 Excess Gain Convergent Mode 25 mm (1") 50 mm (2") 75 mm (3") 10 1.2 mm 0.05" 0 0 1.2 mm 0.05" 2.5 mm 0.10" 3.8 mm 0.15" Excess Gain 0.10" 75 mm (3") 100 mm (4") 1000 2.5 mm 50 mm (2") 10 mm (0.4") 1.0 mm 0.04" 2.0 mm 0.08" 1000 mm (40") 7.5 mm (0.3") 15 mm (0.6") Convergent Mode 2.0 mm 100 22.5 mm (0.9") 1 1 mm (0.04") Distance 10 mm (0.4") 100 mm (4") Convergent Mode SM312CV2 SM2A312CV2 0.08" Convergent Mode 0.04" 0 0.04" 2.0 mm 0.08" 3.0 mm 0.12" 0 25 mm (1") 50 mm (2") 75 mm (3") 100 10 1 1 mm (0.04") 100 mm 125 mm (5") (4") Distance Distance 1000 mm (40") 0.12" 1.0 mm 1000 mm (40") 100 mm (4") 1000 SM312CV2, SM2A312CV2 0 100 mm 125 mm (5") (4") 10 mm (0.4") Distance 1.0 mm 10 10 1 1 mm (0.04") 30 mm 37.5 mm (1.2") (1.5") Distance 3.0 mm 100 0.12" 0 SM312C2 SM2A312C2 0.15" Convergent Mode 25 mm (1") 0 Distance SM312C2, SM2A312C2 0 0.04" 3.0 mm 1 1 mm (0.04") 100 mm 125 mm (4") (5") Convergent Mode 0.08" 0 Distance 3.8 mm 2.0 mm SM312CV SM2A312CV 0.12" Convergent Mode 1.0 mm 0.15" 0 1000 SM312CV, SM2A312CV 3.0 mm Excess Gain 1000 SM312C, SM2A312C 3.8 mm Excess Gain Curve for SM312CV Beam Pattern for SM312CV Excess Gain Excess Gain Curve for SM312C Beam Pattern for SM312C 10 mm (0.4") 100 mm (4") 1000 mm (40") Distance Performance is based on a 90% reflectance white test card. Excess Gain Curve for SM312CVG Beam Pattern for SM312CVG 1000 SM312CVG, SM2A312CVG SM312CVG, SM2A312CVG 0.045 in Convergent Mode 0.80 mm 0.030 in 0.40 mm 0.015 in 0 0 0.40 mm 0.015 in 0.80 mm 0.030 in 1.20 mm Convergent Mode 100 Excess Gain 1.20 mm 10 0.045 in 0 7.5 mm 0.3 in 15 mm 0.6 in 22.5 mm 0.9 in 30 mm 1.2 in 1 1 mm .04 in 37.5 mm 1.5 in 10 mm .4 in Distance 100 mm 4 in 1000 mm 40 in Distance Performance Curves for the SM312F Glass Fiber Optic Models Diffuse Mode Opposed Mode Excess Gain Curve for SM312F Excess Gain Curve for SM312F Beam Pattern for SM312F 1000 1000 1.9 mm 1.3 mm 100 BT13S BT23S 0.65 mm 0 0.025 in 1.3 mm 0.050 in 1.9 mm 0.075 in 0 7.5 mm 0.3 in 15 mm 0.6 in 22.5 mm 0.9 in Distance 30 mm 1.2 in 37.5 mm 1.5 in Excess Gain 0.025 in 0 Diffuse Mode Glass Fibers 0.050 in 0.65 mm 8 SM312F, SM2A312F 0.075 in SM312F, SM2A312F Diffuse Mode SM312F, SM2A312F 75 mm 50 mm 1 in 0 BT13S Fiber 1 1 mm .04 in 10 mm .4 in 100 mm 4 in Distance 2 in 25 mm BT23S Fiber 10 1000 mm 40 in IT13S IT23S 0 25 mm 1 in 50 mm 2 in 75 mm 3 in 0 100 mm 4 in SM312F, SM2A312F 3 in Opposed Mode 200 mm 8 in 300 mm 12 in Distance www.bannerengineering.com - Tel: + 1 888 373 6767 400 mm 500 mm 16 in 20 in Excess Gain Beam Pattern for SM312F Opposed Mode Glass Fibers 100 IT23S Fibers w/L9 lenses 10 IT13S Fibers 1 .01 m .033 ft IT23S Fibers .1 m .33 ft 1m 3.3 ft 10 m 33 ft Distance P/N 69942 Rev. G MINI-BEAM® AC Voltage Series Sensor Diffuse Mode Excess Gain Curve for SM312FV Beam Pattern for SM312FV 1000 Diffuse Mode 0.050 in BT23S 0 0.65 mm 0.025 in 1.30 mm 0.050 in 1.95 mm 0.075 in 0 5 mm 0.2 in 10 mm 0.4 in 15 mm 0.6 in 20 mm 0.8 in 10 BT23S Fiber 25 mm 1.0 in 1 in Distance 1 mm .04 in IT13S 0 IT23S 25 mm 1 in 50 mm 2 in 75 mm BT13S Fiber 10 mm .40 in Opposed Mode 100 IT23S Fiber 10 IT13S Fiber 3 in 0 100 mm 4 in SM312FV SM2A312FV 2 in 25 mm 0 1 .1 mm .004 in 3 in Opposed Mode 50 mm 100 0.025 in BT13S Excess Gain 0.65 mm SM312FV, SM2A312FV 75 mm Excess Gain SM312FV SM2A312FV 0.075 in 1.30 mm 0 Excess Gain Curve for SM312FV Beam Pattern for SM312FV 1000 SM312FV, SM2A312FV Diffuse Mode 1.95 mm Opposed Mode 50 mm 2 in 100 mm 4 in 150 mm 6 in 1 1 mm .04 in 200 mm 250 mm 8 in 10 in Distance Distance 10 mm .40 in 100 mm 4.0 in 1000 mm 40 in Distance Performance Curves for the SM312FP Plastic Fiber Models Diffuse Mode Opposed Mode 1000 SM312FP/SM2A312FP SM312FP SM2A312FP 45 mm 2.5 mm 0.10 in 30 mm 1.2 mm 0.05 in Diffuse Mode Plastic Fibers Diffuse Mode 0 0 PBT46U PBT26U 1.2 mm 0.05 in 2.5 mm 0.01 in 3.8 mm Excess Gain 0.15 in 3.8 mm 100 PBT46U Fiber 0.015 in 0 7.5 mm 0.3 in 15 mm 0.6 in 22.5 mm 0.9 in 30 mm 1.2 in Distance 1 mm .04 in 1.2 in PIT46U PIT26U 10 mm .4 in 100 mm 4 in 0 15 mm 0.6 in 30 mm 1.2 in Opposed Mode Plastic Fibers 100 0.6 in 0 SM312FP SM2A312FP 1.8 in Opposed Mode 45 mm PBT26U Fiber 1 .1 mm .004 in 37.5 mm 1.5 in 1000 SM312FP/SM2A312FP 15 mm 10 Excess Gain Curve for SM312FP Beam Pattern for SM312FP Excess Gain Excess Gain Curve for SM312FP Beam Pattern for SM312FP PIT46U Fiber 10 PIT26U Fiber 1.8 in 0 25 mm 1 in 50 mm 2 in 75 mm 3 in 1 1 mm .04 in 100 mm 125 mm 4 in 5 in Distance Distance 10 mm .40 in 100 mm 4.0 in 1000 mm 40 in Distance Dimensions Divergent Diffuse Models Plastic Fiber Models (Suffix FP) (Suffix DBZ and W) Glass Fiber Models (Suffix F, FV) M18 x 1 x 19 mm Thread (Mounting Nut Supplied) Fiber Optic Fitting Bezel 18.0 mm (0.71") 22.3 mm (0.88") Fiber Optic Fitting 69.9 mm (2.75") 51.8 mm (2.04") P/N 69942 Rev. G 13.2 mm (0.52") 54.8 mm (2.16") 31.2 mm (1.23") 16.2 mm (0.64") www.bannerengineering.com - Tel: + 1 888 373 6767 9 MINI-BEAM® AC Voltage Series Sensor Cabled Models (Suffix E, EL, EPD, R, RL, RPD, LV, LVAG, LP, D, C, C2, CV, CV2, and CVG ) 3.2 mm (0.13") QD Models 12.2 mm (0.48") 30.7 mm (1.21") ø 3 mm Clearance (2) 24.1 mm (0.95") M18 x 1 x 15 mm Thread (Mounting Nut Supplied) 12 mm Thread Quick-disconnect 20.0 mm (0.79”) 2 m (6.5') Cable Mounting Peg (ø 6.3 mm x 2.5 mm) 19.1 mm (0.75") 66.0 mm (2.60") 27.4 mm (1.08") Accessories Quick Disconnect Cordsets — AC Sensors 3-Pin Micro-Style Cordsets Model Length MQDC-306 2 m (6.56 ft) MQDC-315 5 m (16.40 ft) MQDC-330 9 m (29.53 ft) Style Dimensions Pinout (Female) 42 Typ. Straight MQDC-306RA 1.83 m (6 ft) MQDC-315RA 4.57 m (15 ft) 1/2-20 UNF-28 ø 14.5 32 Typ MQDC-330RA 1 = Green 2 = Red/Black 3 = Red/White 28 Typ Right-Angle 9.14 m (30 ft) 1/2-20 UNF-28 ø 14.5 Mounting Brackets SMB46L • Right-angle • L bracket • 14-ga. 316 stainless steel Hole center spacing: A = 16.0 SMB46S • Right-angle • S bracket • 14-ga. 316 stainless steel 54 65 Hole center spacing: A = 16.0 Hole size: A = 16.5 × 18.7 27 10 A Hole size: A = 16.5 × 18.7, B = 34.0 × 10.0 www.bannerengineering.com - Tel: + 1 888 373 6767 27 65 16 54 A B P/N 69942 Rev. G MINI-BEAM® AC Voltage Series Sensor SMB46U • Right-angle • U bracket for sensor protection • 14-ga. 316 stainless steel 70 B 54 Hole center spacing: A = 16.0 Hole size: A = 16.5 × 18.7, B = 34.0 × 13.0 A 65 SMB18A • Right-angle mounting bracket with a curved slot for versatile orientation • 12-ga. stainless steel • 18 mm sensor mounting hole • Clearance for M4 (#8) hardware 30 C A 41 B 46 Hole center spacing: A to B = 24.2 Hole size: A = ø 4.6, B = 17.0 × 4.6, C = ø 18.5 SMB18AFA.. • Protective, swivel bracket with tilt and pan movement for precision adjustment • Easy sensor mounting to extruded rail T-slots • Metric and inch size bolts available • Mounting hole for 18 mm sensors 44 51 ø18.1 3/8-16 UNC X 2 in. SMB18Q • Right-angle flanged bracket • 18 mm sensor mounting hole • 12-ga. stainless steel 46 A 41 B ø19.8 51 C 30 Hole size: B = ø 18.1 Model Bolt Thread (A) SMB18AFA 3/8 - 16 × 2 in SMB18AFAM10 M10 - 1.5 × 50 SMB18SF • 18 mm swivel bracket with M18 × 1 internal thread • Black thermoplastic polyester • Stainless steel swivel locking hardware included Hole center spacing: A to B = 24.2 Hole size: A = ø 4.6, B = 17.0 × 4.6, C = ø 19.0 51 B 42 25 A SMB18UR • 2-piece universal swivel bracket • 300 series stainless steel • Stainless steel swivel locking hardware included • Mounting hole for 18 mm sensor C A 137 B 64 Hole center spacing: A = 36.0 Hole size: A = ø 5.3, B = ø 18.0 SMB312PD • Right-angle mounting bracket with a curved slot for versatile orientation • 12-ga. stainless steel • 18 mm sensor mounting hole • Clearance for M4 (#8) hardware 42 Hole center spacing: A = 25.4, B = 46.7 Hole size: B = 6.9 × 32.0, C = ø 18.3 A 46 B 41 32 SMBAMS18RA • Right-angle SMBAMS series bracket with 18 mm hole • Articulation slots for 90+° rotation • 12-ga. (2.6 mm) cold-rolled steel C Hole center spacing: A to B = 24.2 Hole size: A = ø 4.6, B = 17 × 4.6, C = ø 18.5 40 C 48 A B 45 Hole center spacing: A = 26.0, A to B = 13.0 Hole size: A = 26.8 × 7.0, B = ø 6.5, C = ø 19.0 Note: Not for use with plastic fiber optic sensors P/N 69942 Rev. G www.bannerengineering.com - Tel: + 1 888 373 6767 11 MINI-BEAM® AC Voltage Series Sensor SMBAMS18P • Flat SMBAMS series bracket with 18 mm hole • Articulation slots for 90+° rotation • 12-ga. (2.6 mm) cold-rolled steel SMB30SK • Flat-mount swivel bracket with extended range of motion • Black reinforced thermoplastic polyester and 316 stainless steel • Stainless steel swivel locking hardware included C 78 A 68 A B 57 78 B 45 Hole center spacing: A = 50.8 Hole size: A = ø 7, B = ø 18 Hole center spacing: A = 26.0, A to B = 13.0 Hole size: A = 26.8 × 7.0, B = ø 6.5, C = ø 19.0 SMB3018SC • 18 mm swivel side or barrelmount bracket • Black reinforced thermoplastic polyester • Stainless steel swivel locking hardware included 67 B 59 29 67 B 58 29 A Hole center spacing: A = 50.8 Hole size: A = ø 7.0, B = ø 18.0 A Hole center spacing: A = 50.8, B = 24.1 Hole size: A = ø 7, B = ø 7.6 SMB312S • SMB30SUS • Side-mount swivel with extended range of motion • Black reinforced thermoplastic polyester • Stainless steel swivel locking hardware included SMB312B B Stainless steel 2-axis, sidemount bracket 46 C • • Stainless steel 2-axis, bottom-mount bracket Includes mounting foot A 24 A 32 20 51 23 B C A = diam. 6.9, B = 4.3 × 10.5, C = 3.1 × 15.2 A = 4.3 × 7.5, B = diam. 3, C = 3 × 15.3 Miscellaneous Accessories and Replacement Parts MINI-BEAM lens assemblies are field-replaceable. Replacement Lens for MINI-BEAM Model Possible Sensing Mode or Range Changes LVAG LV to LVAG UC-300BZ W and DBZ D to DBZ and F to DBZ UC-300C..7 C, CV, and CVG CV2 to CV UC-300C2 C2 and CV2 CV to CV2 Replacement Lens Model UC-300AG UC-300E E and R - UC-300EL EL and RL Extends the range of the E/R models EPD - UC-300EPD UC-300F F and FV D to F and DBZ to F UC-300FP FP (old style) - UC-300FP2 FP - LV and D F to D, LVAG to LV, and DBZ to D LP - RPD - UC-300L UC-300LP UC-300RPD MINI-BEAM right-angle reflectors are useful for tight sensing locations. These reflectors significantly decrease excess gain. 12 www.bannerengineering.com - Tel: + 1 888 373 6767 P/N 69942 Rev. G MINI-BEAM® AC Voltage Series Sensor Right-Angle Reflectors RAR300SM • Side mount right-angle reflector • Profile dimension of 14 mm (0.56 inches) in the direction of the scan • Use with MINI-BEAM models 31E, EL, R, RL; and 312D, DBZ, LV, W 30.48 mm [1.2”] 55.7 mm [2.2”] 45° 42.4 mm [1.67”] 12.7 mm [0.5”] 24.13 mm [0.95”] 3.18 mm dia [0.125”] RAR300FM • Front mount right-angle reflector that attaches directly to the threaded barrel of most MINIBEAMs • Profile dimension of 34 mm (1.35 inches) in the direction of the scan • Use with MINI-BEAM models 31E, EL, R, RL; and 312D, LV 30.5 mm [1.2”] 24.13 mm [0.95”] 37.6 mm [1.48”] 45° 4.45 mm [0.18”] dia 3.18mm (2) [0.125’”] 17.5 mm [0.69”] 32.5 mm [1.28”] Opposed-mode MINI-BEAM sensors may be fitted with apertures that narrow or shape the effective beam of the sensor to more closely match the size or profile of the object to be sensed, for example, the use of “line” (or “slit”) apertures for sensing wire or thread. Each model contains 20 apertures. MINI-BEAM Opposed-Mode Aperture Kits Model Description Qty AP31-020 0.5 mm dia. 20 AP31-040 1.0 mm dia. 20 AP31-100 2.5 mm dia. 20 Circular Horizontal Slot AP31-020H 0.5 x 6.4 mm 20 AP31-040H 1.0 x 6.4 mm 20 AP31-100H 2.5 x 6.4 mm 20 AP31-200H 5.1 x 6.4 mm 20 AP31-020V 0.5 x 12.7 mm 20 AP31-040V 1.0 x 12.7 mm 20 AP31-100V 2.5 x 12.7 mm 20 AP31-200V 5.1 x 12.7 mm 20 Vertical Slot Kit AP31-DVHX2 2 of each aperture 2 Range (Standard Group I and II Sensor Pairs) Aperture on Both Emitter and Received Aperture on Receiver Only Aperture Range (Group I Sensor Pairs with UC-300EL Upper Covers Substituted) Group I Sensors Group II Sensors Group I Sensors Group II Sensors Aperture on Both Emitter and Received Aperture on Receiver Only AP31-020 89 mm 102 mm 457 mm 1.5 m 127 mm 914 mm AP31-040 330 mm 457 mm 940 mm 3.2 m 183 mm 2m 1.5 m 3m 2.5 m 8.2 m 2.1 m 5.8 m AP31-020H AP31-100 406 mm 1.8 m 965 mm 9.1 m 864 mm 3.4 m AP31-040H 914 mm 4m 1.8 m 12.5 m 1.8 m 5.2 m AP31-100H 2.3 m 10.4 m 2.9 m 20.7 m 5.2 m 8.5 m AP31-200H 2.8 m 21.3 m 3m 24.4 m 8.2 m 11 m AP31-020V 457 mm 1.7 m 1m 8.2 m 1m 3.4 m AP31-040V 1m 5.5 m 1.8 m 15.8 m 2.1 m 5.5 m AP31-100V 2.3 m 10.7 m 2.9 m 22.9 m 6.1 m 8.5 m AP31-200V 2.8 m 22.9 m 3m 25.9 m 8.5 m 11 m GROUP I Emitter/ Receiver Pairs (see Range): SMA31E/SM2A31R GROUP II Emitter/ Receiver Pairs (see Range): SMA31EL/SM2A31RL P/N 69942 Rev. G www.bannerengineering.com - Tel: + 1 888 373 6767 13 MINI-BEAM® AC Voltage Series Sensor Example: A MINI-BEAM sensor pair is in Group I. With an AP31-040 circular aperture on the receiver only, range is 940 mm (37 in). With AP31-040 apertures on both emitter and receiver, range is 330 mm (13 in). Group I range with AP31-040 apertures and UC-300EL upper covers on both units is 183 mm; range with receiver aperture only is 2 m (80 in). 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. © Banner Engineering Corp. All rights reserved