OMNI-BEAMTM Sensor Heads The Sensing Component of OMNI-BEAM Modular Photoelectric Sensors OMNI-BEAM Features * Sensor heads feature Banner's D.A.T.A.TM (Display And Trouble Alert) indicator system* which warns of an impending sensing problem before a failure occurs * 10-element LED array displays sensing contrast and received signal strength and warns of a sensing problem due to any of the following causes: - Severe condensation or moisture - High temperature - Low supply voltage - Output overload (dc operation) - Too much sensing gain - Not enough sensing gain - Low optical contrast * Separate indicators for target sensed and output energized * Sensor heads are field-programmable for the following response parameters: - Sensing hysteresis - Signal strength indicator scale factor - Light or dark operate of the load output - Normally open or closed alarm output * Choose power blocks for high-voltage ac or low-voltage (10 to 30V) dc operation * Sensor head and power block plug (and bolt) together quickly and easily * Optional plug-in output timing modules may be added at any time *U.S. Patent 4965548 OMNI-BEAM Overview Modular Design OMNI-BEAM is a modular self-contained sensor. It is made up of a sensor head and a power block; an optional plug-in timing logic module may be added easily. The three modular components, sold separately, simply plug and bolt together -- without interwiring -- to create a complete self-contained photoelectric sensor tailored to a particular application's exact sensing requirements. Figure 1. OMNI-BEAM sensor head and power block bolt and plug together quickly and easily; an optional timing logic module may be added at any time. ! WARNING . . . The sensor lenses and modular components are all field-replaceable. OMNI-BEAM's modular design makes change-out of any component quick and easy. Not To Be Used for Personnel Protection Never use these products as sensing devices for personnel protection. Doing so could lead to serious injury or death. These sensors do NOT include the self-checking redundant circuitry necessary to allow their use in personnel safety applications. A sensor failure or malfunction can cause either an energized or de-energized sensor output condition. Consult your current Banner Safety Products catalog for safety products which meet OSHA, ANSI and IEC standards for personnel protection. Printed in USA P/N 03522A9E OMNI-BEAM Sensor Heads Sensor Heads A sensor head module is available for every sensing situation. Sensor heads bolt directly onto the power block, and are fully gasketed for protection against environmental elements. The D.A.T.A. self-diagnostic feature is standard on all OMNIBEAM sensor heads (except emitters and model OSBFAC). Select from most sensing modes, with infrared or visible red, green or blue sensing beams available. Figure 2. OMNI-BEAM sensor heads are available for most sensing modes, including fiber optic models. OMNI-BEAM Sensor Head Models Model Sensing Mode OSBE Opposed emitter OSBR Opposed receiver OSBLV Non-polarized retroreflective Light Source Infrared, 880 nm OSBLVAG Polarized retroreflective Visible red 650 nm OSBLVAGC Polarized retroreflective, clear object detection Visible red 650 nm OSBD Short-range diffuse OSBDX Long-range diffuse Infrared, 880 nm Convergent Repeatability 2 ms 0.01 ms 4 ms 0.2 ms 4 m (12') 4 ms 0.2 ms 300 mm (12") 2 ms 0.1 ms 2 m (6.5') 15 ms 1 ms 38 mm (1.5") Focus 4 ms 0.2 ms Range varies with fiber optics used 2 ms 0.1 ms 0.15 to 9 m (6' to 30') 0.3 to 4.5 m (12" to 15') Visible green, 525 nm Visible blue, 475 nm OSBCVB Infrared, 880 nm OSBF OSBFVG 45 m (150') Response Visible red, 650 nm OSBCV OSBCVG Range Glass fiber optic -high speed Visible green, 525 nm Visible blue, 475 nm OSBFVB OSBFV Glass fiber optic -high speed Visible red, 650 nm Range varies with fiber optics used 2 ms 0.1 ms OSBFX Glass fiber optic -high power Infrared, 880 nm Range varies with fiber optics used 15 ms 1 ms OSBEF Glass fiber optic emitter OSBRF Glass fiber optic receiver Infrared, 880 nm Range varies with fiber optics used 2 ms 0.01 ms OSBFAC Glass fiber optic -ac-coupled Infrared, 880 nm Range varies with fiber optics used 1 ms 0.01 ms Range varies with fiber optics used 2 ms 0.1 ms OSBFP OSBFPG OSBFPB Visible red, 650 nm Plastic fiber optic Visible green, 525 nm Visible blue, 475 nm NOTE: See pages 9 and 10 for Excess Gain and Beam Pattern curves. page 2 OMNI-BEAM Sensor Heads Power Blocks The power block determines the sensor operating voltage and also the sensor output switch configuration. Models are available with a built-in 2 m (6.5') or 9 m (30') cable, or with either Mini-style or Euro-style quick-disconnect ("QD") plug-in cable fittings. Emitter power blocks have no output circuitry. OMNI-BEAM Power Blocks Figure 3. OMNI-BEAM power blocks provide the input and output circuitry for OMNI-BEAM sensor heads. Select models for either ac or dc power. Models Supply Voltage Cable Output Type DC Voltage (see data sheet p/n 03532 packed with the power block) OPBT2 OPBT2QD OPBT2QDH 2 m (6.5') 4-Pin Mini QD 4-Pin Euro QD OPBTE OPBTEQD OPBTEQDH 2 m (6.5') 4-Pin Mini QD 4-Pin Euro QD Bi-ModalTM NPN/PNP Two outputs: Load and Alarm 10-30V dc No output: for powering emitter only sensor heads AC Voltage (see data sheet p/n 03531 packed with the power block) OPBA2 OPBA2QD 2 m (6.5') 5-Pin Mini QD 105-130V ac OPBB2 OPBB2QD 2 m (6.5') 5-Pin Mini QD 210-250V ac 0PBAE OPBAEQD 2 m (6.5') 5-Pin Mini QD 105-130V ac OPBBE OPBBEQD 2 m (6.5') 5-Pin Mini QD 210-250V ac SPST solid-state ac relay Two outputs: Load and Alarm No output: for powering emitter only sensor heads NOTE: 9 m (30') cables are availabe by adding the suffix "w/30" to the model number of any cabled power block (for example, OPBT2 w/30). Optional Timing Logic Modules Timing logic may be added at any time, using one of three timing delay and pulse logic modules. Installation is simple and quick; the logic modules simply slide into the sensor head (see Figure 4). Program them for timing functions and ranges via four DIP switches; each module includes easily accessible 15-turn clutched potentiometers for accurate timing adjustments. OMNI-BEAM Timing Logic Modules (see data sheet p/n 03533 packed with the module) Models Figure 4. OMNI-BEAM optional timing logic modules Type Logic Function Timing Ranges OLM5 ON-Delay: 0.01 to 1 sec, 0.15 to 15 sec, or none Delay Timer ON-DELAY or OFF-DELAY Logic Module or ON/OFF DELAY OFF-Delay: 0.01 to 1 sec, 0.15 to 15 sec, or none OLM8 Pulse Timer Logic Module ONE-SHOT pulse timer or DELAYED ONE-SHOT logic timer Delay: 0.01 to 1 sec, 0.15 to 15 sec, or none Pulse: 0.01 to 1 sec, 0.15 to 15 sec Pulse Timer OLM8M1 Logic Module ONE-SHOT pulse timer or DELAYED ONE-SHOT logic timer Delay: 0.002 to 0.1 sec, 0.03 to 1.5 sec, or none Pulse: 0.002 to 0.1 sec, 0.03 to 1.5 sec page 3 OMNI-BEAM Sensor Heads Sensor Head Programming DIP Switch Settings OMNI-BEAM sensor heads are field-programmable for four operating parameters. To access the four programming DIP switches (see figure 5), remove the sensor block from the power block. Switch #1, Sensing Hysteresis ON: Standard hysteresis. OFF: Low hysteresis; should be used only when all sensing conditions remain completely stable. Hysteresis is an electronic sensor requirement that the amount of received light needed to energize the sensor's output not be equal to the amount needed to release the output. This differential prevents the sensing output from "buzzing" or "chattering" when the received light signal is at or near the sensing threshold level. The standard setting should be used always, except for low-contrast applications such as the detection of subtle differences in reflectivity. Switch #2, Alarm Output Configuration ON: Alarm output is normally open (it conducts with an alarm). OFF: Alarm output is normally closed (the output opens during an alarm). Normally closed mode (OFF) is recommended; it allows a system controller to recognize a sensor power loss or an open sensor output as an alarm condition. Normally open alarm mode (ON) should be used when the alarm outputs of multiple OMNI-BEAMs are wired in parallel to a common alarm or alarm input. Switch #3, Light or Dark Operate ON: Dark Operate mode; the output energizes (after a time delay, if applicable) when the received light level is less than the sensing threshold (4 or fewer D.A.T.A. lights ON). OFF: Light Operate mode; the sensor's load output energizes (after a time delay, if applicable) when the received light level is greater than the sensing threshold (5 or more D.A.T.A. lights ON). Switch #4, Scale Factor for the D.A.T.A. Signal Strength Indicator Display ON: Fine scale. OFF: Standard scale. This switch should always be OFF, except for close differential sensing situations (for example, some color registration applications, which also require the Low hysteresis setting/switch #1 OFF). Factory Settings The following are the factory program settings for OMNI-BEAM sensor head DIP switches. Switch #1: ON (Standard hysteresis) Switch #2: OFF (Normally Closed alarm output) Switch #3: OFF (Light Operate load output) Switch #4: OFF (Standard Scale Factor for signal strength display) page 4 Figure 5. OMNI-BEAM program switches Alarm N/O Dark Operate ON Standard 1 2 3 4 Fine Hysteresis Scale Low Standard OFF OFF Alarm N/C Light Operate Figure 6. OMNI-BEAM program switch configuration OMNI-BEAM Sensor Heads Using the D.A.T.A. Sensor Self-Diagnostic Feature Banner's exclusive D.A.T.A. feature warns of marginal sensing conditions, usually before a sensing failure occurs, by flashing one or more lights in its multiple-LED array, and by sending a warning signal to the system logic controller (or directly to an audible or visual alarm). The chart below describes the meanings of the possible signals. Figure 6. OMNI-BEAM D.A.T.A. LEDs Flashing LED Problem Description #1 Moisture Alert Severe moisture is inside the sensor head, caused by condensation or by entry of moisture when the access cover is removed. #2 High Temperature Alert The temperature inside the sensor head exceeds +70C (+158F). #3 Low Voltage or Overload Alert Sensor supply voltage is below the minimum specified for the power block in use. Power block outputs also shut down to prevent damage to the load(s) from low voltage. DC power blocks OPBT2, OPBT2QD, or OPBT2QDH: Either the load output or the alarm output is shorted. Both outputs will be inhibited, and the circuit will "retry" the outputs every 1/10 second. The outputs automatically reset and function normally when the short is corrected. High Gain Warning The "dark" signal never goes below #4 on the display; decrease the Gain setting. There are two possible causes: 1) The "dark" signal slowly increases and remains at the #4 level for a predetermined delay time, commonly caused by a gradual increase of unwanted background reflections in reflective sensing modes (such as diffuse or convergent). The alarm will reset as soon as the cause of the unwanted light signal is removed, or if the Gain control setting is reduced to bring the "dark" condition below the #4 level. 2) The "dark" signal does not fall below the #4 level during a sensing event. The alarm automatically resets when the "dark" sensing level falls below the #4 level (accomplished by reducing the Gain control setting and/or by removing the cause of unwanted light return in the "dark" condition). Low Gain Warning The "light" signal never goes above #5 on the display; increase the Gain setting. There are two possible causes: 1) The "light" signal slowly decreases to the #5 level and remains at that level for a predetermined delay. This most commonly occurs in opposed or retroreflective sensing systems, caused by a gradual decrease in light in the unblocked condition, due to obscured lenses or sensor misalignment. The alarm will reset when the light signal strength exceeds the #5 level. 2) The "light" signal does not exceed the #5 level during a sensing event. The alarm automatically resets when the "light" signal exceeds the #5 level (accomplished by increasing the GAIN control setting and/or cleaning the lens and realigning the sensor). Low Contrast Warning The lights flash simultaneously to indicate inadequate optical contrast for reliable sensing (the "light" condition is at the #5 level and the "dark" condition is at the #4 level). If this occurs, re-evaluate the application to find ways to increase the differential between the "light" and "dark" conditions. The alarm automatically resets when the "light" signal exceeds the #5 level and the "dark" signal falls below the #4 level. #9 #10 #9 and #10 page 5 OMNI-BEAM Sensor Heads Sense and Load LED Indicators The Sense LED indicates when a target has been sensed. When the sensor head is programmed for Light Operate, it lights when the received light signal exceeds the #5 threshold. When programmed for Dark Operate, it lights when the received light signal falls below the #5 threshold. See figure 7. The Load indicator LED lights whenever the output is energized (after the timing function, if applicable). Measuring Excess Gain Figure 7. Sense and Load indicators OMNI-BEAM's D.A.T.A. indicator display may be used to measure the excess gain and contrast during sensing, installation, or maintenance. Excess gain is a measurement of the amount of light energy falling on a photoelectric sensor's receiver, over and above the minimum amount needed to operate the sensor's amplifier. Excess gain is expressed as a ratio: Excess gain (E.G.) = light energy falling on receiver amplifier threshold The amplifier threshold is the point at which the sensor's output switches (corresponding to the #5 level of the D.A.T.A. display). When LEDs #1 through #5 are ON, the excess gain of the received light signal is equal to "1x." The chart below shows how excess gain relates to the D.A.T.A. light array indication. Relationship Between Excess Gain and D.A.T.A System Lights D.A.T.A. Light LED Number #1 #2 #3 #4 #5 #6 #7 #8 #9 #10 page 6 STANDARD Scale Factor 0.25x Excess Gain 0.35x Excess Gain 0.5x Excess Gain 0.7x Excess Gain 1.0x Excess Gain 1.3x Excess Gain 1.7x Excess Gain 2.2x Excess Gain 2.9x Excess Gain 3.7x Excess Gain (or more) FINE* Scale Factor 0.5x Excess Gain 0.7x Excess Gain 0.8x Excess Gain 0.9x Excess Gain 1.0x Excess Gain 1.1x Excess Gain 1.2x Excess Gain 1.3x Excess Gain 1.7x Excess Gain 2.2x Excess Gain (or more) OMNI-BEAM Sensor Heads Measuring Sensing Contrast Contrast is the ratio of the amount of light falling on the receiver in the "light" state, compared to the "dark" state (sometimes called "light-to-dark ratio"). Optimizing the contrast in any sensing situation increases the sensing reliability. Contrast may be calculated if excess gain values are known for both the light and dark conditions: Contrast = Excess gain (light condition) Excess gain (dark condition) Figure 8. Dark condition example: D.A.T.A. system LEDs #1 and #2 lit. To determine the contrast for any sensing application, present both the Light and Dark conditions to the OMNI-BEAM, and note how many LEDs in the D.A.T.A. display are ON for each condition. Compute the ratio from the corresponding excess gain numbers (from the chart on page 6) for the two conditions. For example, if LEDs #1 through #8 come ON in the Light condition and LEDs #1 and #2 come ON in the Dark condition (assuming Standard scale factor), contrast is calculated as follows: Light condition: 2.2x excess gain Dark condition: 0.35x excess gain Contrast = 2.2x = 6 0.35x This value is expressed as 6:1 ("six-to-one"). The best sensor adjustment will cause all ten D.A.T.A. LEDs to come ON for the Light condition, and none in the Dark condition. In this situation (such as an application in which a box breaks the beam of an opposed-mode emitter/receiver pair): Figure 9. Light condition example: D.A.T.A. system LEDs #1 through #8 lit. Contrast is greater than 3.7x = 15 0.25x While it is not always possible to adjust a sensor to maintain this much contrast, it is important to always adjust for the maximum possible contrast. The D.A.T.A. feature makes this easy. The chart below gives general guidelines for contrast values. Contrast Values and Corresponding Guidelines Contrast Recommendation 1.2 or Less Unreliable. Evaluate alternative sensing schemes. 1.2 to 2 Poor Contrast. Use the LOW hysteresis setting and the FINE scale factor. 2 to 3 Low Contrast. Sensing environment must remain perfectly clean and all other sensing variables must remain stable. 3 to 10 Good Contrast. Minor sensing system variables will not affect sensing reliabilty. 10 or Greater Excellent Contrast. Sensing should remain reliable as long as the sensing system has enough excess gain for operation. page 7 OMNI-BEAM Sensor Heads OMNI-BEAM Sensor Head Specifications Supply Voltage and Current Supplied by OMNI-BEAM power block Output Response Time See individual sensing heads for response times (page 2) 200 millisecond delay on power-up: outputs are non-conducting during this time. Adjustments OMNI-BEAM sensor heads are field-programmable for four operating parameters. A set of four programming DIP switches is located at the base of the sensor head and is accessible with the sensor head removed from the power block (see page 4). Switch #1 selects the amount of sensing hysteresis Switch #2 selects the alarm output configuration Switch #3 selects LIGHT operate (switch #3 OFF) or DARK operate (switch #3 ON) Switch #4 selects the STANDARD (switch #4 OFF) or FINE (switch #4 ON) scale factor for the D.A.T.A. light signal strength indicator array 15-turn slotted brass screw Gain (sensitivity) adjustment potentiometer (clutched at both ends of travel) Indicators Sense and Load indicator LEDs are located on the top of the sensor head on either side of the D.A.T.A. array. Sense LED indicates when a target has been sensed Load LED lights whenever the load output is energized Also, Banner's exclusive D.A.T.A. sensor self-diagnostic system located on the top of the sensor head warns of marginal sensing conditions usually before a sensing failure occurs (except on model OSBFAC). Construction Sensor heads are molded of rugged reinforced thermoplastic polyester; top view window is LEXAN(R) polycarbonate; acrylic lenses; stainless steel hardware Environmental Rating Meets NEMA standards 1, 2, 3, 3S, 4, 12, and 13; IEC IP66 when assembled to power block Operating Temperature Temperature: -40 to +70C (-40 to +158F) Maximum relative humidity: 90% at 50C (non-condensing) Certifications LEXAN(R) is a registered trademark of General Electric Company OMNI-BEAM Dimensions - Sensor Head Shown Assembled to Power Block OMNI-BEAM Sensor with Attached Cable Transparent Cover (Gasketed) View: D.A.T.A. Lights Sensing Status Output Load Remove to Access: Sensitivity (Gain) Adjustment Logic Timing Adjustments OMNI-BEAM Sensor with Quick Disconnect Mini-Style Euro-Style 54.6 mm* (2.15") 44.5 mm (1.75") Lens Centerline #10 Screw Clearance (4) Cross-hole design for front, back, or side mounting 38.1 mm w/DC (1.50") 60.5 mm w/AC (2.38") 57.4 mm w/DC (2.26") 79.8 mm w/AC (3.14") 5.6 mm (0.22") 76.2 mm w/DC Power Block (3.00") Internal Thread (1/2-14NPSM) External Thread Hex Nut Supplied M30 X 1.5 7.1 mm (0.28") 98.6mm w/AC Power Block (3.88") 7.1 mm (0.28") 30.0 mm (1.18") 2 m ( 6.5' Cable) page 8 30.0 mm (1.18") Mini-style QD Connector 14 mm (0.6") * 61.7 mm (2.43") for OSBCV, CVG, CVB 60.5 mm (2.38") for OSBF, FV, FVG, FVB, FX, EF, RF, FAC 59.8 mm (2.35") for OSBFP, FPG, FPB Euro-style QD Connector 15 mm (0.6") OMNI-BEAM Sensor Heads Excess Gain Curves OSBE & OSBR OSBLV (Opposed) G A I N OSBE & OSBR E X C E S S Opposed Mode 100 G A I N 10 1 0.1 m 0.33 ft 1m 3.3 ft 10 m 33 ft OSBLV 100 With BRT-3 Reflector 10 G A I N .10 m .33 ft 1.0 m 3.3 ft 100 10 G A I N 1.0 m 3.3 ft 10 mm .4 in 100 mm 4 in Opposed Mode 100 IT23S Fibers G A I N IT13S Fibers 100 mm 4 in 100 1000 E X C E S S Opposed Mode 100 IT23S fibers 10 G A I N IT13S fibers 0.1 m 0.33 ft 1.0 m 3.3 ft 10 mm .4 in 100 mm 4 in 100 BT23S Fiber G A I N BT13S Fiber 100 mm 4.0 in 10 mm .4 in 100 mm 4 in 1000 mm 40 in OSBFVB (Diffuse) 1000 OSBFVG E X C E S S Diffuse Mode 100 10 G A I N BT23S Fiber 1.0 mm 0.04 in 10 mm 0.4 in OSBFVB Diffuse Mode 100 10 BT23S Fiber 1 0.1 mm 0.004 in 100 mm 4 in 1.0 mm 0.04 in 10 mm 0.4 in 100 mm 4 in DISTANCE OSBFP (Diffuse) 1000 OSBFP 100 E X C E S S Opposed Mode Plastic Fibers Diffuse Mode 100 PBT46U Fiber PIT46U Fibers 10 10 mm 0.4 in 10 DISTANCE OSBFP E X C E S S Convergent Mode 100 1 1 mm .04 in 1000 mm 40 in 1000 Diffuse Mode 1 1 mm 0.04 in 10 m 33 ft 1000 mm 40 in DISTANCE OSBFPG G A I N 10 PIT26U Fibers 1 1 mm .04 in 10 mm .40 in 100 mm 4.0 in 1000 mm 40 in 10 PBT26U Fiber 1 .1 mm .004 in 1 mm .04 in 10 mm .4 in DISTANCE DISTANCE OSBLVAGC: Refer to data sheet p/n 34151 OSBFV: Refer to data sheet p/n 03543 OSBEF/OSBRF: Refer to data sheet p/n 03546 OSBFAC: Refer to data sheet p/n 03553 100 mm 4 in OSBFPB (Diffuse) (Diffuse) 1000 1000 OSBFPG OSBFPB E X C E S S Diffuse Mode Plastic Fiber 100 10 PBT46U Fiber 1 .1 mm .004 in G A I N 10 (Opposed) OSBFX DISTANCE G A I N Convergent Mode OSBFP 1000 OSBFX OSBCVB E X C E S S DISTANCE (Diffuse) 1000 mm 40 in (Convergent) 100 1 0.1 mm 0.004 in 1000 mm 40 in OSBFX (Opposed) E X C E S S 100 mm 4 in 100 mm 4 in 1000 DISTANCE OSBFX 1 0.01 m 0.03 ft G A I N BT13S Fiber DISTANCE G A I N E X C E S S BT23S Fiber 10 mm .4 in 10 mm .4 in OSBCVB 1000 Diffuse Mode 1 1 mm .04 in 1000 mm 40 in 10 DISTANCE (Diffuse) 10 Diffuse Mode 100 1 1 mm .04 in 10 m 33 ft OSBFVG OSBF E X C E S S 1.0 m 3.3 ft OSBD DISTANCE 1000 10 mm .4 in .10 m .33 ft 1 1 mm .04 in 1000 mm 40 in (Diffuse) OSBF E X C E S S E X C E S S G A I N OSBF 1000 1 1 mm .04 in G A I N DISTANCE (Opposed) 10 10 OSBCVG 10 1 1 mm .04 in 10 m 33 ft OSBF G A I N W/BRT-3 Reflector 1000 Convergent Mode 100 DISTANCE E X C E S S 100 (Convergent) OSBCV E X C E S S Diffuse Mode 0.1 m 0.33 ft Retroreflective Mode OSBCVG 1000 OSBDX E X C E S S DISTANCE (Convergent) 1000 1 0.01 m 0.033 ft 1000 1 .01 m .033 ft 10 m 33 ft OSBCV (Diffuse) (Diffuse) OSBLVAG DISTANCE OSBDX G A I N E X C E S S Retroreflective Mode 1 .01 m .033 ft 100 m 330 ft OSBD P 1000 DISTANCE E X C E S S (Polarized Retroreflective) 1000 1000 E X C E S S OSBLVAG (Retroreflective) 1 mm .04 in 10 mm .4 in DISTANCE 100 mm 4 in G A I N Diffuse Mode Plastic Fiber 100 10 PBT46U Fiber 1 .1 mm .004 in 1 mm .04 in 10 mm .4 in 100 mm 4 in DISTANCE page 9 OMNI-BEAM Sensor Heads Beam Patterns OSBE & OSBR OSBLV (Opposed) OSBLVAG (Retroreflective) OSBE and OSBR OSBLV 60 in 150 mm 1000 mm 40 in 100 mm 4.0 in 500 mm 20 in 50 mm 2.0 in 1500 mm Opposed Mode 0 0 0 500 mm 20 in 50 mm 1000 mm 40 in 100 mm 1500 mm 60 in 150 mm 0 10 m 30 ft 20 m 60 ft 30 m 90 ft 40 m 120 ft 6.0 in Retroreflective Mode 0 With BRT-3 Reflector 0 50 m 150 ft 2m 6.6 ft 4m 13 ft 6m 20 ft 8m 26 ft OSBDX 7.5 mm 50 mm 2.0 in 5.0 mm 0.2 in 25 mm 1.0 in 2.5 mm 0.1 in Retroreflective Mode 0 0 25 mm 4.0 in 6.0 in OSBDX Diffuse Mode 0 0 1.0 in 2.5 mm 0.1 in 50 mm 2.0 in 5.0 mm 0.2 in 75 mm 3.0 in 7.5 mm 10 m 33 ft With BRT-3 Reflector 0 1m 3.3 ft 2m 6.6 ft 3m 10 ft 4m 13 ft 0.3 in 0 5m 16 ft 75 mm 150 mm 225 mm 300 mm 375 mm 3 in 6 in 9 in 12 in 15 in DISTANCE DISTANCE OSBCVG (Convergent) OSBCVB (Convergent) OSBCV 0.3 in 3.0 in 2.0 in OSBCV (Diffuse) (Diffuse) OSBD OSBLVAG 75 mm DISTANCE DISTANCE OSBD P (Polarized Retroreflective) (Convergent) OSBCVG OSBCVB 3.0 in 2.4 mm 0.09 in 2.4 mm 0.09 in 2.4 mm 50 mm 2.0 in 1.6 mm 0.06 in 1.6 mm 0.06 in 1.6 mm 0.06 in 25 mm 1.0 in 0.8 mm 0.03 in 0.8 mm 0.03 in 0.8 mm 0.03 in 75 mm Diffuse Mode Convergent Mode Convergent Mode 0 0 0 0 0.09 in Convergent Mode 0 0 0 0 25 mm 1.0 in 0.8 mm 0.03 in 0.8 mm 0.03 in 0.8 mm 0.03 in 50 mm 2.0 in 1.6 mm 0.06 in 1.6 mm 0.06 in 1.6 mm 0.06 in 75 mm 3.0 in 2.4 mm 0.09 in 2.4 mm 0.09 in 2.4 mm 0 0.4 m 1.25 ft 0.8 m 2.5 ft 1.2 m 3.75 ft 1.6 m 5.0 ft 0 2.0 m 6.25 ft OSBF OSBF 3 in 1.9 mm 2 in 1.3 mm 25 mm 1 in 0.65 mm IT13S 0 IT23S Diffuse Mode 0 OSBFVB (Diffuse) OSBF Opposed Mode 12.5 mm 25 mm 37.5 mm 50 mm 62.5 mm 0.50 in 1.0 in 1.5 in 2.0 in 2.5 in DISTANCE OSBFVG (Diffuse) 50 mm 0.09 in 0 DISTANCE OSBF (Opposed) 0 12.5 mm 25 mm 37.5 mm 50 mm 62.5 mm 0.50 in 1.0 in 1.5 in 2.0 in 2.5 in DISTANCE DISTANCE 75 mm 0 12.5 mm 25 mm 37.5 mm 50 mm 62.5 mm 0.50 in 1.0 in 1.5 in 2.0 in 2.5 in BT13S 0.075 in 1.8 mm 0.050 in 1.2 mm 0.025 in 0.6 mm 0 BT23S (Diffuse) OSBFVG Diffuse Mode BT23S Fiber 0 0.075 in 1.8 mm 0.050 in 1.2 mm 0.025 in 0.6 mm 0 OSBFVB 0.075 in Diffuse Mode BT23S Fiber 0.050 in 0.025 in 0 0 25 mm 1 in 0.65 mm 0.025 in 0.6 mm 0.025 in 0.6 mm 0.025 in 50 mm 2 in 1.3 mm 0.050 in 1.2 mm 0.050 in 1.2 mm 0.050 in 75 mm 3 in 1.9 mm 0.075 in 1.8 mm 0.075 in 1.8 mm 0 100 mm 200 mm 300 mm 400 mm 500 mm 4 in 8 in 12 in 16 in 20 in 0 7.5 mm 0.3 in 15 mm 22.5 mm 30 mm 37.5 mm 0.6 in 0.9 in 1.2 in 1.5 in DISTANCE OSBFX 6.0 in 100 mm 4.0 in IT23S Fibers 2.0 in 0 IT13S Fibers 15 mm 0.6 in 20 mm 0.8 in 25 mm 1.0 in 5 mm 0.2 in OSBFX 3.8 mm 2.5 mm 1.3 mm BT23S Fiber 30 mm 1.2 in 2.5 mm 15 mm 0.6 in 1.2 mm 0.10 in 0.05 in BT13S Fiber 0 25 mm 1.0 in PIT46U PIT26U 0 0.15 in Diffuse Mode Opposed Mode 0 20 mm 0.8 in OSBFP OSBFP 3.8 mm 45 mm 15 mm 0.6 in (Diffuse) 1.8 in 0.15 in Diffuse Mode 10 mm 0.4 in OSBFP (Opposed) 0 0.075 in 0 DISTANCE OSBFP (Diffuse) Opposed Mode 0 10 mm 0.4 in DISTANCE OSBFX (Opposed) 50 mm 5 mm 0.2 in DISTANCE OSBFX 150 mm 0 0.10 in 0.05 in 0 PBT26U PBT46U 0 50 mm 2.0 in 1.3 mm 0.05 in 15 mm 0.6 in 1.2 mm 0.05 in 100 mm 4.0 in 2.5 mm 0.10 in 30 mm 1.2 in 2.5 mm 0.10 in 150 mm 6.0 in 3.8 mm 0.15 in 45 mm 1.8 in 3.8 mm 0.15 in 0 0.4 m 15 in 0.8 m 30 in 1.2 m 45 in 1.6 m 60 in 2.0 m 75 in 0 25 mm 1 in DISTANCE 75 mm 100 mm 125 mm 3 in 4 in 5 in DISTANCE OSBFPG 3.0 mm 2.0 mm 0.08 in 2.0 mm 0.08 in 1.0 mm 0.04 in 1.0 mm 0.04 in 0 PBT46U 0.12 in Diffuse Mode 0 0.04 in 1.0 mm 0.04 in 2.0 mm 0.08 in 2.0 mm 0.08 in 3.0 mm 0.12 in 3.0 mm 0.12 in 8 mm 0.30 in 12 mm 0.45 in DISTANCE page 10 75 mm 100 mm 125 mm 3 in 4 in 5 in 0 7.5 mm 0.3 in 15 mm 22.5 mm 30 mm 37.5 mm 0.6 in 0.9 in 1.2 in 1.5 in DISTANCE DISTANCE OSBLVAGC: Refer to data sheet p/n 34151 OSBFV: Refer to data sheet p/n 03543 OSBEF/OSBRF: Refer to data sheet p/n 03546 OSBFAC: Refer to data sheet p/n 03553 0 PBT46U 1.0 mm 4 mm 0.15 in 50 mm 2 in OSBFPB 0.12 in Diffuse Mode 0 25 mm 1 in (Diffuse) OSBFPG 0 0 OSBFPB (Diffuse) 3.0 mm 50 mm 2 in 16 mm 0.60 in 20 mm 0.75 in 0 4 mm 0.15 in 8 mm 0.30 in 12 mm 0.45 in DISTANCE 16 mm 0.60 in 20 mm 0.75 in OMNI-BEAM Sensor Heads Accessories Mounting Brackets * 30 mm split clamp, black reinforced thermoplastic polyester * Stainless steel hardware included SMB30C SMB30UR Top 56.0 mm (2.20") 59.9 mm (2.36") 13 mm (0.5") 38.1 mm 30.0 mm (1.50") (1.18") 31.5 mm (1.24") 2.5 mm (0.10") o38.1 mm (1.50") 76.2 mm (3.00") 23.1 mm (0.91") Nut Plate 45.0 mm (1.77") 60 8X #10-32 63.0 mm (2.48") 13.5 mm (0.53") * Rugged stainless steel construction * Swivel mount SMB30UR 2X o7.1 (0.28") 15.2 mm (0.60") 15.2 mm (0.60") 57.1 mm (2.25") 27.9 mm (1.11") 31.8 mm (1.25") M5 x 0.8 x 80 mm Screw (2) 3.4 mm (0.14") SMB30SC * Compact 30 mm swivel bracket * Excellent range of articulation 82.2 mm (3.24") SMB30UR Bottom 31.8 mm (1.75") 50.8 mm (2.00") 6X 1/4-28 50.8 mm (2.00") o57.2 (2.25") 12.7 mm (0.50") 50.8 mm (2.00") 25.4 mm (1.0") 70.0 mm (2.75") 22.4 mm (0.88") 58.7 mm (2.31") 30.0 mm (1.18") 9.7 mm (0.38") 66.5 mm (2.62") SMB30MM 90 31.8 mm (1.25") 5X 7.1 mm (0.28") 66.0 mm (2.6") 89.8 mm (3.54") 9.7 mm (0.38") 12.7 mm (0.50") 25.4 mm 1.00") 29.0 mm (1.14") 77.1 mm (3.04") * 30 mm, 11-gauge stainless steel * Clearance for M6 (1/4") hardware 3.4 mm (0.14") o30.5 mm (1.20") 172.0 mm (6.77") 35.1 mm (1.38") 25.4 mm (1.00") o 6.4 mm (0.25") 2X 1/4 x 28 x 1/2" Screw 57.2 mm (2.25") 25.4 mm (1.00") 2X 1/4" Lock Washer 7.1 mm x 90 (0.28") (2 Slots) R 25.4 mm (1.00") 35.1 mm (1.38") 2X 1/4" Flat Washer 57.2 mm (2.25") 69.9 mm 76.2 mm (3.00") (2.75") page 11 OMNI-BEAM Sensor Heads Retroreflective Targets Banner offers a wide selection of high-quality retroreflective targets. See Banner Product Catalog for complete information. Replacement Lenses OMNI-BEAM lens assemblies are field-replaceable. Model OUC-C OUC-D OUC-F OUC-FP OUC-L OUC-LAG Description Replacement lens for convergent models (model suffix CV) Replacement lens for short range diffuse models (model suffix D) Replacement lens for glass fiber optic models (model suffix F, FAC, FV, FX, EF, and RF) Replacement lens for plastic fiber optic models (model suffix FP) Replacement lens for non-polarized retroreflective and opposed models (model suffix DX, LV, E and R) Replacement lens for polarized retroreflective models (model suffix LVAG and LVAGC) Cable Protector Model Description * Flexible black nylon cable protector HF1-2NPS * Includes a neoprene gland that compresses around the OMNI-BEAM cable to provide an additional seal against moisture * Resistant to gasoline, alcohol, oil, grease, solvents and weak acids * Working temperature range of -30 to +100C (-22 to +212F) WARRANTY: Banner Engineering Corporation warrants its products to be free from defects for one year. Banner Engineering Corporation will repair or replace, free of charge, any product of its manufacture found to be defective at the time it is returned to the factory during the warranty period. This warranty does not cover damage or liability for the improper application of Banner products. This warranty is in lieu of any other warranty either expressed or implied. Banner Engineering Corp., 9714 Tenth Ave. No., Minneapolis, MN 55441 * Phone: 612.544.3164 * Fax: 612.544.3213 * E-mail: sensors@baneng.com