B5W-LB series Light Convergent Reflective Sensor
Light Convergent Reflective Type for Reduced Color and Material Susceptibility Reliable Detection of Shiny, Black or Transparent objects
- < Robustness of color >
Stable detection of shiny, black or transparent objects
Unaffected by backgrounds, meaning only the intended object is sensed accurately.
- < Robustness of the distance >
A wide sensing range to allow object shifting
- Robust design resistant to ambient lights
- Analog voltage output and digital output models are available
- 55 mm and 10 mm sensing distances are available
|Model||2D/3D CAD||ECAD(Download symbol,FootPrint,3DCAD)
* External site (Ultra Librarian) opens in a new window.
|Sensing method||Appearance||Size||Connecting method||Output type||Sensing distance||Operating mode||Model||Minimum number of deliverable units
|Super miniature||Connector||NPN open
|2 to 10 mm*||Light-ON||B5W-LB1112-1||1|
|Miniature||10 to 55 mm*||Light-ON||B5W-LB2112-1|
|Analog voltage output||---||B5W-LB2101-1|
* White paper
|Item||Sensing method||Light Convergent Reflective|
|Sensing distance||White paper||2 to 10 mm||10 to 55 mm|
|Black paper||3 to 8 mm||10 to 40 mm|
|Non-sensing distance (White paper)||20 mm min.||85 mm min.|
|Minimum detectable object (refernce value)||0.05 mm dia.||0.15 mm dia.|
|Differential travel||20% max.|
|Light source (wavelength)||Infrared LED (850 nm)|
|Power supply voltage||24 VDC ±10%, including 10% ripple (p-p)|
|Current consumption||15 mA max. (at 26.4 VDC)||20mA max. (at 26.4 VDC)|
|Control output||Load power supply voltage: 26.4 VDC, load current: 50 mA max.
Residual voltage; 0.8 V max. at 50 mA load current and 0.32 V at 10 mA load current,
Open collector output (NPN)
|Response time||Operate/reset: 1 ms max.|
|Ambient illumination||Incandescent lamp: 3,000 lx max., Sunlight: 10,000 lx max.|
|Ambient temperature range||Operating: -10 to +60°C, Storage: -25 to +80°C (with no icing or condensation)|
|Vibration resistance||10 to 55 Hz, 1.5-mm double amplitude for 2 h each in X, Y, and Z directions|
|Shock resistance||500 m/s2 for 3 times each in X, Y, and Z directions|
|Degree of protection||IEC IP50 (not including terminals)|
|Connecting method||Connector models|
|Weight (unit only)||Approx 1.6 g||Approx 3.4 g|
Precautions for Correct Use
- （1）Ambient light may cause the sensor to malfunction.In such case, mount the sensor at an angle that ambient light does not enter the receiver lens. Make sure that the sensor does not affected by ambient light.
- （2）Mount the sensor securely on a flat surface.
- （3）Use M3 screws to secure the sensor (use together with spring washers and 6-mm-diameter flat washers to prevent screws from loosening). Use a tightening torque of 0.54 N·m max.
- （4）Take care that nothing comes into contact with the detected part of the sensor. Damage to the sensing element will result in poor performance.
- （5）Before using the sensor, check to make sure that it has not become loose due to vibration or shock.
- （6）Analog output models have a potentiometer mounted on the PCB. This potentiometer is used for in-house processes by OMRON and should not be touched.
- （1）If there is a surge in the power supply, try connecting a Zener diode or a capacitor (with a capacitance of 0.1 to 1 μF), depending on the operating environment. Use the sensor only after confirming that the surge has been removed. We recommend use of 30 to 35 V Zener diodes for a 24 VDC power supply and 10 to 15 V Zener diodes for a 5 VDC power supply.
- （2）Do not use a small inductive load, such as a relay.
- （3）Separate the wiring for Light convergent reflective sensors from high-voltage lines or power lines. If the wiring is routed in the same conduit or duct as such lines, the Light conver- gent reflective sensors may malfunction or may be damaged by inductive interference.
- （4）For the digital type, make sure that the connectors are securely locked.
● Handling during Wiring
- （1）If a force is applied to the connection area between the ter- minal and connector by bending or pulling the cable after the wiring is completed, the connector contact part or connec- tion area with the cable may be damaged, resulting in con- tact failure. Make sure that a stress (external force) as shown in the figure below is not applied to the connection area between the terminal and connector when routing and connecting cables or harnesses.
- （2）Do not perform cord wiring when power supply voltage is applied. Doing so may result in breakage.
Light Convergent Reflective Sensor
A modulated-light type of light convergent reflective sensor is used. When designing, give proper consideration to the power supply and cable lengths used. Light convergent reflective sensors are more easily affected than the sensors with Nonmodulated Light.
Reasons for Interference from Power and Cable Length on the sensors with Modulated Light
An LED emitter is pulse-lighted to produce modulated light. A large current momentarily flows to the sensors in sync with this pulse timing. This causes a pulsating consumption current. A photoelectric sensor incorporates a capacitor with sufficient capacity, and is virtually unaffected by the pulse of the consump- tion current. With a small sensor, however, it is difficult to have a capacitor with a sufficient capacity. Accordingly, when the cable length is long or depending on the type of power source, it may become impossible to keep up with the pulse of the consumption current and operation may become unstable.
Adding a Capacitor
・Attach a capacitor of 10 μF min. to the wires as close as possi- ble to the Sensor. (Use a capacitor with a dielectric strength that is at least twice the Sensor's power supply voltage. Do not use tantalum capacitors. A short-circuit may cause the capaci- tor to ignite due to the large current flow.)
< Cable Length >
・Design the configuration so that the maximum total cable length for the Photomicrosensor with Modulated Light is 2 m.
・When using a cable longer than 2 m, attach a capacitor (e.g., an aluminum electrolytic capacitor) with a capacity of 10 μF min. to the wires. The distance between the terminal and the capacitor must be within 2 m. Make sure that the total cable length is no longer than 5 m. To use a cable length longer than 5 m, use a PLC or other means to read the sensor output and then transmit the signals using a PLC's communications.
・Although cables are capable of being extended longer than 5 m, performance is likely to be affected by noise interference from adjacent cables and other devices. Voltage drops due to the resistance of the cable material itself will also influence performance. Therefore, factors, such as the difference in voltage between the end of the cable and the sensor and noise levels, must be given full consideration.
Countermeasures for Switching Power Supplies
・Take either of the following countermeasures as required if connecting a sensor to a switching power supply.
- 1. Attach a capacitor of 10 μF min. to the wires as close as possible to the sensor. (Use a capacitor with a dielectric strength that is at least twice the sensor's power supply voltage. Do not use tantalum capacitors. A short-circuit may cause the capacitor to ignite due to the large current flow. Do not use tantalum capacitors. A short-circuit may cause the capacitor to ignite due to the large current flow.)
- 2. Connect to the 0-V line of the power source or connect to the power source via a capacitor of approximately 0.47 μF to reduce the impedance of the mounting base to prevent inductive noise from entering the mounting base. Or, con- nect by way of a capacitor (approx. 0.47 μF).
- 3. Connect the noise filter terminal (neutral terminal to ACG) of the switching power supply to the case (FG) and 0-V ter- minal of the power supply. The line connected as mentioned above should be grounded or connected to the mounting base to ensure sta- ble operation. (Recommended by power supply manufacturers.)
Countermeasures to Handle Inductive Noise
- 4. Insert a plastic insulator of approximately 10 mm between the Sensor and the mounting base.
Effects of Inductive Noise
・When there is inductive noise in the Sensor mounting frame (metal), the output of the sensor may be affected. In this case, ensure that there is no electrical potential difference between the sensor 0-V terminal and the sensor mounting frame, or put a 0.47-μF capacitor between the 0-V terminal and the frame.
< Effects when the power supply is turned ON >
An output pulse may occur when the power supply is turned ON depending on the power supply and other conditions. Use the sensor in the stable ready-for-detection state reached in 100 ms after turning on the power supply.