| Angle of radiation | 3 ° |
| Range | 5,000 mm |
| Adjustment options | Manual adjustment |
Throughbeam photoelectric sensors
Through-beam photoelectric sensors are measuring devices used to detect the movement and speed of objects. They consist of a transmitter and a receiver located on opposite sides of a measuring path. When the object passes the sensing section, it interrupts the light beam between the transmitter and receiver, generating a signal that is processed by an electronic circuit.
Through-beam photoelectric sensors can be used in a wide variety of industrial, commercial and leisure applications. They can be used to measure the speed of vehicles or the movement of people. Through-beam photoelectric sensors can also be used to automatically control plant or machinery by transmitting the signal to a control unit.
Modern through-beam sensors often use digital displays and can be linked to other systems, such as an automatic control system, to optimise the production process and improve efficiency.
Through-beam photoelectric sensors are a simple and cost-effective method of measuring movement and speed and can be used in many applications.
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Through-beam photoelectric sensors can be used in a wide variety of industrial, commercial and leisure applications. They can be used to measure the speed of vehicles or the movement of people. Through-beam photoelectric sensors can also be used to automatically control plant or machinery by transmitting the signal to a control unit.
Modern through-beam sensors often use digital displays and can be linked to other systems, such as an automatic control system, to optimise the production process and improve efficiency.
Through-beam photoelectric sensors are a simple and cost-effective method of measuring movement and speed and can be used in many applications.
... Read more
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| Angle of radiation | 25 ° |
| Response time | 5 to 8,000 ms |
| Range | 300 mm |
| Angle of radiation | 15 ° |
| Response time | 5 to 8,000 ms |
| Range | 30,000 mm |
| Angle of radiation | 3 ° |
| Response time | 5 to 8,000 ms |
| Range | 60,000 mm |
| Angle of radiation | 2 ° |
| Response time | 5 to 8,000 ms |
| Range | 20,000 mm |
| Angle of radiation | 15 ° |
| Response time | 5 to 8,000 ms |
| Range | 30,000 mm |
| Angle of radiation | 10 ° |
| Response time | 5 to 8,000 ms |
| Range | 500 mm |
| Angle of radiation | 25 ° |
| Response time | 5 to 8,000 ms |
| Range | 300 mm |
| Angle of radiation | 15 ° |
| Response time | 5 to 8,000 ms |
| Range | 15,000 mm |
| Angle of radiation | 4 ° |
| Response time | 5 to 8,000 ms |
| Range | 7,000 mm |
| Angle of radiation | 2 ° |
| Response time | 5 to 8,000 ms |
| Range | 15,000 mm |
| Angle of radiation | 3 ° |
| Response time | 5 to 8,000 ms |
| Range | 60,000 mm |
| Angle of radiation | 3 ° |
| Response time | 5 to 8,000 ms |
| Range | 15,000 mm |
| Angle of radiation | 15 ° |
| Range | 30,000 mm |
| Light source/transmitted light | Infrared light |
| Angle of radiation | 3 ° |
| Response time | 5 to 8,000 ms |
| Range | 800 mm |
| Angle of radiation | 15 ° |
| Response time | 5 to 8,000 ms |
| Range | 10,000 mm |
| Angle of radiation | 20 ° |
| Range | 10,000 mm |
| Light source/transmitted light | Infrared light |
| Angle of radiation | 2 ° |
| Response time | 5 to 8,000 ms |
| Range | 20,000 mm |
| Angle of radiation | 3 ° |
| Response time | 5 to 8,000 ms |
| Range | 60,000 mm |
| Angle of radiation | 2 ° |
| Response time | 5 to 8,000 ms |
| Range | 20,000 mm |
Extraneous light interference/interference suppression
Extraneous light interference is an important criterion when selecting the appropriate sensor. Ambient light can have a negative effect on the function of the through-beam sensor. For this reason, suppliers also specify the immunity to ambient light(daylight/artificial light) in kLx. The direct sunlight can strongly affect the functionality. Therefore, it is important that direct sunlight does not shine on the light barrier receiver. One way to prevent direct irradiation is to shade the receiver by means of a tube. The use of an optical filter makes it possible to limit the bandwidth of the light that can be received by the photoelectric sensor receiver. Pulsing the driver current of the transmitter unit and the corresponding phase and frequency synchronicity of the receiver also offer further possibilities.
The function of throughbeam sensors can be impaired by contamination of the sensor, but also by particles in the ambient air, and may lead to malfunctions.
Light/dark switching
If the light beam between the transmitter and receiver of the throughbeam sensor is interrupted and switches the light barrier, the function is dark switching. Accordingly, the photoelectric sensor is light-switching when the receiver receives light and then switches. Sensors are also offered that can be switched between light and dark.
Application areas of through-beam sensors
One of the main application areas of through-beam sensors is long distance and detection of objects, regardless of shape, color, reflectance.
Advantages of through-beam sensors
Through-beam sensors have high functional reserves and are in principle suitable for use in harsh environmental conditions. Another advantage is the high switching speed. A minimum distance between transmitter and receiver is not required..
Extraneous light interference is an important criterion when selecting the appropriate sensor. Ambient light can have a negative effect on the function of the through-beam sensor. For this reason, suppliers also specify the immunity to ambient light(daylight/artificial light) in kLx. The direct sunlight can strongly affect the functionality. Therefore, it is important that direct sunlight does not shine on the light barrier receiver. One way to prevent direct irradiation is to shade the receiver by means of a tube. The use of an optical filter makes it possible to limit the bandwidth of the light that can be received by the photoelectric sensor receiver. Pulsing the driver current of the transmitter unit and the corresponding phase and frequency synchronicity of the receiver also offer further possibilities.
The function of throughbeam sensors can be impaired by contamination of the sensor, but also by particles in the ambient air, and may lead to malfunctions.
Light/dark switching
If the light beam between the transmitter and receiver of the throughbeam sensor is interrupted and switches the light barrier, the function is dark switching. Accordingly, the photoelectric sensor is light-switching when the receiver receives light and then switches. Sensors are also offered that can be switched between light and dark.
Application areas of through-beam sensors
One of the main application areas of through-beam sensors is long distance and detection of objects, regardless of shape, color, reflectance.
Advantages of through-beam sensors
Through-beam sensors have high functional reserves and are in principle suitable for use in harsh environmental conditions. Another advantage is the high switching speed. A minimum distance between transmitter and receiver is not required..
What are throughbeam photoelectric sensors and how do they work?
Throughbeam photoelectric sensors are sensors that are used to detect the presence or absence of an object in a specific area. They consist of a light source that emits infrared light and a receiver that detects the reflected light.
The function of a throughbeam photoelectric sensor is based on the principle of interrupting the light beam. If the object blocks the light beam between the light source and receiver, the reflected light is not detected and the receiver recognizes the presence of the object. This signal can then be used to perform a specific action, such as triggering an alarm or activating a machine part.
Throughbeam photoelectric sensors are used in various applications, such as industrial automation, the packaging industry, safety technology and robotics. They offer reliable and precise detection of objects and are easy to install and operate.
The function of a throughbeam photoelectric sensor is based on the principle of interrupting the light beam. If the object blocks the light beam between the light source and receiver, the reflected light is not detected and the receiver recognizes the presence of the object. This signal can then be used to perform a specific action, such as triggering an alarm or activating a machine part.
Throughbeam photoelectric sensors are used in various applications, such as industrial automation, the packaging industry, safety technology and robotics. They offer reliable and precise detection of objects and are easy to install and operate.
What areas of application are there for throughbeam photoelectric sensors?
Throughbeam photoelectric sensors are used in various areas. Here are some examples:
1. Industrial automation: Throughbeam photoelectric sensors are often used in industrial production to monitor the material flow. For example, they can be used to count the flow of products on a conveyor belt or to detect whether a product has reached the desired area.
2. packaging industry: Throughbeam photoelectric sensors are used in packaging machines to detect the presence or absence of products in a package. They can also be used to check whether a label has been applied correctly.
3. Building security: Throughbeam photoelectric sensors are used in security systems to detect whether people or objects are present in a certain area. For example, they can be used in automatic doors to detect whether someone is blocking the doorway.
4. Transportation systems: One-way photoelectric sensors are used in traffic signal systems and toll systems to detect whether a vehicle has passed a certain point. They can also be used to count traffic or monitor the speed of vehicles.
5. Medical devices: Through-beam photoelectric sensors are used in medical devices such as blood glucose meters or infusion pumps to monitor the correct positioning of test strips or the flow rate of liquids.
These are just a few examples of applications for throughbeam photoelectric sensors. The technology can be used in many other areas where precise detection or monitoring is required.
1. Industrial automation: Throughbeam photoelectric sensors are often used in industrial production to monitor the material flow. For example, they can be used to count the flow of products on a conveyor belt or to detect whether a product has reached the desired area.
2. packaging industry: Throughbeam photoelectric sensors are used in packaging machines to detect the presence or absence of products in a package. They can also be used to check whether a label has been applied correctly.
3. Building security: Throughbeam photoelectric sensors are used in security systems to detect whether people or objects are present in a certain area. For example, they can be used in automatic doors to detect whether someone is blocking the doorway.
4. Transportation systems: One-way photoelectric sensors are used in traffic signal systems and toll systems to detect whether a vehicle has passed a certain point. They can also be used to count traffic or monitor the speed of vehicles.
5. Medical devices: Through-beam photoelectric sensors are used in medical devices such as blood glucose meters or infusion pumps to monitor the correct positioning of test strips or the flow rate of liquids.
These are just a few examples of applications for throughbeam photoelectric sensors. The technology can be used in many other areas where precise detection or monitoring is required.
What advantages do throughbeam photoelectric sensors offer compared to other safety systems?
Throughbeam photoelectric sensors offer several advantages compared to other safety systems:
1. Simple installation: Throughbeam photoelectric sensors are relatively easy to install as they only consist of a transmitter and a receiver, which must be placed on opposite sides of the area to be monitored. No complex wiring or extensive installations are required.
2. Cost efficiency: One-way photoelectric sensors are generally more cost-effective than other security systems such as motion detectors or video surveillance cameras. They are a cost-effective solution for monitoring access points or specific areas.
3. Reliable protection: Throughbeam photoelectric sensors offer reliable protection because they are based on light. If the light signal between the transmitter and the receiver is interrupted, an alarm is triggered. This technology is very reliable and less prone to false alarms compared to other systems such as motion detectors, which can be triggered by random movements.
4. Flexibility: Throughbeam photoelectric sensors can be used in various environments, including indoor and outdoor areas. They can be installed on doors, windows, fences or other potentially vulnerable areas.
5. Versatility: Throughbeam photoelectric sensors can be used for various safety applications, such as access control, intrusion detection systems, person or object detection. They can also be used in combination with other safety systems to further improve safety.
Overall, throughbeam photoelectric sensors offer a cost-effective, reliable and versatile solution for monitoring and securing areas. They are a popular choice for businesses and private households looking to improve their security.
1. Simple installation: Throughbeam photoelectric sensors are relatively easy to install as they only consist of a transmitter and a receiver, which must be placed on opposite sides of the area to be monitored. No complex wiring or extensive installations are required.
2. Cost efficiency: One-way photoelectric sensors are generally more cost-effective than other security systems such as motion detectors or video surveillance cameras. They are a cost-effective solution for monitoring access points or specific areas.
3. Reliable protection: Throughbeam photoelectric sensors offer reliable protection because they are based on light. If the light signal between the transmitter and the receiver is interrupted, an alarm is triggered. This technology is very reliable and less prone to false alarms compared to other systems such as motion detectors, which can be triggered by random movements.
4. Flexibility: Throughbeam photoelectric sensors can be used in various environments, including indoor and outdoor areas. They can be installed on doors, windows, fences or other potentially vulnerable areas.
5. Versatility: Throughbeam photoelectric sensors can be used for various safety applications, such as access control, intrusion detection systems, person or object detection. They can also be used in combination with other safety systems to further improve safety.
Overall, throughbeam photoelectric sensors offer a cost-effective, reliable and versatile solution for monitoring and securing areas. They are a popular choice for businesses and private households looking to improve their security.
What types of throughbeam photoelectric sensors are there and what are their differences?
There are various types of throughbeam photoelectric sensors, which differ in their mode of operation and application. Here are some of the most common types:
1. Reflection light barrier: This type of photoelectric sensor combines a transmitter and receiver in one housing. The light is emitted by the transmitter and reflected by the object. The receiver detects the reflected light, and if the light beam is interrupted, a signal is triggered. This type of photoelectric sensor is well suited for applications where the object crosses the photoelectric sensor.
2. Transmitted light barrier: The transmitter and receiver are placed separately from each other. The transmitter emits the light and the receiver detects the light as it passes through the object. If the light beam is interrupted, a signal is triggered. This type of photoelectric sensor is well suited for applications where the object does not necessarily have to pass through the photoelectric sensor.
3. Fork light barrier: With this type of photoelectric sensor, the transmitter and receiver are mounted in a fork arrangement. The light is reflected back and forth between the forks. If the light is interrupted, a signal is triggered. Fork light barriers are often used in the packaging industry.
4. Laser scanner: This type of light barrier uses a laser beam instead of normal light. The laser beam is emitted in a specific pattern and detects the reflections of objects. Laser scanners are often used in industry and logistics to detect objects and carry out measurements.
The differences between the various types of throughbeam photoelectric sensors lie in their mode of operation, range, sensitivity and area of application. Depending on the requirements, selecting the right photoelectric sensor can be crucial to ensure optimum performance.
1. Reflection light barrier: This type of photoelectric sensor combines a transmitter and receiver in one housing. The light is emitted by the transmitter and reflected by the object. The receiver detects the reflected light, and if the light beam is interrupted, a signal is triggered. This type of photoelectric sensor is well suited for applications where the object crosses the photoelectric sensor.
2. Transmitted light barrier: The transmitter and receiver are placed separately from each other. The transmitter emits the light and the receiver detects the light as it passes through the object. If the light beam is interrupted, a signal is triggered. This type of photoelectric sensor is well suited for applications where the object does not necessarily have to pass through the photoelectric sensor.
3. Fork light barrier: With this type of photoelectric sensor, the transmitter and receiver are mounted in a fork arrangement. The light is reflected back and forth between the forks. If the light is interrupted, a signal is triggered. Fork light barriers are often used in the packaging industry.
4. Laser scanner: This type of light barrier uses a laser beam instead of normal light. The laser beam is emitted in a specific pattern and detects the reflections of objects. Laser scanners are often used in industry and logistics to detect objects and carry out measurements.
The differences between the various types of throughbeam photoelectric sensors lie in their mode of operation, range, sensitivity and area of application. Depending on the requirements, selecting the right photoelectric sensor can be crucial to ensure optimum performance.
How are throughbeam photoelectric sensors used in industry?
Through-beam photoelectric sensors, also known as through-beam optocouplers, are used in industry for various purposes. Here are some examples:
1. Machine safety: One-way light barriers are often used as protective devices to prevent access to hazardous areas of machinery. If someone interrupts the light beam between the transmitter and receiver, a safety mechanism is activated that stops the machine or triggers other protective measures.
2. Counters and sorters: Throughbeam photoelectric sensors can be used to count or sort products. If an object interrupts the light beam, a pulse is generated and counted. This function is used in the packaging industry, for example, to monitor the number of packaged products.
3. Position detection: Throughbeam photoelectric sensors can be used to detect the position of objects. If an object interrupts the light beam, this can be used as a signal for the presence or absence of the object. This is used in the manufacturing industry, for example, to check the correct fit of components.
4. Speed measurement: Throughbeam photoelectric sensors can also be used to measure the speed of objects. If an object interrupts the light beam and the time it takes for the object to pass the light beam is measured, the speed can be calculated. This is used in the logistics industry, for example, to monitor the speed of conveyor belts or vehicles.
These are just a few examples of the use of throughbeam photoelectric sensors in industry. As they are easy to install and use, they are widely used in many different applications.
1. Machine safety: One-way light barriers are often used as protective devices to prevent access to hazardous areas of machinery. If someone interrupts the light beam between the transmitter and receiver, a safety mechanism is activated that stops the machine or triggers other protective measures.
2. Counters and sorters: Throughbeam photoelectric sensors can be used to count or sort products. If an object interrupts the light beam, a pulse is generated and counted. This function is used in the packaging industry, for example, to monitor the number of packaged products.
3. Position detection: Throughbeam photoelectric sensors can be used to detect the position of objects. If an object interrupts the light beam, this can be used as a signal for the presence or absence of the object. This is used in the manufacturing industry, for example, to check the correct fit of components.
4. Speed measurement: Throughbeam photoelectric sensors can also be used to measure the speed of objects. If an object interrupts the light beam and the time it takes for the object to pass the light beam is measured, the speed can be calculated. This is used in the logistics industry, for example, to monitor the speed of conveyor belts or vehicles.
These are just a few examples of the use of throughbeam photoelectric sensors in industry. As they are easy to install and use, they are widely used in many different applications.
What factors should be considered when installing throughbeam photoelectric sensors?
Various factors should be taken into account when installing throughbeam photoelectric sensors:
1. Positioning: The light barrier should be positioned so that it covers the desired area. It is important that the light beams from the transmitter and receiver unit are not interrupted by obstacles such as trees, buildings or other objects.
2. Height: The height of the light barrier should be selected so that it cannot be accidentally blocked by people or animals.
3. Alignment: The transmitter and receiver units must be correctly aligned to ensure reliable detection.
4. Cable length: The cable length between the transmitter and receiver unit should be sufficient to bridge the desired distance between the two units.
5. Power supply: It is important to ensure that a reliable power supply is available for the light barrier.
6. Ambient conditions: Environmental conditions such as temperature, humidity and dust should be taken into account to ensure that the photoelectric sensor works properly in the respective environment.
7. Mounting material: Depending on the installation location and type, special mounting materials such as brackets or fastening elements may be required.
8. Commissioning and testing: After installation, the light barrier should be tested to ensure that it is working properly and generating the desired signals.
The exact requirements and recommendations may vary depending on the manufacturer and model of the throughbeam photoelectric sensor. It is therefore advisable to consult the manufacturer's installation instructions and seek professional help if necessary.
1. Positioning: The light barrier should be positioned so that it covers the desired area. It is important that the light beams from the transmitter and receiver unit are not interrupted by obstacles such as trees, buildings or other objects.
2. Height: The height of the light barrier should be selected so that it cannot be accidentally blocked by people or animals.
3. Alignment: The transmitter and receiver units must be correctly aligned to ensure reliable detection.
4. Cable length: The cable length between the transmitter and receiver unit should be sufficient to bridge the desired distance between the two units.
5. Power supply: It is important to ensure that a reliable power supply is available for the light barrier.
6. Ambient conditions: Environmental conditions such as temperature, humidity and dust should be taken into account to ensure that the photoelectric sensor works properly in the respective environment.
7. Mounting material: Depending on the installation location and type, special mounting materials such as brackets or fastening elements may be required.
8. Commissioning and testing: After installation, the light barrier should be tested to ensure that it is working properly and generating the desired signals.
The exact requirements and recommendations may vary depending on the manufacturer and model of the throughbeam photoelectric sensor. It is therefore advisable to consult the manufacturer's installation instructions and seek professional help if necessary.
What challenges can arise when using throughbeam photoelectric sensors and how are they solved?
When using throughbeam photoelectric sensors, various challenges can arise that need to be solved. Here are some examples:
1. False tripping: Throughbeam photoelectric sensors can be falsely triggered by other light sources in the vicinity, such as sunlight or lighting. To solve this problem, filters can be used to detect only the light from the light barrier. Sensitivity settings can also be adjusted to reduce the likelihood of false triggering.
2. Interference from other light barriers: If several throughbeam photoelectric sensors are placed in the vicinity, they can interfere with each other and trigger unwanted signals. To solve this problem, the light barriers can operate at different frequencies to minimize interference.
3. Ambient conditions: Throughbeam photoelectric sensors can be affected by external influences such as dust, fog or rain. To solve this problem, photoelectric sensors with special housings or covers can be used to protect them from the ambient conditions.
4. Alignment: Correct alignment of the transmitter and receiver unit is crucial for reliable operation of the throughbeam photoelectric sensor. If the alignment is not correct, this can lead to false triggering. To solve this problem, aids such as lasers can be used for alignment.
5. Cable length: When installing throughbeam photoelectric sensors, it can be difficult to determine the cable length required for connection to the control system. One possible solution is to plan for cable length reserves or to use wireless communication technologies to bypass the cable length.
These are just a few examples of the challenges that can arise when using throughbeam photoelectric sensors and how they can be solved. The solutions may vary depending on the specific application.
1. False tripping: Throughbeam photoelectric sensors can be falsely triggered by other light sources in the vicinity, such as sunlight or lighting. To solve this problem, filters can be used to detect only the light from the light barrier. Sensitivity settings can also be adjusted to reduce the likelihood of false triggering.
2. Interference from other light barriers: If several throughbeam photoelectric sensors are placed in the vicinity, they can interfere with each other and trigger unwanted signals. To solve this problem, the light barriers can operate at different frequencies to minimize interference.
3. Ambient conditions: Throughbeam photoelectric sensors can be affected by external influences such as dust, fog or rain. To solve this problem, photoelectric sensors with special housings or covers can be used to protect them from the ambient conditions.
4. Alignment: Correct alignment of the transmitter and receiver unit is crucial for reliable operation of the throughbeam photoelectric sensor. If the alignment is not correct, this can lead to false triggering. To solve this problem, aids such as lasers can be used for alignment.
5. Cable length: When installing throughbeam photoelectric sensors, it can be difficult to determine the cable length required for connection to the control system. One possible solution is to plan for cable length reserves or to use wireless communication technologies to bypass the cable length.
These are just a few examples of the challenges that can arise when using throughbeam photoelectric sensors and how they can be solved. The solutions may vary depending on the specific application.
What innovations are currently available in the field of throughbeam photoelectric sensor technology?
There are several innovations in the field of throughbeam photoelectric sensor technology. Some of them are:
1. Improved range: Manufacturers are constantly working on improving the range of throughbeam photoelectric sensors to enable reliable detection over greater distances.
2. Miniaturization: Thanks to the use of smaller and more compact components, throughbeam photoelectric sensors can be integrated into ever smaller devices, which extends their range of applications.
3. Wireless communication: Some throughbeam photoelectric sensors are now equipped with wireless communication technology so that they can send data to other devices via a wireless connection. This enables seamless integration into smart home or IoT environments.
4. Intelligent functions: Some modern throughbeam photoelectric sensors have intelligent functions such as automatic calibration, self-monitoring and fault detection. This minimizes maintenance costs and downtimes.
5. Improved energy efficiency: By using energy-efficient components and intelligent energy management, modern throughbeam photoelectric sensors are able to reduce their energy consumption and extend battery life.
6. Extended areas of application: Throughbeam photoelectric sensors are no longer only used in industry, but also in areas such as robotics, safety systems, the automotive industry and medical technology.
These innovations help to make throughbeam photoelectric sensors more effective, versatile and user-friendly than ever before.
1. Improved range: Manufacturers are constantly working on improving the range of throughbeam photoelectric sensors to enable reliable detection over greater distances.
2. Miniaturization: Thanks to the use of smaller and more compact components, throughbeam photoelectric sensors can be integrated into ever smaller devices, which extends their range of applications.
3. Wireless communication: Some throughbeam photoelectric sensors are now equipped with wireless communication technology so that they can send data to other devices via a wireless connection. This enables seamless integration into smart home or IoT environments.
4. Intelligent functions: Some modern throughbeam photoelectric sensors have intelligent functions such as automatic calibration, self-monitoring and fault detection. This minimizes maintenance costs and downtimes.
5. Improved energy efficiency: By using energy-efficient components and intelligent energy management, modern throughbeam photoelectric sensors are able to reduce their energy consumption and extend battery life.
6. Extended areas of application: Throughbeam photoelectric sensors are no longer only used in industry, but also in areas such as robotics, safety systems, the automotive industry and medical technology.
These innovations help to make throughbeam photoelectric sensors more effective, versatile and user-friendly than ever before.