| Fork depth | 114 mm |
| Fork width | 180 mm |
| Transmitted light | LED, red |
Forked photoelectric sensors
Fork sensors are measuring devices used to detect the movement and speed of objects. They consist of a fork with a transmitter and receiver facing each other.
The fork emits a light beam which is interrupted by the object to be measured. When the light beam is interrupted, the receiver generates an electrical signal that is processed by an electronic circuit. The processing of the signal enables the speed and/or position of the object to be measured.
Fork sensors are used in a wide range of applications, including industrial, commercial and leisure. They can measure the speed of conveyor belts or the movement of machine parts. Fork sensors can also be used to automatically control plant or machinery by transmitting the signal to a control unit.
Modern fork sensors often use digital displays and can be linked to other systems, such as an automatic control system, to optimise the production process and increase efficiency.
Fork sensors are a simple and effective method of measuring movement and speed and can be used in many applications.
... Read more
The fork emits a light beam which is interrupted by the object to be measured. When the light beam is interrupted, the receiver generates an electrical signal that is processed by an electronic circuit. The processing of the signal enables the speed and/or position of the object to be measured.
Fork sensors are used in a wide range of applications, including industrial, commercial and leisure. They can measure the speed of conveyor belts or the movement of machine parts. Fork sensors can also be used to automatically control plant or machinery by transmitting the signal to a control unit.
Modern fork sensors often use digital displays and can be linked to other systems, such as an automatic control system, to optimise the production process and increase efficiency.
Fork sensors are a simple and effective method of measuring movement and speed and can be used in many applications.
... Read more
61 - 80 / 545
| Fork depth | 54 mm |
| Fork width | 120 mm |
| Transmitted light | LED, red |
| Fork depth | 34 mm |
| Fork width | 30 mm |
| Transmitted light | LED, infrared |
| Fork depth | 54 mm |
| Fork width | 120 mm |
| Transmitted light | LED, red |
| Fork depth | 34 mm |
| Fork width | 30 mm |
| Transmitted light | LED, red |
| Fork depth | 17 mm |
| Fork width | 10 mm |
| Transmitted light | LED, red |
| Fork depth | 34 mm |
| Fork width | 30 mm |
| Transmitted light | LED, red |
| Fork depth | 34 mm |
| Fork width | 30 mm |
| Transmitted light | LED, red |
| Fork depth | 80 mm |
| Fork width | 120 mm |
| Transmitted light | LED, infrared |
| Fork depth | 35 mm |
| Fork width | 25 mm |
| Response time | 5 to 8,000 ms |
| Dimension (width) | 10 mm |
| Dimension (depth) | 480 mm |
| Dimension (height) | 30 mm |
| Dimension (width) | 12 mm |
| Dimension (depth) | 480 mm |
| Dimension (height) | 145 mm |
| Dimension (width) | 10 mm |
| Dimension (depth) | 480 mm |
| Dimension (height) | 40 mm |
| Dimension (width) | 12 mm |
| Dimension (depth) | 480 mm |
| Dimension (height) | 245 mm |
| Dimension (width) | 10 mm |
| Dimension (depth) | 480 mm |
| Dimension (height) | 30 mm |
| Dimension (width) | 12 mm |
| Dimension (depth) | 480 mm |
| Dimension (height) | 145 mm |
| Dimension (width) | 10 mm |
| Dimension (depth) | 480 mm |
| Dimension (height) | 45 mm |
| Dimension (width) | 10 mm |
| Dimension (depth) | 480 mm |
| Dimension (height) | 40 mm |
| Dimension (width) | 10 mm |
| Dimension (depth) | 480 mm |
| Dimension (height) | 30 mm |
| Dimension (width) | 12 mm |
| Dimension (depth) | 480 mm |
| Dimension (height) | 145 mm |
Fork light barriers are offered with different measuring principles. These are:
Capacitive
Optical
Laser
Ultrasonic
Light band
Laser forked photoelectric sensors enable the detection of the smallest parts and offer high resolution and very good immunity to ambient light.
Light/dark switching
If the light beam between the transmitter and receiver of the throughbeam photoelectric sensor is interrupted and switches the photoelectric sensor, 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.
In addition to point light sources, forked barriers are also offered that emit a band of light or ultrasonic waves. These light band fork sensors are particularly suitable for detecting faults in wires and threads.
The forked light barriers are characterized, among other things, by short response times and high resolution. Typical applications of forked photoelectric sensors include: Detection of small objects, speed measurement, ejection control, positioning tasks, counting of objects.
Capacitive
Optical
Laser
Ultrasonic
Light band
Laser forked photoelectric sensors enable the detection of the smallest parts and offer high resolution and very good immunity to ambient light.
Light/dark switching
If the light beam between the transmitter and receiver of the throughbeam photoelectric sensor is interrupted and switches the photoelectric sensor, 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.
In addition to point light sources, forked barriers are also offered that emit a band of light or ultrasonic waves. These light band fork sensors are particularly suitable for detecting faults in wires and threads.
The forked light barriers are characterized, among other things, by short response times and high resolution. Typical applications of forked photoelectric sensors include: Detection of small objects, speed measurement, ejection control, positioning tasks, counting of objects.
What are fork light barriers and how do they work?
Fork light barriers are optoelectronic sensors that are used to detect objects. They consist of a transmitter unit that emits infrared light and a receiver unit that detects the reflected light.
The function of a fork light barrier is based on the principle of interrupting the light beam. The transmitter unit generates a light beam that is detected by the receiver unit as long as no object interrupts the beam. If an object enters the area between the transmitter unit and the receiver unit and blocks the light beam, no more light is detected by the receiver unit. This leads to a change in the electrical signal generated by the receiver unit.
This change in the signal can then be recognized by a suitable evaluation system and converted into a corresponding signal. This signal can be used, for example, to control a process, to detect presence or to detect movement.
Fork light barriers are used in various applications, e.g. in automation technology, the packaging industry, conveyor technology, robotics and many other areas in which the precise detection of objects is required.
The function of a fork light barrier is based on the principle of interrupting the light beam. The transmitter unit generates a light beam that is detected by the receiver unit as long as no object interrupts the beam. If an object enters the area between the transmitter unit and the receiver unit and blocks the light beam, no more light is detected by the receiver unit. This leads to a change in the electrical signal generated by the receiver unit.
This change in the signal can then be recognized by a suitable evaluation system and converted into a corresponding signal. This signal can be used, for example, to control a process, to detect presence or to detect movement.
Fork light barriers are used in various applications, e.g. in automation technology, the packaging industry, conveyor technology, robotics and many other areas in which the precise detection of objects is required.
What are the possible applications for fork light barriers?
Fork light barriers are used in various areas to detect or count objects. Here are some possible applications for fork light barriers:
1. Industrial automation: Fork light barriers are often used in industrial automation to monitor the flow of objects on conveyor belts. They can be used to detect the start and end of a product on a conveyor belt or to check whether a product is positioned correctly.
2. packaging industry: In the packaging industry, fork light barriers are often used to count packages or to check whether they are stacked correctly. They can also be used to check the position of labels or barcodes on packaging.
3. printing industry: In the printing industry, fork light barriers are used to monitor the flow of paper or printing material. They can be used to detect whether the correct paper is loaded or to check whether the paper is correctly aligned.
4. Logistics and warehousing: Fork light barriers are used in logistics and warehousing areas to monitor the flow of goods. They can be used to detect when a pallet or container passes certain points or to count stock.
5. Traffic engineering: In traffic engineering, fork light barriers can be used to monitor the flow of traffic. They can be used to detect the passage of vehicles at a specific location or to detect the presence of vehicles at traffic lights or barriers.
6. Security systems: Fork light barriers can also be used in security systems to detect unauthorized access to secure areas. They can be used to detect when someone opens a door or window or to check whether a particular area is clear of people.
This list is not exhaustive, as there are many other possible applications for fork light barriers. They are often used where reliable and precise object detection is required.
1. Industrial automation: Fork light barriers are often used in industrial automation to monitor the flow of objects on conveyor belts. They can be used to detect the start and end of a product on a conveyor belt or to check whether a product is positioned correctly.
2. packaging industry: In the packaging industry, fork light barriers are often used to count packages or to check whether they are stacked correctly. They can also be used to check the position of labels or barcodes on packaging.
3. printing industry: In the printing industry, fork light barriers are used to monitor the flow of paper or printing material. They can be used to detect whether the correct paper is loaded or to check whether the paper is correctly aligned.
4. Logistics and warehousing: Fork light barriers are used in logistics and warehousing areas to monitor the flow of goods. They can be used to detect when a pallet or container passes certain points or to count stock.
5. Traffic engineering: In traffic engineering, fork light barriers can be used to monitor the flow of traffic. They can be used to detect the passage of vehicles at a specific location or to detect the presence of vehicles at traffic lights or barriers.
6. Security systems: Fork light barriers can also be used in security systems to detect unauthorized access to secure areas. They can be used to detect when someone opens a door or window or to check whether a particular area is clear of people.
This list is not exhaustive, as there are many other possible applications for fork light barriers. They are often used where reliable and precise object detection is required.
What advantages do fork light barriers offer compared to other sensors?
Fork light barriers offer several advantages compared to other sensors:
1. High accuracy: Fork light barriers have a precise detection function. They can detect and measure small objects with high accuracy.
2. Fast response time: Fork light barriers react very quickly to changes in the detected object. They can work in real time and enable rapid control or reaction to the detected event.
3. Simple installation: Fork light barriers are relatively easy to install and do not require complicated configuration. They can easily be placed in different locations and can be used flexibly.
4. Robustness: Fork light barriers are generally very robust and durable. They can be used in a variety of environments, including harsh or demanding conditions, without compromising performance.
5. Flexibility: Fork light barriers can be used for various applications, including object detection, flow measurement, positioning and counting. They can also be used in combination with other sensors or devices to perform complex tasks.
6. Cost savings: Fork light barriers are often inexpensive compared to other sensors. They offer good value for money and are an economical solution for many applications.
Overall, fork light barriers offer a reliable and cost-effective solution for object detection and measurement in various applications.
1. High accuracy: Fork light barriers have a precise detection function. They can detect and measure small objects with high accuracy.
2. Fast response time: Fork light barriers react very quickly to changes in the detected object. They can work in real time and enable rapid control or reaction to the detected event.
3. Simple installation: Fork light barriers are relatively easy to install and do not require complicated configuration. They can easily be placed in different locations and can be used flexibly.
4. Robustness: Fork light barriers are generally very robust and durable. They can be used in a variety of environments, including harsh or demanding conditions, without compromising performance.
5. Flexibility: Fork light barriers can be used for various applications, including object detection, flow measurement, positioning and counting. They can also be used in combination with other sensors or devices to perform complex tasks.
6. Cost savings: Fork light barriers are often inexpensive compared to other sensors. They offer good value for money and are an economical solution for many applications.
Overall, fork light barriers offer a reliable and cost-effective solution for object detection and measurement in various applications.
What types of fork light barriers are there and what are the differences between them?
There are different types of fork light barriers that can be used depending on the application and requirements. The differences between them lie mainly in the type of light source, the detection technology and the functions they offer.
1. Infrared fork light barrier: This type of light barrier uses infrared light as a light source. It is well suited for applications where high precision and high immunity to ambient light are required.
2. Laser fork light barrier: Laser light is used as the light source, which enables a more precise and longer range. Laser fork light barriers are generally more expensive than infrared fork light barriers and are used in applications where very precise detection is required.
3. LED fork light barrier: This type of light barrier uses LEDs as the light source. They are cost-effective and offer reliable detection in most applications. However, LED fork light barriers are generally less precise than the other two types.
The differences between the various types of fork light barriers also lie in the functions they can offer, such as background suppression, filtering of extraneous light or adjustment of sensitivity. These functions may vary depending on the model and manufacturer and should be selected according to the requirements of the application.
1. Infrared fork light barrier: This type of light barrier uses infrared light as a light source. It is well suited for applications where high precision and high immunity to ambient light are required.
2. Laser fork light barrier: Laser light is used as the light source, which enables a more precise and longer range. Laser fork light barriers are generally more expensive than infrared fork light barriers and are used in applications where very precise detection is required.
3. LED fork light barrier: This type of light barrier uses LEDs as the light source. They are cost-effective and offer reliable detection in most applications. However, LED fork light barriers are generally less precise than the other two types.
The differences between the various types of fork light barriers also lie in the functions they can offer, such as background suppression, filtering of extraneous light or adjustment of sensitivity. These functions may vary depending on the model and manufacturer and should be selected according to the requirements of the application.
What factors should be considered when selecting and installing fork light barriers?
The following factors should be taken into account when selecting and installing fork light barriers:
1. Area of application: It is important to clarify the purpose of the light barrier. For example, should it be used to detect objects or to record throughput times?
2. Range: The range of the light barrier should correspond to the requirements of the application. It is important to consider the maximum distance between the transmitter and receiver.
3. Ambient conditions: The ambient conditions, such as temperature, humidity, dust or vibrations, can affect the performance of the light barrier. It is important to choose a photoelectric sensor that is suitable for the specific environmental conditions.
4. Installation location: The installation location of the light barrier should be selected so that it functions optimally. Factors such as alignment, height, inclination and mounting options must be taken into account.
5. Connection options: The light barrier should have the necessary connection options to connect it to the control system or other devices.
6. Reliability and service life: The reliability and service life of the light barrier are important factors. It is advisable to choose high-quality products from reliable manufacturers.
7. Costs: The cost of the light barrier should also be taken into account. It is important to find the right balance between quality and price.
8. Security functions: Depending on the application, additional safety functions may be required, such as a muting function that allows certain objects to be ignored.
It is advisable to seek advice from a specialist to ensure that the correct photoelectric sensor is selected for the specific requirements and installed correctly.
1. Area of application: It is important to clarify the purpose of the light barrier. For example, should it be used to detect objects or to record throughput times?
2. Range: The range of the light barrier should correspond to the requirements of the application. It is important to consider the maximum distance between the transmitter and receiver.
3. Ambient conditions: The ambient conditions, such as temperature, humidity, dust or vibrations, can affect the performance of the light barrier. It is important to choose a photoelectric sensor that is suitable for the specific environmental conditions.
4. Installation location: The installation location of the light barrier should be selected so that it functions optimally. Factors such as alignment, height, inclination and mounting options must be taken into account.
5. Connection options: The light barrier should have the necessary connection options to connect it to the control system or other devices.
6. Reliability and service life: The reliability and service life of the light barrier are important factors. It is advisable to choose high-quality products from reliable manufacturers.
7. Costs: The cost of the light barrier should also be taken into account. It is important to find the right balance between quality and price.
8. Security functions: Depending on the application, additional safety functions may be required, such as a muting function that allows certain objects to be ignored.
It is advisable to seek advice from a specialist to ensure that the correct photoelectric sensor is selected for the specific requirements and installed correctly.
What challenges can arise when using fork light barriers and how can they be overcome?
Various challenges can arise when using fork light barriers. Here are some examples and possible solutions:
1. Interference due to extraneous light: Fork light barriers can be affected by extraneous light sources such as sunlight or other light sources in the vicinity. To overcome this, you can, for example, use a suitable shield or filter to filter out the extraneous light.
2. Contamination of the optics: The appearance of the fork light barrier can be impaired by dust, dirt or other impurities. It is important to carry out regular cleaning and maintenance to ensure that the light barrier functions optimally.
3. Alignment problems: Correct alignment of the transmitter and receiver units is crucial for the reliable functioning of a fork light barrier. It can be difficult to align the two units precisely. In such cases, it can be helpful to use aids such as lasers or target boards to facilitate alignment.
4. Missing or inaccurate recording: Sometimes it can happen that the fork light barrier does not detect objects correctly or provides incorrect signals. This can be due to various factors, such as reflections, absorption or occlusion. To overcome this problem, it is important to select the right photoelectric sensor for the specific application and, if necessary, make adjustments to the positioning or setting.
5. Electrical faults: Electromagnetic interference or electrical interference can impair the performance of a fork light barrier. To achieve this, it is important to install the light barrier in an environment that is as free as possible from sources of electrical interference. If necessary, appropriate shielding or filters can also be used.
It is important to note that the exact challenges and solutions may depend on the specific application and environmental conditions. It may be advisable to contact the manufacturer of the light barrier or a specialist to find an optimum solution.
1. Interference due to extraneous light: Fork light barriers can be affected by extraneous light sources such as sunlight or other light sources in the vicinity. To overcome this, you can, for example, use a suitable shield or filter to filter out the extraneous light.
2. Contamination of the optics: The appearance of the fork light barrier can be impaired by dust, dirt or other impurities. It is important to carry out regular cleaning and maintenance to ensure that the light barrier functions optimally.
3. Alignment problems: Correct alignment of the transmitter and receiver units is crucial for the reliable functioning of a fork light barrier. It can be difficult to align the two units precisely. In such cases, it can be helpful to use aids such as lasers or target boards to facilitate alignment.
4. Missing or inaccurate recording: Sometimes it can happen that the fork light barrier does not detect objects correctly or provides incorrect signals. This can be due to various factors, such as reflections, absorption or occlusion. To overcome this problem, it is important to select the right photoelectric sensor for the specific application and, if necessary, make adjustments to the positioning or setting.
5. Electrical faults: Electromagnetic interference or electrical interference can impair the performance of a fork light barrier. To achieve this, it is important to install the light barrier in an environment that is as free as possible from sources of electrical interference. If necessary, appropriate shielding or filters can also be used.
It is important to note that the exact challenges and solutions may depend on the specific application and environmental conditions. It may be advisable to contact the manufacturer of the light barrier or a specialist to find an optimum solution.
What are the current trends and developments in the field of fork light barriers?
There are currently several trends and developments in the field of fork light barriers:
1. Miniaturization: Fork light barriers are becoming smaller and more compact, which enables easy integration into various applications.
2. Greater range: Manufacturers are working on increasing the range of fork light barriers so that they can also be used in larger applications.
3. Improved precision: By using advanced technologies and algorithms, the precision of fork light barriers is continuously improved to enable accurate measurement and detection.
4. Wireless communication: Some fork light barriers now offer wireless communication options to transmit data via Bluetooth or WLAN, which makes integration and control easier.
5. Extended functionalities: New fork light barrier models offer advanced features such as background suppression, ambient light filtering or multi-channel operation to improve performance in demanding environments.
6. Industry 4.0 integration: Fork light barriers can increasingly be integrated into Industry 4.0 applications by incorporating them into a network of sensors and controllers to enable comprehensive monitoring and control.
7. Environmental friendliness: Manufacturers are increasingly focusing on energy-efficient solutions by reducing the energy consumption of fork light barriers and using alternative energy sources such as solar energy.
These trends and developments mean that fork light barriers can be used in a wide range of applications, including automation technology, the packaging industry, logistics, material handling and many other areas.
1. Miniaturization: Fork light barriers are becoming smaller and more compact, which enables easy integration into various applications.
2. Greater range: Manufacturers are working on increasing the range of fork light barriers so that they can also be used in larger applications.
3. Improved precision: By using advanced technologies and algorithms, the precision of fork light barriers is continuously improved to enable accurate measurement and detection.
4. Wireless communication: Some fork light barriers now offer wireless communication options to transmit data via Bluetooth or WLAN, which makes integration and control easier.
5. Extended functionalities: New fork light barrier models offer advanced features such as background suppression, ambient light filtering or multi-channel operation to improve performance in demanding environments.
6. Industry 4.0 integration: Fork light barriers can increasingly be integrated into Industry 4.0 applications by incorporating them into a network of sensors and controllers to enable comprehensive monitoring and control.
7. Environmental friendliness: Manufacturers are increasingly focusing on energy-efficient solutions by reducing the energy consumption of fork light barriers and using alternative energy sources such as solar energy.
These trends and developments mean that fork light barriers can be used in a wide range of applications, including automation technology, the packaging industry, logistics, material handling and many other areas.
How can fork light barriers contribute to improving processes and efficiency in industry?
Fork light barriers can help to improve processes and efficiency in industry in various ways. Here are some possibilities:
1. Precise positioning: Fork light barriers offer precise detection of objects and can be used for the exact positioning of machines or workpieces. This enables improved accuracy and efficiency in assembly and manufacturing processes.
2. Automation: Certain processes can be automated by using fork light barriers. For example, if an object interrupts the light beam, this can be used as a signal to start or stop a machine. This reduces manual intervention and increases production speed.
3. Error detection: Fork light barriers can also be used to detect faults or deviations in a process. If, for example, an object does not interrupt the expected light beam, this may indicate faulty mounting or a defective component. This allows problems to be identified and rectified at an early stage, resulting in higher quality and fewer rejects.
4. Security: Fork light barriers are often used to monitor hazardous areas in order to prevent injuries to employees. If the light beam is interrupted, this can cause the machine to stop or an alarm to be triggered. This contributes to the safety of employees and minimizes the risk of accidents.
5. Speed control: Fork light barriers can also be used to monitor the speed of objects. This is particularly useful in processes where a certain speed must be maintained in order to achieve optimum results. By using fork light barriers, deviations from the desired speed can be detected and corrected if necessary.
Overall, fork light barriers help to optimize industrial processes, increase efficiency and improve the safety of employees. They enable precise detection of objects, automate processes, detect errors at an early stage and offer a wide range of applications for improving production processes.
1. Precise positioning: Fork light barriers offer precise detection of objects and can be used for the exact positioning of machines or workpieces. This enables improved accuracy and efficiency in assembly and manufacturing processes.
2. Automation: Certain processes can be automated by using fork light barriers. For example, if an object interrupts the light beam, this can be used as a signal to start or stop a machine. This reduces manual intervention and increases production speed.
3. Error detection: Fork light barriers can also be used to detect faults or deviations in a process. If, for example, an object does not interrupt the expected light beam, this may indicate faulty mounting or a defective component. This allows problems to be identified and rectified at an early stage, resulting in higher quality and fewer rejects.
4. Security: Fork light barriers are often used to monitor hazardous areas in order to prevent injuries to employees. If the light beam is interrupted, this can cause the machine to stop or an alarm to be triggered. This contributes to the safety of employees and minimizes the risk of accidents.
5. Speed control: Fork light barriers can also be used to monitor the speed of objects. This is particularly useful in processes where a certain speed must be maintained in order to achieve optimum results. By using fork light barriers, deviations from the desired speed can be detected and corrected if necessary.
Overall, fork light barriers help to optimize industrial processes, increase efficiency and improve the safety of employees. They enable precise detection of objects, automate processes, detect errors at an early stage and offer a wide range of applications for improving production processes.