| Switching frequency max. | 100 Hz |
| Additional signal outputs | Contamination output |
| Switching output | PNP |
Angle light barriers
Angle sensors are optical sensors for detecting angles. They consist of a transmitter and a receiver located on opposite sides of the angle to be measured.
The transmitter generates a light signal which is directed at a reflector. The reflected light is detected by the receiver. Changing the angle between the transmitter and reflector changes the position of the reflected signal, which is detected by the receiver unit.
Angle sensors are used in many applications, including the automotive industry, robotics and navigation. They can be used to measure angles in motion systems, to control robots or to navigate vehicles.
Modern angle sensors often use digital displays and can be linked to other systems, such as automatic control, to optimise the production process and increase efficiency.
Angle sensors provide an accurate method of measuring angles in a variety of applications and can be used in a wide range of applications.
... Read more
The transmitter generates a light signal which is directed at a reflector. The reflected light is detected by the receiver. Changing the angle between the transmitter and reflector changes the position of the reflected signal, which is detected by the receiver unit.
Angle sensors are used in many applications, including the automotive industry, robotics and navigation. They can be used to measure angles in motion systems, to control robots or to navigate vehicles.
Modern angle sensors often use digital displays and can be linked to other systems, such as automatic control, to optimise the production process and increase efficiency.
Angle sensors provide an accurate method of measuring angles in a variety of applications and can be used in a wide range of applications.
... Read more
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| Switching frequency max. | 100 Hz |
| Additional signal outputs | Contamination output |
| Switching output | PNP |
| Switching frequency max. | 200 Hz |
| Additional signal outputs | Contamination output |
| Switching output | PNP |
| Switching frequency max. | 200 Hz |
| Additional signal outputs | Contamination output |
| Switching output | PNP |
| Switching frequency max. | 200 Hz |
| Additional signal outputs | Contamination output |
| Switching output | PNP |
| Switching frequency max. | 100 Hz |
| Additional signal outputs | Contamination output |
| Switching output | PNP |
| Smallest detectable object diameter | 0.7 mm |
| Setting via | Potentiometer |
| Transmitted light | Red light standard |
| Smallest detectable object diameter | 0.5 mm |
| Setting via | Potentiometer |
| Transmitted light | Red light standard |
| Smallest detectable object diameter | 3 mm |
| Setting via | Potentiometer |
| Transmitted light | Red light standard |
| Smallest detectable object diameter | 0.05 mm |
| Setting via | Potentiometer |
| Transmitted light | Red light standard |
| Smallest detectable object diameter | 1 mm |
| Setting via | Potentiometer |
| Transmitted light | Red light standard |
| Smallest detectable object diameter | 1 mm |
| Setting via | Potentiometer |
| Transmitted light | Red light standard |
| Smallest detectable object diameter | 3 mm |
| Setting via | Potentiometer |
| Transmitted light | Red light standard |
| Smallest detectable object diameter | 3 mm |
| Setting via | Potentiometer |
| Transmitted light | Red light standard |
| Smallest detectable object diameter | 0.05 mm |
| Setting via | Potentiometer |
| Transmitted light | Red light standard |
| Smallest detectable object diameter | 0.7 mm |
| Setting via | Potentiometer |
| Transmitted light | Red light standard |
| Smallest detectable object diameter | 0.7 mm |
| Setting via | Potentiometer |
| Transmitted light | Red light standard |
| Smallest detectable object diameter | 1 mm |
| Setting via | Potentiometer |
| Transmitted light | Red light standard |
| Smallest detectable object diameter | 3 mm |
| Setting via | Potentiometer |
| Transmitted light | Red light standard |
| Smallest detectable object diameter | 3 mm |
| Setting via | Potentiometer |
| Transmitted light | Red light standard |
The sometimes time-consuming assembly of transmitter and receiver with through-beam sensors and their alignment to each other is no longer necessary. Only one cable connection is required. Angle light barriers are offered with different light sources. Thus, infrared light, red light and laser light are used. Laser light is suitable for detecting very small objects, for example. Infrared light is suitable for use in polluted environments, for example. Angular photoelectric sensors offer high switching frequencies and can also be used for speed measurements, for example.
Depending on the model, the sensitivity of the angular light barriers is set by means of a potentiometer or teach-in.
Light/dark switching
If the light beam between the transmitter and receiver of the angle 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.
Typical applications include stack height control, part detection, handling technology, position control and assembly technology.
Depending on the model, the sensitivity of the angular light barriers is set by means of a potentiometer or teach-in.
Light/dark switching
If the light beam between the transmitter and receiver of the angle 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.
Typical applications include stack height control, part detection, handling technology, position control and assembly technology.
What are angle light barriers and how do they work?
Angle light barriers are optical sensors that are used to detect the presence or passage of an object at a certain angle. They consist of a transmitter and a receiver that face each other and generate a narrow beam of light.
The function of an angled photoelectric sensor is based on the principle of interrupting the light beam. If the light beam is interrupted by an object, the receiver detects this interruption and emits a corresponding signal. This signal can then be used to trigger a specific action, such as controlling a machine or triggering an alarm.
Angle light barriers are useful in various applications such as material detection in industry, object detection in robotics or position detection in the automotive industry. They offer a precise and reliable way of detecting the presence of objects at a specific angle.
The function of an angled photoelectric sensor is based on the principle of interrupting the light beam. If the light beam is interrupted by an object, the receiver detects this interruption and emits a corresponding signal. This signal can then be used to trigger a specific action, such as controlling a machine or triggering an alarm.
Angle light barriers are useful in various applications such as material detection in industry, object detection in robotics or position detection in the automotive industry. They offer a precise and reliable way of detecting the presence of objects at a specific angle.
What are the areas of application for angle light barriers?
Angle light barriers are used in various areas of application. Here are some examples:
1. Industrial automation: Angle light barriers are often used in industrial production to monitor the flow of materials or parts. They can be used, for example, to detect whether a product has passed a certain point.
2. Transportation systems: Angle light barriers can be used in traffic systems to detect vehicles. They can be used in traffic lights, for example, to determine whether a vehicle is present at an intersection and control the traffic light accordingly.
3. Security technology: Angle light barriers are also often used in safety systems to monitor movements. They can be used in alarm systems, for example, to determine whether someone is moving in a certain area.
4. Medical devices: In medical technology, angle light barriers are often used in devices such as ultrasound and CT scanners to monitor the position of patients or device parts.
5. Robotics: In robotics, angle light barriers can be used to monitor the movement of robots and avoid collisions with obstacles.
These are just a few examples of applications for angle light barriers. Due to their versatility and adaptability, they are used in many different industries and applications.
1. Industrial automation: Angle light barriers are often used in industrial production to monitor the flow of materials or parts. They can be used, for example, to detect whether a product has passed a certain point.
2. Transportation systems: Angle light barriers can be used in traffic systems to detect vehicles. They can be used in traffic lights, for example, to determine whether a vehicle is present at an intersection and control the traffic light accordingly.
3. Security technology: Angle light barriers are also often used in safety systems to monitor movements. They can be used in alarm systems, for example, to determine whether someone is moving in a certain area.
4. Medical devices: In medical technology, angle light barriers are often used in devices such as ultrasound and CT scanners to monitor the position of patients or device parts.
5. Robotics: In robotics, angle light barriers can be used to monitor the movement of robots and avoid collisions with obstacles.
These are just a few examples of applications for angle light barriers. Due to their versatility and adaptability, they are used in many different industries and applications.
What types of angled photoelectric sensors are there?
There are different types of angle light barriers, depending on how they measure the angle. Here are some examples:
1. Retro-reflective photoelectric sensor: This type of angled photoelectric sensor consists of a transmitter and a receiver that face each other. The light is emitted by the transmitter and detected by the receiver. If an object interrupts the light beam, the angle is measured.
2. Transmitted light barrier: With this type of angled photoelectric sensor, the light is sent from above through the angle and detected by a receiver on the opposite side. If an object blocks the light beam, the angle is measured.
3. Refraction light barrier: This type of angled photoelectric sensor uses a lens to direct the light through the angle. A receiver detects the light and when it is interrupted, the angle is measured.
4. Inductive angled photoelectric sensor: This type of angled photoelectric sensor uses an inductive method to measure the angle. It generates a magnetic field around the angle and detects changes in this field when an object crosses the angle.
There are other types of angled photoelectric sensors, but these are some of the most common. Depending on the application, certain types of angled light barriers may be more suitable than others.
1. Retro-reflective photoelectric sensor: This type of angled photoelectric sensor consists of a transmitter and a receiver that face each other. The light is emitted by the transmitter and detected by the receiver. If an object interrupts the light beam, the angle is measured.
2. Transmitted light barrier: With this type of angled photoelectric sensor, the light is sent from above through the angle and detected by a receiver on the opposite side. If an object blocks the light beam, the angle is measured.
3. Refraction light barrier: This type of angled photoelectric sensor uses a lens to direct the light through the angle. A receiver detects the light and when it is interrupted, the angle is measured.
4. Inductive angled photoelectric sensor: This type of angled photoelectric sensor uses an inductive method to measure the angle. It generates a magnetic field around the angle and detects changes in this field when an object crosses the angle.
There are other types of angled photoelectric sensors, but these are some of the most common. Depending on the application, certain types of angled light barriers may be more suitable than others.
How accurate are angle light barriers when measuring angles?
Angle light barriers are used to measure the angle between a light source and a detector. They consist of a light source, a detector and a reflector or an object that reflects the light.
The light source emits a beam of light that hits the reflector and is reflected back to the detector. The detector detects the reflected light and converts it into an electrical signal.
The angle between the light source and the detector can be measured based on the position of the reflected light beam. The exact angle can be calculated by evaluating the electrical signal.
Angle light barriers offer precise measurement of angles as they are based on the principle of light refraction and reflection. The accuracy depends on various factors, such as the quality of the components used, the alignment of the light source and detector and the environment in which the measurement is carried out.
Overall, angle light barriers offer a reliable way to measure angles and are used in various applications, such as robotics, automation technology or measurement technology.
The light source emits a beam of light that hits the reflector and is reflected back to the detector. The detector detects the reflected light and converts it into an electrical signal.
The angle between the light source and the detector can be measured based on the position of the reflected light beam. The exact angle can be calculated by evaluating the electrical signal.
Angle light barriers offer precise measurement of angles as they are based on the principle of light refraction and reflection. The accuracy depends on various factors, such as the quality of the components used, the alignment of the light source and detector and the environment in which the measurement is carried out.
Overall, angle light barriers offer a reliable way to measure angles and are used in various applications, such as robotics, automation technology or measurement technology.
What are the advantages of angle light barriers compared to other measuring methods?
Angle light barriers offer several advantages compared to other measuring methods:
1. High accuracy: Angle light barriers enable precise measurement of angles and positions. They can detect the smallest deviations and deliver accurate measurement results.
2. Fast response time: Angle light barriers react very quickly to changes in position or angle. This makes them ideal for applications where fast feedback is required.
3. Non-contact measurement: In contrast to other measuring methods such as mechanical sensors or contact probes, angle light barriers work without contact. This enables measurement without wear or damage to the measurement object.
4. Versatile areas of application: Angle light barriers can be used in a variety of applications, e.g. in industrial automation, robotics, measurement technology or medical technology. They can be used flexibly and can be adapted to different measurement requirements.
5. Low space requirement: Angle light barriers are generally compact and require little space. This means they can also be used in confined or restricted environments.
6. Robustness: Angle light barriers are often very robust and protected against external influences such as vibrations, dust or moisture. This makes them ideal for use in demanding environments.
Overall, angle light barriers offer a precise, fast and reliable measurement method for angles and positions in various application areas.
1. High accuracy: Angle light barriers enable precise measurement of angles and positions. They can detect the smallest deviations and deliver accurate measurement results.
2. Fast response time: Angle light barriers react very quickly to changes in position or angle. This makes them ideal for applications where fast feedback is required.
3. Non-contact measurement: In contrast to other measuring methods such as mechanical sensors or contact probes, angle light barriers work without contact. This enables measurement without wear or damage to the measurement object.
4. Versatile areas of application: Angle light barriers can be used in a variety of applications, e.g. in industrial automation, robotics, measurement technology or medical technology. They can be used flexibly and can be adapted to different measurement requirements.
5. Low space requirement: Angle light barriers are generally compact and require little space. This means they can also be used in confined or restricted environments.
6. Robustness: Angle light barriers are often very robust and protected against external influences such as vibrations, dust or moisture. This makes them ideal for use in demanding environments.
Overall, angle light barriers offer a precise, fast and reliable measurement method for angles and positions in various application areas.
What challenges can arise when using angle light barriers?
Various challenges can arise when using angled light barriers:
1. Sensitivity: Angle light barriers can react sensitively to ambient light. Strong daylight or other light sources can affect the measurements and lead to incorrect results.
2. Alignment: The angled photoelectric sensor must be correctly aligned to ensure accurate measurements. Incorrect alignment can lead to incorrect angle results.
3. Reflective surfaces: If the light is reflected by the surface to be measured, this can lead to inaccurate measurements. Reflective surfaces can reflect the light and influence the angle determination.
4. Pollution: Dirty or dusty lenses can impair the measuring accuracy. It is important to clean the angled light barrier regularly in order to achieve optimum results.
5. Electrical faults: Electrical interference can affect the measurements. Electromagnetic interference or other electrical devices in the vicinity of the angled light barrier can lead to faults or failures.
6. Calibration: Incorrect calibration of the angled photoelectric sensor can lead to inaccurate measurement results. It is important to calibrate the light barrier regularly to ensure accurate and reliable measurements.
These challenges should be taken into account when using angle light barriers to enable accurate and reliable measurements.
1. Sensitivity: Angle light barriers can react sensitively to ambient light. Strong daylight or other light sources can affect the measurements and lead to incorrect results.
2. Alignment: The angled photoelectric sensor must be correctly aligned to ensure accurate measurements. Incorrect alignment can lead to incorrect angle results.
3. Reflective surfaces: If the light is reflected by the surface to be measured, this can lead to inaccurate measurements. Reflective surfaces can reflect the light and influence the angle determination.
4. Pollution: Dirty or dusty lenses can impair the measuring accuracy. It is important to clean the angled light barrier regularly in order to achieve optimum results.
5. Electrical faults: Electrical interference can affect the measurements. Electromagnetic interference or other electrical devices in the vicinity of the angled light barrier can lead to faults or failures.
6. Calibration: Incorrect calibration of the angled photoelectric sensor can lead to inaccurate measurement results. It is important to calibrate the light barrier regularly to ensure accurate and reliable measurements.
These challenges should be taken into account when using angle light barriers to enable accurate and reliable measurements.
What factors influence the accuracy of angle light barriers?
The accuracy of angle light barriers can be influenced by various factors, including
1. Sensor quality: The quality of the sensor itself can influence the accuracy. High-quality sensors are generally more precise and provide accurate measured values.
2. Ambient conditions: The ambient conditions, such as temperature, humidity and vibrations, can affect the accuracy. A stable and controlled environment can improve measurement accuracy.
3. Assembly and alignment: Correct mounting and alignment of the angled photoelectric sensor is crucial for accuracy. Incorrect alignment can lead to measurement errors.
4. Distance to the object: The distance between the angled photoelectric sensor and the object to be measured can influence the accuracy. A distance that is too large or too small can lead to inaccurate measured values.
5. Object surface: The surface of the object to be measured can also influence the accuracy. A reflective or highly structured surface can lead to incorrect measurements.
6. Signal processing: The signal processing within the angled light barrier can also influence the accuracy. Precise and stable signal processing is important in order to obtain accurate measured values.
It is important to take all these factors into account when installing and using angle light barriers to ensure high accuracy and reliability.
1. Sensor quality: The quality of the sensor itself can influence the accuracy. High-quality sensors are generally more precise and provide accurate measured values.
2. Ambient conditions: The ambient conditions, such as temperature, humidity and vibrations, can affect the accuracy. A stable and controlled environment can improve measurement accuracy.
3. Assembly and alignment: Correct mounting and alignment of the angled photoelectric sensor is crucial for accuracy. Incorrect alignment can lead to measurement errors.
4. Distance to the object: The distance between the angled photoelectric sensor and the object to be measured can influence the accuracy. A distance that is too large or too small can lead to inaccurate measured values.
5. Object surface: The surface of the object to be measured can also influence the accuracy. A reflective or highly structured surface can lead to incorrect measurements.
6. Signal processing: The signal processing within the angled light barrier can also influence the accuracy. Precise and stable signal processing is important in order to obtain accurate measured values.
It is important to take all these factors into account when installing and using angle light barriers to ensure high accuracy and reliability.