| Applications | Vehicles & Road Traffic Heating/ Air conditioning/ Ventilation Fisheries & Aquaculture Forestry Mechanical engineering & Plant construction Show all Metal industry Semiconductor industry |
| Resolution | 16 bit |
| Speed max. | 800 U/min |
| Electrical rotation angle | 0 to 360 ° |
Rotary angle sensors
1 - 20 / 108
| Load capacity, max. | 0.24 W |
| Protection class, housing | IP 67 |
| Signal output level | -6°~6°:1V±0.3V 6°~84°: 2.5V±0.3V 84°~96°: 4V±0.3V |
| Current, max. | 2,000 mA |
| Cable length | 340 mm |
| Supply voltage | 5 to 10 V |
| Current, max. | 2,000 mA |
| Supply voltage | 3 to 30 V |
| Number of PINs | 3 |
| Applications | Fisheries & Aquaculture Forestry Mechanical engineering & Plant construction Metal industry Semiconductor industry |
| Speed max. | 120 U/min |
| Resolution | 12 bit |
| Electrical rotation angle | 0 to 360 ° |
| Applications | Fisheries & Aquaculture Forestry Mechanical engineering & Plant construction Metal industry Semiconductor industry |
| Resolution | 12 bit |
| Electrical rotation angle | 0 to 360 ° |
| Measuring principle | Hall effect |
| Current, max. | 2,000 mA |
| Supply voltage | 3 to 30 V |
| Number of PINs | 4 |
| Shaft diameter (solid shaft, hollow shaft) | 16 to 30.4 mm |
| Housing diameter | 17.5 mm |
| Design | Encapsulated |
| Current, max. | 2,000 mA |
| Supply voltage | 5 to 30 V |
| Number of PINs | 5-pin |
| Current, max. | 2,000 mA |
| Cable length | 114 mm |
| Supply voltage | 5 to 30 V |
| Shaft diameter (solid shaft, hollow shaft) | 16 to 30.4 mm |
| Housing diameter | 13 mm |
| Design | Open |
| Shaft diameter (solid shaft, hollow shaft) | 30.4 mm |
| Housing diameter | 30.4 mm |
| Shaft type | Blind hollow shaft |
| Shaft diameter (solid shaft, hollow shaft) | 16 to 30.4 mm |
| Linearity | 2 % |
| Electrical rotation angle | 320 ° |
| Shaft diameter (solid shaft, hollow shaft) | 16 to 30.4 mm |
| Cable length | 45 mm |
| Supply voltage | 3 to 30 V |
| Shaft diameter (solid shaft, hollow shaft) | 16 to 30.4 mm |
| Housing diameter | 45 mm |
| Shaft type | Solid shaft |
| Current, max. | 2,000 mA |
| Supply voltage | 5 to 10 V |
| Shaft diameter (solid shaft, hollow shaft) | 16 to 30.4 mm |
| Shaft diameter (solid shaft, hollow shaft) | 16 to 30.4 mm |
| Fastening | 6 mm shaft with marking, IP54 |
| Mechanical rotation angle max. | 360° |
| Shaft diameter (solid shaft, hollow shaft) | 16 to 30.4 mm |
| Fastening | 6 mm shaft with marking, IP65 |
| Mechanical rotation angle max. | 360° |
| Shaft diameter (solid shaft, hollow shaft) | 16 to 30.4 mm |
| Fastening | 6 mm shaft with marking, IP67 |
| Mechanical rotation angle max. | 360° |
Angle of rotation sensors are electronic devices used to measure the angle or position of rotation of a rotating shaft or object. Angle of rotation sensors, often referred to as potentiometric angle sensors, are based on the principle of voltage drop across a rotating resistor.
An angle of rotation sensor typically consists of a rotating resistive element mounted on a shaft and a moving contact connected to the rotating shaft via a drive. As the shaft rotates, the contact rotates, changing the resistance of the rotating resistive element. This causes a change in the voltage drop and therefore a change in the output voltage of the sensor.
There are several types of angle of rotation sensors, including linear and rotary. Linear angle of rotation sensors measure the angle of rotation in a straight line, while rotary angle of rotation sensors measure the angle in a circle.
Angular position sensors are used in many applications, including automotive, aerospace, robotics, medical and industrial automation. They are used to position machines and systems, control motors and drives, monitor rotary motion and control position, speed and acceleration.
The accuracy and resolution of rotary sensors depends on the size and design of the rotating resistive element. Some sensors have high resolution and accuracy but are sensitive to noise and vibration. Other sensors are more robust and stable, but have lower resolution and accuracy. The selection of the right angular position sensor depends on the application and the requirements for accuracy and stability of the measurement.
An angle of rotation sensor typically consists of a rotating resistive element mounted on a shaft and a moving contact connected to the rotating shaft via a drive. As the shaft rotates, the contact rotates, changing the resistance of the rotating resistive element. This causes a change in the voltage drop and therefore a change in the output voltage of the sensor.
There are several types of angle of rotation sensors, including linear and rotary. Linear angle of rotation sensors measure the angle of rotation in a straight line, while rotary angle of rotation sensors measure the angle in a circle.
Angular position sensors are used in many applications, including automotive, aerospace, robotics, medical and industrial automation. They are used to position machines and systems, control motors and drives, monitor rotary motion and control position, speed and acceleration.
The accuracy and resolution of rotary sensors depends on the size and design of the rotating resistive element. Some sensors have high resolution and accuracy but are sensitive to noise and vibration. Other sensors are more robust and stable, but have lower resolution and accuracy. The selection of the right angular position sensor depends on the application and the requirements for accuracy and stability of the measurement.
What are rotation angle sensors and what are they used for?
Angle of rotation sensors are electronic devices that detect the angle or rotational movement of an object. They measure the relative or absolute rotation of an object and convert this into an electrical signal.
Rotation angle sensors are used in various applications to monitor or control the position or movement of rotating parts. Some common applications are:
1. Automotive industry: Rotation angle sensors are used to detect the position of the steering wheel and transmit information to the electronic steering system. They also help to detect the position of the brake and gas pedal pedals.
2. Industrial machines: Rotation angle sensors are used in industrial machines to monitor the position or movement of rotating parts such as motors, gears or axes. They can also be used to control robots or CNC machines.
3. Medical technology: Rotation angle sensors are used in medical devices such as prostheses or medical robots to improve movement accuracy and control.
4. Aerospace: In the aerospace industry, rotation angle sensors are used to monitor and control the position of flight control systems, for example in the control of aircraft wings or rocket nozzles.
5. Electronics: Rotation angle sensors are also used in electronic devices, for example to control joysticks in video games or to detect the position of sliders in audio devices.
Overall, rotation angle sensors are used to detect the position or movement of rotating parts or objects and to use this information for control or monitoring purposes.
Rotation angle sensors are used in various applications to monitor or control the position or movement of rotating parts. Some common applications are:
1. Automotive industry: Rotation angle sensors are used to detect the position of the steering wheel and transmit information to the electronic steering system. They also help to detect the position of the brake and gas pedal pedals.
2. Industrial machines: Rotation angle sensors are used in industrial machines to monitor the position or movement of rotating parts such as motors, gears or axes. They can also be used to control robots or CNC machines.
3. Medical technology: Rotation angle sensors are used in medical devices such as prostheses or medical robots to improve movement accuracy and control.
4. Aerospace: In the aerospace industry, rotation angle sensors are used to monitor and control the position of flight control systems, for example in the control of aircraft wings or rocket nozzles.
5. Electronics: Rotation angle sensors are also used in electronic devices, for example to control joysticks in video games or to detect the position of sliders in audio devices.
Overall, rotation angle sensors are used to detect the position or movement of rotating parts or objects and to use this information for control or monitoring purposes.
How do rotation angle sensors work and what technologies are used?
Rotation angle sensors detect the rotational movement of an object and output the angle of rotation as an output signal. There are various technologies that are used to measure rotation angles:
1. Potentiometer: A potentiometer consists of a resistor element and a movable wiper. When the object is rotated, the resistance value of the potentiometer changes according to the angle of rotation. This resistance value can then be used as an output signal.
2. Optical encoders: Optical encoders use light and photo sensors to measure the angle of rotation. A rotating pattern or pattern on a disk reflects or blocks the light that is detected by the photosensors. The angle of rotation can be determined by analyzing the changes in the light pattern. There are incremental encoders, which detect changes in position, and absolute encoders, which can determine the exact angle.
3. Magnetic encoders: Magnetic encoders use magnetic fields to measure the angle of rotation. A rotating magnet or a magnetic pattern on a disk generates changes in the magnetic field that are detected by magnetic sensors. These changes are then converted into the corresponding angle of rotation.
4. Hall sensors: Hall sensors use the Hall effect to measure magnetic fields. When a magnetic field changes, a Hall sensor generates an electrical signal that is proportional to the strength and direction of the field. The angle of rotation can be determined by placing magnets or magnetic patterns on a rotating disk.
These technologies are used depending on the application and accuracy requirements. Potentiometers are simpler and less expensive, but may not offer the same accuracy as optical or magnetic encoders. Optical and magnetic encoders are more precise, but also more expensive. The choice of technology depends on the specific requirements of the angle of rotation sensor.
1. Potentiometer: A potentiometer consists of a resistor element and a movable wiper. When the object is rotated, the resistance value of the potentiometer changes according to the angle of rotation. This resistance value can then be used as an output signal.
2. Optical encoders: Optical encoders use light and photo sensors to measure the angle of rotation. A rotating pattern or pattern on a disk reflects or blocks the light that is detected by the photosensors. The angle of rotation can be determined by analyzing the changes in the light pattern. There are incremental encoders, which detect changes in position, and absolute encoders, which can determine the exact angle.
3. Magnetic encoders: Magnetic encoders use magnetic fields to measure the angle of rotation. A rotating magnet or a magnetic pattern on a disk generates changes in the magnetic field that are detected by magnetic sensors. These changes are then converted into the corresponding angle of rotation.
4. Hall sensors: Hall sensors use the Hall effect to measure magnetic fields. When a magnetic field changes, a Hall sensor generates an electrical signal that is proportional to the strength and direction of the field. The angle of rotation can be determined by placing magnets or magnetic patterns on a rotating disk.
These technologies are used depending on the application and accuracy requirements. Potentiometers are simpler and less expensive, but may not offer the same accuracy as optical or magnetic encoders. Optical and magnetic encoders are more precise, but also more expensive. The choice of technology depends on the specific requirements of the angle of rotation sensor.
What types of rotation angle sensors are there and what are the differences between them?
There are different types of rotation angle sensors that use different measuring principles depending on the application. Here are some common types of rotation angle sensors and their differences:
1. Potentiometer: Potentiometers are simple rotation angle sensors that measure the resistance as a function of the rotational position. They are inexpensive, but not very precise and often have a limited service life.
2. Incremental encoders: Incremental encoders measure the change in the angle of rotation in discrete steps. They consist of a pulse generator and a scanning head that counts the pulses. They are precise, but they do not provide absolute position information, only relative changes in the angle of rotation.
3. Absolute encoder: Absolute encoders provide absolute position information of the angle of rotation. They can either be incremental with additional positioning information or absolute without additional reference points. Absolute encoders are precise, but generally more expensive than incremental encoders.
4. Hall sensors: Hall sensors use the Hall effect principle to measure the angle of rotation. They detect the changes in the magnetic field generated by a magnet on the rotating object. Hall sensors are contactless and can also be used under extreme conditions.
5. Optical encoders: Optical encoders use light barriers or optical sensors to measure the angle of rotation. They consist of a light source, a pattern or a disk with apertures and a sensor that measures the light intensity. Optical encoders are precise and have a high resolution, but they can be susceptible to contamination.
6. Magnetic encoders: Magnetic encoders use magnetic fields to measure the angle of rotation. They consist of a magnet on the rotating object and a sensor that detects the changes in the magnetic field. Magnetic encoders are robust and can also be used in environments with vibrations and shocks.
The choice of the right angle of rotation sensor depends on the specific requirements of the application, such as accuracy, resolution, robustness and cost.
1. Potentiometer: Potentiometers are simple rotation angle sensors that measure the resistance as a function of the rotational position. They are inexpensive, but not very precise and often have a limited service life.
2. Incremental encoders: Incremental encoders measure the change in the angle of rotation in discrete steps. They consist of a pulse generator and a scanning head that counts the pulses. They are precise, but they do not provide absolute position information, only relative changes in the angle of rotation.
3. Absolute encoder: Absolute encoders provide absolute position information of the angle of rotation. They can either be incremental with additional positioning information or absolute without additional reference points. Absolute encoders are precise, but generally more expensive than incremental encoders.
4. Hall sensors: Hall sensors use the Hall effect principle to measure the angle of rotation. They detect the changes in the magnetic field generated by a magnet on the rotating object. Hall sensors are contactless and can also be used under extreme conditions.
5. Optical encoders: Optical encoders use light barriers or optical sensors to measure the angle of rotation. They consist of a light source, a pattern or a disk with apertures and a sensor that measures the light intensity. Optical encoders are precise and have a high resolution, but they can be susceptible to contamination.
6. Magnetic encoders: Magnetic encoders use magnetic fields to measure the angle of rotation. They consist of a magnet on the rotating object and a sensor that detects the changes in the magnetic field. Magnetic encoders are robust and can also be used in environments with vibrations and shocks.
The choice of the right angle of rotation sensor depends on the specific requirements of the application, such as accuracy, resolution, robustness and cost.
What advantages do rotation angle sensors offer over other measurement methods for detecting angles?
Rotation angle sensors offer several advantages over other measurement methods for detecting angles:
1. High accuracy: Rotation angle sensors can measure angles with high accuracy, which is important when precise measurements are required.
2. Large measuring range: Rotation angle sensors can cover a wide measuring range, from a few degrees to several revolutions. This enables the measurement of a wide variety of applications and movements.
3. Non-contact based measurement: In contrast to some other measuring methods, rotation angle sensors measure the angle without direct contact with the measured object. This reduces wear and enables measurement in environments with high levels of contamination or under extreme conditions.
4. Fast response time: Rotation angle sensors can quickly detect changes in the angle and provide real-time data. This is important in applications that require fast movements or quick reactions.
5. Low energy consumption: Angle of rotation sensors require less energy than some other measuring methods, which is particularly advantageous in battery-powered applications.
6. Compact design: Rotation angle sensors are generally small and compact, which facilitates their integration into various applications.
7. Longevity: Due to the non-contact-based measuring method and the low number of moving parts, angle of rotation sensors are often more durable and less susceptible to wear or failure.
These advantages make rotary angle sensors a preferred choice in many applications, including robotics, automotive, aerospace, medical and many others.
1. High accuracy: Rotation angle sensors can measure angles with high accuracy, which is important when precise measurements are required.
2. Large measuring range: Rotation angle sensors can cover a wide measuring range, from a few degrees to several revolutions. This enables the measurement of a wide variety of applications and movements.
3. Non-contact based measurement: In contrast to some other measuring methods, rotation angle sensors measure the angle without direct contact with the measured object. This reduces wear and enables measurement in environments with high levels of contamination or under extreme conditions.
4. Fast response time: Rotation angle sensors can quickly detect changes in the angle and provide real-time data. This is important in applications that require fast movements or quick reactions.
5. Low energy consumption: Angle of rotation sensors require less energy than some other measuring methods, which is particularly advantageous in battery-powered applications.
6. Compact design: Rotation angle sensors are generally small and compact, which facilitates their integration into various applications.
7. Longevity: Due to the non-contact-based measuring method and the low number of moving parts, angle of rotation sensors are often more durable and less susceptible to wear or failure.
These advantages make rotary angle sensors a preferred choice in many applications, including robotics, automotive, aerospace, medical and many others.
What areas of application are there for angle of rotation sensors and in which areas are they used particularly frequently?
Angle of rotation sensors are used in a wide range of applications. Here are some examples:
1. Industrial automation: Rotation angle sensors are used in machines and systems to detect the position and angle of rotating parts such as motors, gears or swivel arms. They are important for regulating and controlling movements in industrial automation.
2. Vehicle technology: Rotation angle sensors are used in vehicles to detect the position and angle of steering wheels, pedals, gear sticks and other components. They are used to control vehicle systems such as steering, brakes, accelerator pedal and transmission.
3. Aerospace: Angle of rotation sensors are used in the aerospace industry to detect the position and angle of flight control components such as rudders, flaps and control horns. They play an important role in the control of airplanes, helicopters, satellites and spacecraft.
4. Medical technology: Rotation angle sensors are used in medical devices such as prostheses, robots for minimally invasive surgery and rehabilitation systems. They enable precise motion control and monitoring in medical technology.
5. Robotics: Rotation angle sensors are used in robots to detect the position and angle of joints and actuators. They enable precise motion control and monitoring of robots in various applications such as assembly, warehousing, medicine and research.
6. Renewable energies: Rotation angle sensors are used in wind turbines and solar tracking systems to detect the position and angle of rotor blades or solar panels. They are used to optimize energy generation and to control the systems.
These areas of application are not exhaustive and there are many other areas in which rotation angle sensors are used. The flexibility and precision of these sensors make them indispensable in many industries.
1. Industrial automation: Rotation angle sensors are used in machines and systems to detect the position and angle of rotating parts such as motors, gears or swivel arms. They are important for regulating and controlling movements in industrial automation.
2. Vehicle technology: Rotation angle sensors are used in vehicles to detect the position and angle of steering wheels, pedals, gear sticks and other components. They are used to control vehicle systems such as steering, brakes, accelerator pedal and transmission.
3. Aerospace: Angle of rotation sensors are used in the aerospace industry to detect the position and angle of flight control components such as rudders, flaps and control horns. They play an important role in the control of airplanes, helicopters, satellites and spacecraft.
4. Medical technology: Rotation angle sensors are used in medical devices such as prostheses, robots for minimally invasive surgery and rehabilitation systems. They enable precise motion control and monitoring in medical technology.
5. Robotics: Rotation angle sensors are used in robots to detect the position and angle of joints and actuators. They enable precise motion control and monitoring of robots in various applications such as assembly, warehousing, medicine and research.
6. Renewable energies: Rotation angle sensors are used in wind turbines and solar tracking systems to detect the position and angle of rotor blades or solar panels. They are used to optimize energy generation and to control the systems.
These areas of application are not exhaustive and there are many other areas in which rotation angle sensors are used. The flexibility and precision of these sensors make them indispensable in many industries.
How precise are rotation angle sensors and what accuracies can they achieve?
Rotation angle sensors can be very precise and achieve high accuracies. However, the actual accuracy depends on various factors, such as the type of rotation angle sensor, the quality of the components used and the calibration of the sensor.
Some common types of rotation angle sensors, such as potentiometers or optical encoders, can achieve accuracies ranging from a few degrees to fractions of a degree. Magnetic encoders can achieve even higher accuracies, typically in the range of a few angular seconds.
It is important to note that the accuracy of a rotation angle sensor can also be influenced by external factors such as vibrations, temperature fluctuations and electrical interference. It is therefore advisable to test the sensor under the specific operating conditions and to calibrate it if necessary in order to achieve the best possible accuracy.
Some common types of rotation angle sensors, such as potentiometers or optical encoders, can achieve accuracies ranging from a few degrees to fractions of a degree. Magnetic encoders can achieve even higher accuracies, typically in the range of a few angular seconds.
It is important to note that the accuracy of a rotation angle sensor can also be influenced by external factors such as vibrations, temperature fluctuations and electrical interference. It is therefore advisable to test the sensor under the specific operating conditions and to calibrate it if necessary in order to achieve the best possible accuracy.
What challenges can arise when using rotation angle sensors and how can they be solved?
Various challenges can arise when using rotation angle sensors. Some possible problems and solutions are:
1. Nonlinearity: Angle of rotation sensors can be non-linear, which can lead to inaccurate measurements. One solution is to calibrate the measured data and use a correction function to compensate for the non-linearity.
2. Temperature dependence: The measuring accuracy of rotation angle sensors can depend on the temperature. To solve this problem, sensors with integrated temperature compensation can be used or a separate temperature measurement can be carried out to adjust the measurements accordingly.
3. Interferences: External magnetic or electric fields can influence the measurements of rotation angle sensors and lead to incorrect results. One possible solution is to shield the sensors or use them in an environment with low interference.
4. Wear and tear: Mechanical rotation angle sensors can be subject to wear, which can lead to a reduction in measuring accuracy. One solution is to carry out regular maintenance and calibration work and replace the sensor if necessary.
5. Assembly and alignment: Incorrect installation or alignment of the rotation angle sensor can lead to inaccurate measurements. It is important to mount and align the sensor properly according to the manufacturer's instructions in order to obtain accurate measurement results.
It should be noted that the specific challenges and solutions may vary depending on the type of rotation angle sensor, e.g. optical, magnetic or inductive sensors.
1. Nonlinearity: Angle of rotation sensors can be non-linear, which can lead to inaccurate measurements. One solution is to calibrate the measured data and use a correction function to compensate for the non-linearity.
2. Temperature dependence: The measuring accuracy of rotation angle sensors can depend on the temperature. To solve this problem, sensors with integrated temperature compensation can be used or a separate temperature measurement can be carried out to adjust the measurements accordingly.
3. Interferences: External magnetic or electric fields can influence the measurements of rotation angle sensors and lead to incorrect results. One possible solution is to shield the sensors or use them in an environment with low interference.
4. Wear and tear: Mechanical rotation angle sensors can be subject to wear, which can lead to a reduction in measuring accuracy. One solution is to carry out regular maintenance and calibration work and replace the sensor if necessary.
5. Assembly and alignment: Incorrect installation or alignment of the rotation angle sensor can lead to inaccurate measurements. It is important to mount and align the sensor properly according to the manufacturer's instructions in order to obtain accurate measurement results.
It should be noted that the specific challenges and solutions may vary depending on the type of rotation angle sensor, e.g. optical, magnetic or inductive sensors.
What does the future of rotation angle sensors look like and what developments can be expected in this area?
The future of rotation angle sensors looks promising and various developments are expected. Here are some possible developments in this area:
1. Improved accuracy: Rotation angle sensors are expected to become even more precise in the future. Advances in sensor and measurement technology enable higher resolution and accuracy when measuring angles of rotation.
2. Smaller and more compact design: Thanks to the use of advanced materials and technologies, angle of rotation sensors are expected to become smaller and more compact. This enables their integration into more and more devices and applications where space and weight play a role.
3. Wireless communication: Another possible development is the wireless communication of rotation angle sensors. This would facilitate use in wireless networks and IoT applications and simplify installation and maintenance.
4. Extended functionalities: Future rotation angle sensors could have extended functionalities, such as the detection of speeds or accelerations. This would expand their possible uses and enable new applications.
5. Integrated sensors: It is expected that rotation angle sensors will increasingly be integrated with other sensors to capture more comprehensive information. For example, they could be coupled with acceleration sensors to record movements in several dimensions.
6. Energy efficiency: Future developments could aim to improve the energy efficiency of rotation angle sensors. This could facilitate use in battery-powered devices and applications and extend battery life.
However, these developments are speculative and are based on current trends and technological advances. It is important to note that the actual future of rotation angle sensors depends on several factors, including the needs and requirements of the industry and the technological breakthroughs that will be achieved in the coming years.
1. Improved accuracy: Rotation angle sensors are expected to become even more precise in the future. Advances in sensor and measurement technology enable higher resolution and accuracy when measuring angles of rotation.
2. Smaller and more compact design: Thanks to the use of advanced materials and technologies, angle of rotation sensors are expected to become smaller and more compact. This enables their integration into more and more devices and applications where space and weight play a role.
3. Wireless communication: Another possible development is the wireless communication of rotation angle sensors. This would facilitate use in wireless networks and IoT applications and simplify installation and maintenance.
4. Extended functionalities: Future rotation angle sensors could have extended functionalities, such as the detection of speeds or accelerations. This would expand their possible uses and enable new applications.
5. Integrated sensors: It is expected that rotation angle sensors will increasingly be integrated with other sensors to capture more comprehensive information. For example, they could be coupled with acceleration sensors to record movements in several dimensions.
6. Energy efficiency: Future developments could aim to improve the energy efficiency of rotation angle sensors. This could facilitate use in battery-powered devices and applications and extend battery life.
However, these developments are speculative and are based on current trends and technological advances. It is important to note that the actual future of rotation angle sensors depends on several factors, including the needs and requirements of the industry and the technological breakthroughs that will be achieved in the coming years.