| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 100 mA |
| Switching output | PNP |
Cylinder sensors
Magnetic cylinder sensors, also called cylinder displacement sensors among others, are non-contact measuring position sensors. Magnetic cylinder sensors detect the piston position in cylinders without contact; they are mounted directly on the cylinder. The cylinder is made of non-magnetizable material. A permanent magnet or electromagnet is mounted in the piston of the cylinder (required for Hall sensors). The position of the piston in the cylinder is measured through the cylinder wall by the cylinder sensor.
... Read more
... Read more
21 - 38
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 200 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 200 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 200 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 200 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 100 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 100 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 200 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 200 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 200 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 200 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 200 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 200 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 100 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 100 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 100 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 100 mA |
| Switching output | PNP |
| Switching frequency max. | 1,000 Hz |
| Switching current, max. | 100 mA |
| Switching output | PNP |
When the set piston position is reached, a switching signal is triggered via a magnetic switch. The switching contacts of magnetic switches are triggered by a magnetic field. These magnetic switches are reed contacts and non-contact electronic sensors such as AMR (Anisotropic Magneto-Resistive), GMR (Giant Magneto-Resistive) or Hall sensors.
In sensors based on AMR technology, a change in the magnetic field produces a change in electrical resistance.
Unlike AMR, the magnetoresistance effect in GMR is very large. GMR sensors basically consist of two very thin magnetic layers with a very thin non-magnetic layer between them. By multiplying this layer structure, the increase in resistance can be increased even more significantly. The GMR effect depends on the material used and the layer thickness of the materials.
Magnetic switches operate wear-free, enable high switching frequencies and are insensitive to shock and vibration. The power consumption is relatively low.
Reed contact switches operate without external electrical power and can switch DC and AC loads. Relatively high switching capacities can be realized. The insulation resistance with an open reed switch is high, so that only very low leakage currents flow. The contact resistance of closed reed contacts is very low. Reed switches operate over a wide temperature range (approx. -55...200 °C depending on the supplier).
Linear measuring magnetic cylinder sensors with analog output output the piston position over the entire measuring range.
Application reports on the topic of cylinder sensors
In diribo you will find application reports written by the suppliers on the sensor category "cylinder sensors". There exists also the possibility to enter search terms. In this way, application reports can be found that deal with a specific topic.
In sensors based on AMR technology, a change in the magnetic field produces a change in electrical resistance.
Unlike AMR, the magnetoresistance effect in GMR is very large. GMR sensors basically consist of two very thin magnetic layers with a very thin non-magnetic layer between them. By multiplying this layer structure, the increase in resistance can be increased even more significantly. The GMR effect depends on the material used and the layer thickness of the materials.
Magnetic switches operate wear-free, enable high switching frequencies and are insensitive to shock and vibration. The power consumption is relatively low.
Reed contact switches operate without external electrical power and can switch DC and AC loads. Relatively high switching capacities can be realized. The insulation resistance with an open reed switch is high, so that only very low leakage currents flow. The contact resistance of closed reed contacts is very low. Reed switches operate over a wide temperature range (approx. -55...200 °C depending on the supplier).
Linear measuring magnetic cylinder sensors with analog output output the piston position over the entire measuring range.
Application reports on the topic of cylinder sensors
In diribo you will find application reports written by the suppliers on the sensor category "cylinder sensors". There exists also the possibility to enter search terms. In this way, application reports can be found that deal with a specific topic.
What are cylinder sensors and what are they used for?
Cylinder sensors are sensors that are able to detect the status or movement of a cylinder. They are typically used in pneumatic or hydraulic systems.
The main function of cylinder sensors is to monitor the stroke or position of the cylinder. For example, you can record the start and end point of a cylinder stroke or measure the exact position of the cylinder in real time.
Cylinder sensors are used in various industrial applications where precise motion control is required. These include automation systems, robotics, production technology, packaging systems and medical technology.
By using cylinder sensors, companies can improve the accuracy and reliability of their systems, increase productivity and reduce downtime.
The main function of cylinder sensors is to monitor the stroke or position of the cylinder. For example, you can record the start and end point of a cylinder stroke or measure the exact position of the cylinder in real time.
Cylinder sensors are used in various industrial applications where precise motion control is required. These include automation systems, robotics, production technology, packaging systems and medical technology.
By using cylinder sensors, companies can improve the accuracy and reliability of their systems, increase productivity and reduce downtime.
How do cylinder sensors work and what technologies are used?
Cylinder sensors are special sensors that are installed in cylinders or other pneumatic or hydraulic actuators. They are used to monitor and control the condition of the cylinder or the piston inside it.
There are various technologies that are used to record the cylinder status:
1. Inductive sensors: These sensors use the principle of magnetic induction to detect changes in the magnetic field. Inductive sensors can detect the position of the cylinder by measuring the distance to a metal part (e.g. a magnetic piston).
2. Optical sensors: Optical sensors use light beams to detect the state of the cylinder. For example, you can measure the position of the piston by reflection on a reflective tape or by shining light through the cylinder.
3. Ultrasonic sensors: Ultrasonic sensors use sound waves with a frequency above the audible range to detect the cylinder condition. You can measure the distance to the piston by measuring the time it takes for the sound to return to the sensor.
4. Pressure sensors: Pressure sensors measure the pressure inside a cylinder to monitor the condition of the cylinder. For example, you can measure the pressure in the cylinder to determine whether it is moving or whether there is a leak.
5. Magnetic sensors: Magnetic sensors detect changes in the magnetic field and can recognize the state of the cylinder by measuring the distance to a magnetic part (e.g. a magnet on the piston).
These sensors provide information about the status of the cylinder to a control system, which can then send corresponding control commands to the actuator. This enables precise and reliable control of the cylinder.
There are various technologies that are used to record the cylinder status:
1. Inductive sensors: These sensors use the principle of magnetic induction to detect changes in the magnetic field. Inductive sensors can detect the position of the cylinder by measuring the distance to a metal part (e.g. a magnetic piston).
2. Optical sensors: Optical sensors use light beams to detect the state of the cylinder. For example, you can measure the position of the piston by reflection on a reflective tape or by shining light through the cylinder.
3. Ultrasonic sensors: Ultrasonic sensors use sound waves with a frequency above the audible range to detect the cylinder condition. You can measure the distance to the piston by measuring the time it takes for the sound to return to the sensor.
4. Pressure sensors: Pressure sensors measure the pressure inside a cylinder to monitor the condition of the cylinder. For example, you can measure the pressure in the cylinder to determine whether it is moving or whether there is a leak.
5. Magnetic sensors: Magnetic sensors detect changes in the magnetic field and can recognize the state of the cylinder by measuring the distance to a magnetic part (e.g. a magnet on the piston).
These sensors provide information about the status of the cylinder to a control system, which can then send corresponding control commands to the actuator. This enables precise and reliable control of the cylinder.
What types of cylinder sensors are there and what are the differences between them?
There are different types of cylinder sensors that fulfill different functions depending on the application. Here are some common types:
1. Inductive cylinder sensors: These sensors detect the presence of a metal object inside the cylinder. They work by generating an electromagnetic field that is disturbed when a metal object comes close to the sensor.
2. Capacitive cylinder sensors: These sensors detect the presence of any material within the cylinder that has a certain capacity. They work by generating an electric field that is disturbed when a material comes close to the sensor.
3. Magnetic cylinder sensors: These sensors detect the presence of a magnetic object inside the cylinder. They use either a Hall-effect sensor or a magnetoresistive sensor to detect the changes in the magnetic field when the magnetic object approaches the sensor.
4. Optical cylinder sensors: These sensors detect the presence of an object inside the cylinder by using light beams. They can function either by reflecting the light or by interrupting the light beam.
The differences between the various types of cylinder sensors lie in the way they work and the materials they can detect. Inductive sensors only detect metals, while capacitive sensors can detect any material that has a certain capacitance. Magnetic sensors only detect magnetic objects, while optical sensors can also detect non-magnetic objects. Depending on the application, different sensors must therefore be used to achieve the desired results.
1. Inductive cylinder sensors: These sensors detect the presence of a metal object inside the cylinder. They work by generating an electromagnetic field that is disturbed when a metal object comes close to the sensor.
2. Capacitive cylinder sensors: These sensors detect the presence of any material within the cylinder that has a certain capacity. They work by generating an electric field that is disturbed when a material comes close to the sensor.
3. Magnetic cylinder sensors: These sensors detect the presence of a magnetic object inside the cylinder. They use either a Hall-effect sensor or a magnetoresistive sensor to detect the changes in the magnetic field when the magnetic object approaches the sensor.
4. Optical cylinder sensors: These sensors detect the presence of an object inside the cylinder by using light beams. They can function either by reflecting the light or by interrupting the light beam.
The differences between the various types of cylinder sensors lie in the way they work and the materials they can detect. Inductive sensors only detect metals, while capacitive sensors can detect any material that has a certain capacitance. Magnetic sensors only detect magnetic objects, while optical sensors can also detect non-magnetic objects. Depending on the application, different sensors must therefore be used to achieve the desired results.
What advantages do cylinder sensors offer over conventional sensors?
Cylinder sensors offer various advantages over conventional sensors, including
1. Space saving: Cylinder sensors are compact and can be installed directly in cylinders, saving additional space.
2. Cost efficiency: By integrating them into the cylinder, separate installation and cabling costs can be avoided.
3. Robustness: Cylinder sensors are generally shock-resistant and protected against external influences such as vibrations, dirt and moisture. This makes them durable and reliable.
4. Precision: Cylinder sensors offer high accuracy in the detection of positions, movements and other parameters. This means they can be used for precise control and regulation tasks.
5. Simple installation: The integration of cylinder sensors into the cylinder itself simplifies installation and commissioning. This reduces the time and effort required for setup.
6. Flexibility: Cylinder sensors are available in various versions tailored to different applications. They can be used for position, speed or pressure measurement, for example.
7. Energy efficiency: Cylinder sensors generally operate with low energy consumption and can therefore contribute to energy savings.
Overall, cylinder sensors offer an efficient and reliable solution for detecting movements and positions in cylindrical applications.
1. Space saving: Cylinder sensors are compact and can be installed directly in cylinders, saving additional space.
2. Cost efficiency: By integrating them into the cylinder, separate installation and cabling costs can be avoided.
3. Robustness: Cylinder sensors are generally shock-resistant and protected against external influences such as vibrations, dirt and moisture. This makes them durable and reliable.
4. Precision: Cylinder sensors offer high accuracy in the detection of positions, movements and other parameters. This means they can be used for precise control and regulation tasks.
5. Simple installation: The integration of cylinder sensors into the cylinder itself simplifies installation and commissioning. This reduces the time and effort required for setup.
6. Flexibility: Cylinder sensors are available in various versions tailored to different applications. They can be used for position, speed or pressure measurement, for example.
7. Energy efficiency: Cylinder sensors generally operate with low energy consumption and can therefore contribute to energy savings.
Overall, cylinder sensors offer an efficient and reliable solution for detecting movements and positions in cylindrical applications.
How are cylinder sensors used in industry and what areas of application are there?
Cylinder sensors are used in industry to monitor the condition of cylinders and detect the movement of pistons. You can measure various parameters such as position, speed, acceleration and forces.
A common area of application is the monitoring of pneumatic or hydraulic cylinders in machines and systems. Cylinder sensors can be used here, for example, to measure the stroke of a piston or to determine whether a cylinder is in the correct position.
Cylinder sensors are also used in robotics, where they are used to control movements and detect positions. They can be used in grippers, for example, to determine the exact position of an object to be gripped.
Other areas of application include automation technology, the manufacture of packaging machines, process automation and the food industry. In these areas, cylinder sensors can be used, for example, to monitor movements in conveyor belts, to control valves or to detect the position of workpieces.
Cylinder sensors are available in various designs, for example as inductive sensors, magnetic sensors, optical sensors or capacitive sensors. They can be selected according to the area of application and the requirements of the process.
A common area of application is the monitoring of pneumatic or hydraulic cylinders in machines and systems. Cylinder sensors can be used here, for example, to measure the stroke of a piston or to determine whether a cylinder is in the correct position.
Cylinder sensors are also used in robotics, where they are used to control movements and detect positions. They can be used in grippers, for example, to determine the exact position of an object to be gripped.
Other areas of application include automation technology, the manufacture of packaging machines, process automation and the food industry. In these areas, cylinder sensors can be used, for example, to monitor movements in conveyor belts, to control valves or to detect the position of workpieces.
Cylinder sensors are available in various designs, for example as inductive sensors, magnetic sensors, optical sensors or capacitive sensors. They can be selected according to the area of application and the requirements of the process.
What factors need to be considered when selecting and installing cylinder sensors?
Various factors must be taken into account when selecting and installing cylinder sensors:
1. Type of sensor: There are different types of cylinder sensors, such as inductive sensors, capacitive sensors, optical sensors or magnetic sensors. The appropriate sensor technology must be selected depending on the application and requirements.
2. Mounting options: Cylinder sensors can be attached to a cylinder in various ways, for example using threads, clamp mounts or magnetic attachments. The selected fastening method should match the cylinder design.
3. Detection range: The detection area of the sensor must be sufficiently dimensioned to cover the desired object area. It is important to ensure that the sensor reliably detects the object to be detected.
4. Ambient conditions: The ambient conditions in which the cylinder sensor is used play an important role. Factors such as humidity, temperature, dust or vibrations can affect the performance of the sensor. It is important to select a sensor that is suitable for the specific environmental conditions.
5. Connection type: The type of connection of the sensor to the control system must be taken into account. Depending on the application, different connection types such as cable connection, plug connectors or screw terminals may be available.
6. Electrical attributes: The electrical attributes of the sensor, such as operating voltage, output signal or switching frequency, must meet the requirements of the control system.
7. Assembly: Correct installation of the sensor is crucial for reliable operation. It is important to follow the manufacturer's installation instructions and ensure that the sensor is correctly positioned and attached.
8. Maintenance and servicing: The maintenance and servicing of the cylinder sensor should also be taken into account. It is important to ensure that the sensor is checked and cleaned regularly to ensure optimum performance.
These factors should be taken into account when selecting and installing cylinder sensors to ensure reliable and efficient operation. It can be helpful to seek advice from an expert or manufacturer when selecting and installing the system.
1. Type of sensor: There are different types of cylinder sensors, such as inductive sensors, capacitive sensors, optical sensors or magnetic sensors. The appropriate sensor technology must be selected depending on the application and requirements.
2. Mounting options: Cylinder sensors can be attached to a cylinder in various ways, for example using threads, clamp mounts or magnetic attachments. The selected fastening method should match the cylinder design.
3. Detection range: The detection area of the sensor must be sufficiently dimensioned to cover the desired object area. It is important to ensure that the sensor reliably detects the object to be detected.
4. Ambient conditions: The ambient conditions in which the cylinder sensor is used play an important role. Factors such as humidity, temperature, dust or vibrations can affect the performance of the sensor. It is important to select a sensor that is suitable for the specific environmental conditions.
5. Connection type: The type of connection of the sensor to the control system must be taken into account. Depending on the application, different connection types such as cable connection, plug connectors or screw terminals may be available.
6. Electrical attributes: The electrical attributes of the sensor, such as operating voltage, output signal or switching frequency, must meet the requirements of the control system.
7. Assembly: Correct installation of the sensor is crucial for reliable operation. It is important to follow the manufacturer's installation instructions and ensure that the sensor is correctly positioned and attached.
8. Maintenance and servicing: The maintenance and servicing of the cylinder sensor should also be taken into account. It is important to ensure that the sensor is checked and cleaned regularly to ensure optimum performance.
These factors should be taken into account when selecting and installing cylinder sensors to ensure reliable and efficient operation. It can be helpful to seek advice from an expert or manufacturer when selecting and installing the system.
How can cylinder sensors be used to monitor and control processes?
Cylinder sensors can be used to monitor and control processes in various ways. Here are some examples:
1. Position control: Cylinder sensors can be used to monitor the position of a cylinder in an automated process. You can determine whether the cylinder is in the correct position or whether it has moved. This can help to ensure that the process runs properly and possible errors are detected.
2. End position control: Cylinder sensors can also be used to monitor the end positions of a cylinder. You can determine whether the cylinder has reached its maximum extended position or its fully retracted position. This can help to prevent collisions or damage.
3. Speed control: Cylinder sensors can also be used to monitor the speed of a cylinder. You can determine whether the cylinder is moving too fast or too slow and this can be used to fine-tune the process.
4. Fill level control: In some processes, a cylinder is used to dose liquids or gases. Cylinder sensors can be used to monitor the level in the cylinder and ensure that the correct amount of liquid or gas is dispensed.
5. Error detection: Cylinder sensors can also be used for fault detection. You can determine whether a cylinder is not working properly or whether there are problems with the pressure, temperature or other parameters. This can help to ensure that problems are identified and rectified at an early stage before they lead to major problems.
Overall, cylinder sensors can play an important role in monitoring and controlling processes by providing precise and reliable information and helping to ensure that the process runs efficiently and safely.
1. Position control: Cylinder sensors can be used to monitor the position of a cylinder in an automated process. You can determine whether the cylinder is in the correct position or whether it has moved. This can help to ensure that the process runs properly and possible errors are detected.
2. End position control: Cylinder sensors can also be used to monitor the end positions of a cylinder. You can determine whether the cylinder has reached its maximum extended position or its fully retracted position. This can help to prevent collisions or damage.
3. Speed control: Cylinder sensors can also be used to monitor the speed of a cylinder. You can determine whether the cylinder is moving too fast or too slow and this can be used to fine-tune the process.
4. Fill level control: In some processes, a cylinder is used to dose liquids or gases. Cylinder sensors can be used to monitor the level in the cylinder and ensure that the correct amount of liquid or gas is dispensed.
5. Error detection: Cylinder sensors can also be used for fault detection. You can determine whether a cylinder is not working properly or whether there are problems with the pressure, temperature or other parameters. This can help to ensure that problems are identified and rectified at an early stage before they lead to major problems.
Overall, cylinder sensors can play an important role in monitoring and controlling processes by providing precise and reliable information and helping to ensure that the process runs efficiently and safely.
What future developments can be expected in cylinder sensors and how will they affect the industry?
Several future developments in cylinder sensors are expected to influence the industry:
1. Miniaturization: Cylinder sensors are becoming smaller and more compact so that they can be used in confined spaces. This enables a wider range of applications in various sectors, such as the automotive industry, robotics and medical technology.
2. Integrated intelligence: Future cylinder sensors will be equipped with increasing intelligence. They will be able to analyze and process data in order to carry out complex tasks autonomously. This enables them to monitor the condition of a cylinder, detect wear and predict maintenance requirements, for example.
3. Wireless communication: Cylinder sensors will increasingly be able to communicate wirelessly, which will simplify cabling and increase flexibility. This makes them easier to integrate into existing systems and enables more efficient data transmission.
4. Improved accuracy and reliability: Future cylinder sensors will provide more precise measurements and be more reliable. This is particularly important for applications that place high demands on accuracy and reliability, such as quality assurance in production.
These developments will influence the industry in many ways:
1. Increased efficiency: Production processes can be optimized and efficiency increased through the use of advanced cylinder sensors. For example, they can help to reduce energy consumption by precisely controlling the use of actuators.
2. Cost reduction: Advanced cylinder sensors enable better monitoring and prediction of maintenance requirements. This means that breakdowns can be avoided and planned maintenance work can be carried out, resulting in a reduction in costs.
3. Quality improvement: More precise measurements and greater reliability of the cylinder sensors contribute to an improvement in product quality. Errors can be detected and corrected more quickly, which reduces the reject rate.
4. Automation and robotics: The miniaturization and integrated intelligence of cylinder sensors create new possibilities for the use of robots and automated systems. They can carry out complex tasks autonomously and further increase productivity.
Overall, future developments in cylinder sensors will lead to further optimization and automation of production processes, resulting in a more efficient and competitive industry.
1. Miniaturization: Cylinder sensors are becoming smaller and more compact so that they can be used in confined spaces. This enables a wider range of applications in various sectors, such as the automotive industry, robotics and medical technology.
2. Integrated intelligence: Future cylinder sensors will be equipped with increasing intelligence. They will be able to analyze and process data in order to carry out complex tasks autonomously. This enables them to monitor the condition of a cylinder, detect wear and predict maintenance requirements, for example.
3. Wireless communication: Cylinder sensors will increasingly be able to communicate wirelessly, which will simplify cabling and increase flexibility. This makes them easier to integrate into existing systems and enables more efficient data transmission.
4. Improved accuracy and reliability: Future cylinder sensors will provide more precise measurements and be more reliable. This is particularly important for applications that place high demands on accuracy and reliability, such as quality assurance in production.
These developments will influence the industry in many ways:
1. Increased efficiency: Production processes can be optimized and efficiency increased through the use of advanced cylinder sensors. For example, they can help to reduce energy consumption by precisely controlling the use of actuators.
2. Cost reduction: Advanced cylinder sensors enable better monitoring and prediction of maintenance requirements. This means that breakdowns can be avoided and planned maintenance work can be carried out, resulting in a reduction in costs.
3. Quality improvement: More precise measurements and greater reliability of the cylinder sensors contribute to an improvement in product quality. Errors can be detected and corrected more quickly, which reduces the reject rate.
4. Automation and robotics: The miniaturization and integrated intelligence of cylinder sensors create new possibilities for the use of robots and automated systems. They can carry out complex tasks autonomously and further increase productivity.
Overall, future developments in cylinder sensors will lead to further optimization and automation of production processes, resulting in a more efficient and competitive industry.