| Applications | Medical devices Chemical industry Glass, Ceramics & Plastics Industry Electrical industry Precision mechanics & Optics Show all Automotive Aircraft & Spacecraft construction Rail vehicle construction Environmental & Energy technology |
| Protection class | IP65 |
| Signal output | 1,75 mV/V |
| Mounting | M 4 x 0,7 |
Force gauges
Force gauges are used for measuring tensile and compressive forces.
The measured force is specified in the unit N (newton). A newton is defined as the force that uniformly accelerates a resting body with a mass of 1 kg to a speed of 1 m/s in one second. ... Read more
The measured force is specified in the unit N (newton). A newton is defined as the force that uniformly accelerates a resting body with a mass of 1 kg to a speed of 1 m/s in one second. ... Read more
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| Applications | Medical devices Chemical industry Glass, Ceramics & Plastics Industry Electrical industry Precision mechanics & Optics Show all Automotive Aircraft & Spacecraft construction Rail vehicle construction Environmental & Energy technology |
| Protection class | IP65 |
| Signal output | 2,0 mV/V |
| Mounting | M 6 x 1,0 |
| Applications | Medical devices Chemical industry Glass, Ceramics & Plastics Industry Electrical industry Precision mechanics & Optics Show all Automotive Aircraft & Spacecraft construction Rail vehicle construction Environmental & Energy technology |
| Protection class | IP65 |
| Signal output | 2,0 mV/V |
| Mounting | M 5 x 0,8 |
| Applications | Medical devices Chemical industry Glass, Ceramics & Plastics Industry Electrical industry Precision mechanics & Optics Show all Automotive Aircraft & Spacecraft construction Rail vehicle construction Environmental & Energy technology |
| Protection class | IP65 |
| Signal output | 2,0 mV/V |
| Mounting | M 5 x 0,8 |
| Applications | Medical devices Chemical industry Glass, Ceramics & Plastics Industry Electrical industry Precision mechanics & Optics Show all Automotive Aircraft & Spacecraft construction Rail vehicle construction Environmental & Energy technology |
| Protection class | IP65 |
| Signal output | 2,0 mV/V |
| Mounting | M 4 x 0,7 |
| Applications | Medical devices Chemical industry Glass, Ceramics & Plastics Industry Electrical industry Precision mechanics & Optics Show all Automotive Aircraft & Spacecraft construction Rail vehicle construction Environmental & Energy technology |
| Protection class | IP65 |
| Signal output | 2,0 mV/V |
| Mounting | M 6 x 1,0 |
| Applications | Medical devices Chemical industry Glass, Ceramics & Plastics Industry Electrical industry Precision mechanics & Optics Show all Automotive Aircraft & Spacecraft construction Rail vehicle construction Environmental & Energy technology |
| Protection class | IP65 |
| Signal output | 2,0 mV/V |
| Mounting | M 4 x 0,7 |
| Applications | Medical devices Chemical industry Glass, Ceramics & Plastics Industry Electrical industry Precision mechanics & Optics Show all Automotive Aircraft & Spacecraft construction Rail vehicle construction Environmental & Energy technology |
| Protection class | IP65 |
| Signal output | 2,0 mV/V |
| Mounting | M 5 x 0,8 |
| Applications | Vehicles & Road Traffic Automotive Mechanical engineering & Plant construction |
| Type of force measurement | Compressive force |
| Measurement principle | Strain gauge |
| Measuring body material | Stainless materials |
| Applications | Aircraft & Spacecraft construction Rail vehicle construction Shipbuilding |
| Customized versions | Temperature range TEDS Connection cable length |
| Signal output | 2,5 mV/V |
| Protection class | IP54 |
| Applications | Aircraft & Spacecraft construction Rail vehicle construction Shipbuilding |
| Customized versions | Temperature range TEDS Connection cable length |
| Signal output | 2,0 mV/V |
| Protection class | IP54 |
| Applications | Aircraft & Spacecraft construction Rail vehicle construction Shipbuilding |
| Customized versions | Temperature range TEDS Connection cable length |
| Signal output | 2,0 mV/V |
| Protection class | IP54 |
| Applications | Aircraft & Spacecraft construction Rail vehicle construction Shipbuilding |
| Customized versions | Temperature range TEDS Connection cable length |
| Signal output | 1,0 mV/V |
| Protection class | IP54 |
| Applications | Aircraft & Spacecraft construction Rail vehicle construction Shipbuilding |
| Customized versions | Temperature range TEDS Connection cable length |
| Signal output | 1,0 mV/V |
| Protection class | IP54 |
| Applications | Aircraft & Spacecraft construction Rail vehicle construction Shipbuilding |
| Customized versions | Temperature range TEDS Connection cable length |
| Signal output | 2,5 mV/V |
| Protection class | IP54 |
| Applications | Aircraft & Spacecraft construction Rail vehicle construction Shipbuilding |
| Customized versions | Temperature range TEDS Connection cable length |
| Signal output | 1,0 mV/V |
| Protection class | IP54 |
| Applications | Aircraft & Spacecraft construction Rail vehicle construction Shipbuilding |
| Customized versions | Temperature range TEDS Connection cable length |
| Signal output | 2,0 mV/V |
| Protection class | IP54 |
| Applications | Automotive Aircraft & Spacecraft construction Rail vehicle construction Shipbuilding |
| Length | 1.7 mm |
| Type of force measurement | Compressive force |
| Measurement principle | Strain gauge, foil |
| Applications | Medical devices Chemical industry Glass, Ceramics & Plastics Industry Aircraft & Spacecraft construction Rail vehicle construction |
| Mounting | Three through-holes |
| Customized versions | Other versions on request TEDS |
| Typical applications | Friction forces |
| Applications | Medical devices Glass, Ceramics & Plastics Industry Precision mechanics & Optics Automotive Metal industry Show all Rail vehicle construction Shipbuilding Construction |
| Type of force measurement | Compressive force |
| Certificates/approvals | DKD calibration certificate Factory calibration certificate (optional) |
| Signal output | 1.5 mV/V |
Force measuring devices are an important component in many areas where forces need to be measured and analyzed. They are used in industry, sport, research and many other areas. Force gauges allow us to collect and analyze precise data about the applied force, which is crucial for the development and optimization of products and processes. There are different types of force measuring devices, each suitable for specific applications. One of the most common types are so-called strain gauges, which are applied to a body and stretch under load. The change in elongation is detected by the sensors and converted into electrical signals, which can then be measured and evaluated. Strain gauges are very precise and can measure large forces, but are sensitive to temperature fluctuations and can be damaged if overloaded. Hydraulic or pneumatic load cells, which are based on the principle of pressure measurement, are another type of force measuring device. These devices use liquids or gases to measure the applied force. The advantages of these devices are their robustness, their accuracy and their ability to measure large forces. However, they are often more expensive than strain gauges and require regular maintenance. Another interesting development in the field of force gauges is digital force gauges. These devices have integrated sensors and electronic circuits that convert the applied force directly into digital signals. Digital force gauges offer many advantages, such as higher accuracy, simple operation and fast data recording. They can also communicate wirelessly with other devices, enabling seamless integration into complex measuring systems. Force measuring devices are of great importance for quality assurance and product development in industry. They make it possible to monitor the force applied during the production process and ensure that the products meet the required standards. Force measuring devices are also used in sport to measure and improve the performance of athletes. In research, they are used to investigate the effects of forces on materials and structures. Overall, force measuring devices play a crucial role in many areas and enable us to precisely measure and analyze forces. They are indispensable tools for engineers, scientists and athletes and contribute to the development of high-quality products, the optimization of processes and the improvement of performance.
What are force gauges and what are they used for?
Force gauges are devices that are used to measure the force exerted on a sample or a body. They are used to measure and monitor forces in various applications, including:
1. Research and development: Force gauges are used in materials testing to measure the strength and load-bearing capacity of materials. They can also be used in the development of new products to measure the forces acting on the product during use.
2. Industrial applications: In industry, force measuring devices are used to measure the forces that occur in certain processes or machines. This can help to improve efficiency, ensure safety and identify potential problems.
3. Medical applications: Strength measuring devices are used in medicine to measure muscle strength and monitor the rehabilitation of patients. They can also be used in prosthetics to check the functionality of prostheses.
4. Sport and fitness: In the sports and fitness industry, strength measuring devices are used to measure the strength and performance of athletes. They can also be used to monitor progress in the rehabilitation of injuries.
5. Automotive industry: In the automotive industry, force measuring devices are used to measure the forces acting on various components such as brakes, suspensions and steering systems. This helps in the development and testing of vehicle performance and safety.
Overall, force measuring devices are used to measure the force exerted on a sample or body and provide important data for various applications in different industries.
1. Research and development: Force gauges are used in materials testing to measure the strength and load-bearing capacity of materials. They can also be used in the development of new products to measure the forces acting on the product during use.
2. Industrial applications: In industry, force measuring devices are used to measure the forces that occur in certain processes or machines. This can help to improve efficiency, ensure safety and identify potential problems.
3. Medical applications: Strength measuring devices are used in medicine to measure muscle strength and monitor the rehabilitation of patients. They can also be used in prosthetics to check the functionality of prostheses.
4. Sport and fitness: In the sports and fitness industry, strength measuring devices are used to measure the strength and performance of athletes. They can also be used to monitor progress in the rehabilitation of injuries.
5. Automotive industry: In the automotive industry, force measuring devices are used to measure the forces acting on various components such as brakes, suspensions and steering systems. This helps in the development and testing of vehicle performance and safety.
Overall, force measuring devices are used to measure the force exerted on a sample or body and provide important data for various applications in different industries.
How do force measuring devices work and what technologies are used?
Force measuring devices are used to measure the force exerted on a body. There are various technologies that can be used for this:
1. Spring scales: Spring scales use a spring that expands or contracts when a force is applied. The deflection of the spring is measured and converted into a force. This type of force gauge is simple and inexpensive, but has limited accuracy.
2. Strain gages: Strain gauges are thin metal foils that are stuck or glued to the body. When a force is applied to the body, the shape of the strain gauge changes and so does its electrical resistance. This change in resistance is measured and converted into a force. Strain gauges offer greater accuracy than spring balances.
3. Piezoelectric sensors: Piezoelectric sensors use materials that generate an electrical charge when a force is applied. This charge is measured and converted into a force. Piezoelectric sensors have very high accuracy and are able to detect rapid changes in force.
4. Hydraulic or pneumatic force measuring devices: These devices use liquids or gases to measure the force exerted on the body. The force is transferred to a piston or diaphragm, which leads to a change in pressure. This change in pressure is measured and converted into a force. Hydraulic or pneumatic force measuring devices offer high accuracy and are capable of measuring large forces.
The selection of the appropriate technology depends on the specific requirements of the application, such as the required accuracy, the size of the area to be measured and the speed of the force changes.
1. Spring scales: Spring scales use a spring that expands or contracts when a force is applied. The deflection of the spring is measured and converted into a force. This type of force gauge is simple and inexpensive, but has limited accuracy.
2. Strain gages: Strain gauges are thin metal foils that are stuck or glued to the body. When a force is applied to the body, the shape of the strain gauge changes and so does its electrical resistance. This change in resistance is measured and converted into a force. Strain gauges offer greater accuracy than spring balances.
3. Piezoelectric sensors: Piezoelectric sensors use materials that generate an electrical charge when a force is applied. This charge is measured and converted into a force. Piezoelectric sensors have very high accuracy and are able to detect rapid changes in force.
4. Hydraulic or pneumatic force measuring devices: These devices use liquids or gases to measure the force exerted on the body. The force is transferred to a piston or diaphragm, which leads to a change in pressure. This change in pressure is measured and converted into a force. Hydraulic or pneumatic force measuring devices offer high accuracy and are capable of measuring large forces.
The selection of the appropriate technology depends on the specific requirements of the application, such as the required accuracy, the size of the area to be measured and the speed of the force changes.
What different types of force gauges are there and what attributes do they have?
There are different types of force gauges, which have different attributes depending on the area of application. Here are some common types of force gauges:
1. Spring balance: A spring balance is a simple mechanical force measuring device that uses a spring to measure the force exerted on it. It is easy to use and inexpensive, but its accuracy is limited.
2. Dynamometer: A dynamometer measures the forces that occur during a movement or process. For example, it can be used to measure the tractive force of a vehicle or the load on an engine. Dynamometers can be mechanical or electronic and generally offer greater accuracy than spring balances.
3. Pressure gauge: A pressure gauge is used to measure pressure forces, such as those that occur in hydraulic or pneumatic systems. There are different types of pressure measuring devices, such as pressure gauges or pressure transmitters, which have different attributes depending on the application.
4. Sample force gauge: Specimen dynamometers are used in material testing to measure the strength or load-bearing capacity of a material. They can measure tensile forces, compression forces or bending forces and generally offer high accuracy and precision.
5. Voltmeter: A tension meter measures the tension exerted on a material. It is often used in materials testing to measure the elongation or deformation of a material under load. Voltmeters can be mechanical or electronic and offer high accuracy.
This list is not exhaustive and there are many other types of force gauges that have been developed depending on the specific application. Choosing the right force gauge depends on the specific requirements of the application, including the required accuracy, measuring ranges and environmental conditions.
1. Spring balance: A spring balance is a simple mechanical force measuring device that uses a spring to measure the force exerted on it. It is easy to use and inexpensive, but its accuracy is limited.
2. Dynamometer: A dynamometer measures the forces that occur during a movement or process. For example, it can be used to measure the tractive force of a vehicle or the load on an engine. Dynamometers can be mechanical or electronic and generally offer greater accuracy than spring balances.
3. Pressure gauge: A pressure gauge is used to measure pressure forces, such as those that occur in hydraulic or pneumatic systems. There are different types of pressure measuring devices, such as pressure gauges or pressure transmitters, which have different attributes depending on the application.
4. Sample force gauge: Specimen dynamometers are used in material testing to measure the strength or load-bearing capacity of a material. They can measure tensile forces, compression forces or bending forces and generally offer high accuracy and precision.
5. Voltmeter: A tension meter measures the tension exerted on a material. It is often used in materials testing to measure the elongation or deformation of a material under load. Voltmeters can be mechanical or electronic and offer high accuracy.
This list is not exhaustive and there are many other types of force gauges that have been developed depending on the specific application. Choosing the right force gauge depends on the specific requirements of the application, including the required accuracy, measuring ranges and environmental conditions.
Who uses force measuring devices and in which areas are they used?
Force measuring devices are used by various professionals and in different areas. Here are some examples:
1. Engineers and designers: Force measuring devices are used by engineers and designers to measure the load and stability of structures, machines or products. This helps them to ensure the correct dimensioning and strength for their constructions.
2. Researchers and scientists: Force measuring devices are used in research and science to investigate the effects of forces on various materials and biological systems. For example, in biomechanics, to measure the forces that act on the body when running or lifting.
3. Athletes and trainers: Strength measuring devices are used in the sports sector to measure and improve the performance of athletes. They can be used, for example, to monitor strength development or measure muscle activity during training.
4. Medical professionals: Strength measuring devices are used in medicine to measure the muscle strength of patients and to monitor rehabilitation. They can also be used in prosthetics to measure and adjust the force and control of prostheses.
5. Manufacturer and quality control: Force gauges are used in manufacturing and quality control to ensure that products meet the required standards. For example, when testing the strength of components or monitoring the tensile strength of materials.
These are just a few examples, but there are many other areas in which force measuring devices can be used, depending on the specific requirements and needs.
1. Engineers and designers: Force measuring devices are used by engineers and designers to measure the load and stability of structures, machines or products. This helps them to ensure the correct dimensioning and strength for their constructions.
2. Researchers and scientists: Force measuring devices are used in research and science to investigate the effects of forces on various materials and biological systems. For example, in biomechanics, to measure the forces that act on the body when running or lifting.
3. Athletes and trainers: Strength measuring devices are used in the sports sector to measure and improve the performance of athletes. They can be used, for example, to monitor strength development or measure muscle activity during training.
4. Medical professionals: Strength measuring devices are used in medicine to measure the muscle strength of patients and to monitor rehabilitation. They can also be used in prosthetics to measure and adjust the force and control of prostheses.
5. Manufacturer and quality control: Force gauges are used in manufacturing and quality control to ensure that products meet the required standards. For example, when testing the strength of components or monitoring the tensile strength of materials.
These are just a few examples, but there are many other areas in which force measuring devices can be used, depending on the specific requirements and needs.
What advantages do force gauges offer over other measuring methods?
Force gauges offer several advantages over other measuring methods:
1. Precise measurements: Force measuring devices are able to accurately measure force in various units such as newtons or kilograms. This allows accurate and reliable measurements to be carried out.
2. Easy handling: Force gauges are generally easy to use and do not require complex settings or calibrations. This means they can be easily used by different people.
3. Versatility: Force measuring devices can be used in various applications, for example in materials testing, in manufacturing or in the field of ergonomics. They can also be used for different types of force such as tensile, compressive or bending forces.
4. Real-time measurements: Force measuring devices provide measurement results in real time, which enables a quick overview of the current force. This means that errors or deviations can be detected and corrected immediately.
5. Data analysis: Many force measuring devices have integrated functions for recording and analyzing measurement data. This allows trends and patterns to be recognized in order to improve performance or identify potential problems.
6. Non-invasive measurements: Force measuring devices often enable non-invasive measurements that do not require direct contact with the object to be measured. This can be particularly advantageous if sensitive materials or surfaces are to be tested.
1. Precise measurements: Force measuring devices are able to accurately measure force in various units such as newtons or kilograms. This allows accurate and reliable measurements to be carried out.
2. Easy handling: Force gauges are generally easy to use and do not require complex settings or calibrations. This means they can be easily used by different people.
3. Versatility: Force measuring devices can be used in various applications, for example in materials testing, in manufacturing or in the field of ergonomics. They can also be used for different types of force such as tensile, compressive or bending forces.
4. Real-time measurements: Force measuring devices provide measurement results in real time, which enables a quick overview of the current force. This means that errors or deviations can be detected and corrected immediately.
5. Data analysis: Many force measuring devices have integrated functions for recording and analyzing measurement data. This allows trends and patterns to be recognized in order to improve performance or identify potential problems.
6. Non-invasive measurements: Force measuring devices often enable non-invasive measurements that do not require direct contact with the object to be measured. This can be particularly advantageous if sensitive materials or surfaces are to be tested.
How accurate are force measuring devices and how are the measurement results interpreted?
Force gauges are devices that are used to measure the force exerted on a body. They usually consist of a sensor unit that records the force and a display or recording device that displays or records the measured values.
There are various types of force measuring devices, including strain gauges, hydraulic or pneumatic sensors, piezoelectric sensors and electromagnetic sensors. Each type has its own advantages and disadvantages and is selected according to the area of application.
The measurement results of a force measuring device are normally given in Newtons (N) or kilograms (kg), as these are the units for force. The measurements can be recorded either as a static force (constant force) or as a dynamic force (changing force over time).
The interpretation of the measurement results depends on the specific application. In some cases, the measured force can be used directly to monitor or control a system. In other cases, the measurement results can be used to calculate other parameters such as pressure, torque or acceleration.
The accuracy of force gauges depends on various factors, such as calibration, the quality of the sensor and the evaluation technology. It is important to ensure that the force gauge is regularly calibrated and maintained to ensure accurate measurement results.
There are various types of force measuring devices, including strain gauges, hydraulic or pneumatic sensors, piezoelectric sensors and electromagnetic sensors. Each type has its own advantages and disadvantages and is selected according to the area of application.
The measurement results of a force measuring device are normally given in Newtons (N) or kilograms (kg), as these are the units for force. The measurements can be recorded either as a static force (constant force) or as a dynamic force (changing force over time).
The interpretation of the measurement results depends on the specific application. In some cases, the measured force can be used directly to monitor or control a system. In other cases, the measurement results can be used to calculate other parameters such as pressure, torque or acceleration.
The accuracy of force gauges depends on various factors, such as calibration, the quality of the sensor and the evaluation technology. It is important to ensure that the force gauge is regularly calibrated and maintained to ensure accurate measurement results.
What factors influence the accuracy and reliability of force gauges?
The accuracy and reliability of force gauges can be influenced by various factors, including
1. Calibration: Regular calibration of the device is crucial to ensure that it provides correct readings. Incorrect calibration can lead to incorrect results.
2. Sensor quality: The quality of the sensor used is an important factor. High-quality sensors generally provide more accurate and reliable measurements than inferior sensors.
3. Ambient conditions: The ambient conditions, such as temperature, humidity and vibrations, can influence the measurements. It is important that the force measuring device is suitable for the respective ambient conditions.
4. Application type: Depending on the type of application, certain factors can influence the measuring accuracy. For example, the friction between the objects to be measured can distort the measurements.
5. Operating error: Errors when operating the force gauge can lead to inaccurate measurements. It is important that the appliance is used properly and that the user is informed about the correct handling.
6. Ageing and wear: Over time, force gauges can wear out and lose their accuracy. Regular maintenance and, if necessary, replacement of parts can maintain the reliability of the appliance.
These factors should be taken into account when selecting and using force gauges to ensure accurate and reliable measurements.
1. Calibration: Regular calibration of the device is crucial to ensure that it provides correct readings. Incorrect calibration can lead to incorrect results.
2. Sensor quality: The quality of the sensor used is an important factor. High-quality sensors generally provide more accurate and reliable measurements than inferior sensors.
3. Ambient conditions: The ambient conditions, such as temperature, humidity and vibrations, can influence the measurements. It is important that the force measuring device is suitable for the respective ambient conditions.
4. Application type: Depending on the type of application, certain factors can influence the measuring accuracy. For example, the friction between the objects to be measured can distort the measurements.
5. Operating error: Errors when operating the force gauge can lead to inaccurate measurements. It is important that the appliance is used properly and that the user is informed about the correct handling.
6. Ageing and wear: Over time, force gauges can wear out and lose their accuracy. Regular maintenance and, if necessary, replacement of parts can maintain the reliability of the appliance.
These factors should be taken into account when selecting and using force gauges to ensure accurate and reliable measurements.