What is a Load Cell?
A load cell is a transducer or sensor that is used to convert a mechanical force or load into an electrical signal. It is a critical component in various applications where the measurement of force, weight, or tension is required. Load cells are commonly used in industrial, scientific, and commercial settings to obtain accurate and reliable measurements of forces or loads.
Here are the key components and functions of a load cell:
Strain Gauges: Load cells typically contain one or more strain gauges, which are thin, wire-like devices that are bonded or attached to a structural element within the load cell. Strain gauges are designed to deform when subjected to mechanical force, and this deformation results in a change in electrical resistance.
Wheatstone Bridge Circuit: Strain gauges are configured in a Wheatstone bridge circuit, which is an electrical circuit that can detect small changes in resistance. When force is applied to the load cell, the strain gauges experience deformation, causing a change in resistance. This change in resistance leads to an imbalance in the Wheatstone bridge, generating an electrical output signal.
Output Signal: The electrical output signal produced by the load cell is typically very low in magnitude, often in the millivolt (mV) range. This signal is proportional to the applied force or load and can be further processed and amplified to obtain meaningful measurements.
Calibration: Load cells must be calibrated to ensure accurate and consistent measurements. Calibration involves applying known forces to the load cell and recording the corresponding output signals. This calibration data is used to establish a relationship between the applied force and the output signal.
Types of Load Cells: There are various types of load cells, each designed for specific applications and load measurement requirements. Common types include:
Strain Gauge Load Cells: These load cells use strain gauges to measure the deformation caused by the applied force. They are suitable for a wide range of applications and are available in various configurations, including bending beam, shear beam, and single-point designs.
Compression Load Cells: Designed to measure forces that compress the load cell along its central axis, compression load cells are often used in applications like platform scales and industrial weighing.
Tension Load Cells: These load cells are designed to measure forces that pull or stretch the load cell, making them suitable for applications like crane scales and tensile testing.
Shear Beam Load Cells: Shear beam load cells are commonly used in industrial scales and conveyor systems to measure forces applied parallel to the load cell's mounting surface.
Bending Beam Load Cells: Bending beam load cells are versatile and used in applications such as floor scales and batching systems.
S-Type Load Cells: Shaped like the letter "S," these load cells can be used for both tension and compression measurements.
Load cells find applications in various industries, including manufacturing, aerospace, automotive, healthcare, agriculture, and more. They are crucial for tasks such as weight measurement, force monitoring, quality control, and process automation, contributing to increased accuracy, efficiency, and safety in numerous processes and systems..
How does a Load Cell work?
A load cell works on the principle of converting an applied mechanical force or load into an electrical signal. It accomplishes this by utilizing one or more strain gauges, which are devices that change their electrical resistance in response to mechanical deformation. Here's a step-by-step explanation of how a load cell works:
Strain Gauges: Load cells typically incorporate one or more strain gauges, which are small sensors made of thin wires or foil elements. These strain gauges are bonded or attached to a structural element within the load cell, such as a beam or diaphragm.
Wheatstone Bridge Circuit: The strain gauges are arranged in a Wheatstone bridge circuit, which is an electrical circuit designed to measure small changes in resistance. The Wheatstone bridge consists of four resistors, with the strain gauges forming two of them. The other two resistors are typically fixed or have a known resistance value.
Zero Load State: When there is no load applied to the load cell (the "zero load" or "no force" state), the strain gauges are in their initial, undeformed condition, and their resistance values are stable.
Application of Load: When a mechanical force or load is applied to the load cell, it causes deformation or strain in the structural element to which the strain gauges are attached. This deformation results in a change in the resistance of the strain gauges.
Imbalance in the Wheatstone Bridge: The change in resistance of the strain gauges creates an imbalance in the Wheatstone bridge circuit. As a result, there is an output voltage or electrical signal generated across the bridge's output terminals. The magnitude and polarity of this output signal are proportional to the applied force or load.
Signal Amplification and Conditioning: The electrical output signal produced by the Wheatstone bridge is typically very low in magnitude, often in the millivolt (mV) range. To obtain useful measurements, the signal is amplified and conditioned using signal conditioning circuits. This may involve amplifying the signal, filtering out noise, and compensating for temperature variations.
Calibration: Load cells are calibrated to establish a linear relationship between the applied force and the output signal. During calibration, known forces are applied to the load cell, and the corresponding output signals are recorded. This calibration data is used to create calibration curves or equations for accurate force measurement.
Output Signal: The amplified and conditioned electrical signal is then available for measurement, display, recording, or control purposes. Depending on the application, load cell signals can be analog (voltage or current) or digital.
Accuracy and Resolution: The accuracy and resolution of a load cell depend on factors such as the quality of the strain gauges, the design of the load cell, the calibration process, and the signal conditioning. High-quality load cells are capable of providing accurate and precise measurements.
Load cells come in various types, including compression load cells, tension load cells, shear beam load cells, and more, each designed for specific force measurement applications. They are widely used in industries such as manufacturing, automotive, aerospace, healthcare, and research to measure forces, weights, and loads accurately and reliably.
Load Cell Choices
How to choose the correct Load Cell and compatible instrument for your load or force measurement application?
Our application sales engineers do this day in and out, with years of experience so please don’t hesitate to give us a call to help you though this process, that’s what we are here for. But it all comes down to your budget, your application, what stage your application is in, and how quickly you need your load cell system.
Let me start with a few easy applications and I will follow it by a layout of things you should consider in your load cell selection process.
If you need to perform a quick one time test to verify a load or force on a component or to prove an application, you might choose an inexpensive load beam load cell with a precision power supply and a voltmeter. We can help.
If you’re designing a Test machine you would choose a load cell based upon the overall system accuracy. Is the measurement static or dynamic? Do you require a digital display or just an amplifier signal conditioner module for a data acquisition system? We can help.
If your application is on a race car suspension system recording real time data while testing the car on an actual race track, like the Cornell racing team in one of our featured videos, you would need a load cell that could perform in a dynamic application and be able to handle extraneous loads like our MLP series load cell did. We double the normal load capacity of the load cell (which is a good rule of thumb in dynamic loading applications) and still exceeded the accuracy they required. We supplied our TM0-1 amplifier signal conditioner module that sent high speed data to their on board data acquisition system. We also designed a custom load pin load cell to measure the torque on the drive train. In some applications going with a custom load cell makes more sense.
National Geographic had an application on one of their super human strength episodes where they needed to measure the force of a strong man pulling a Semi tractor trailer (featured in our video gallery) that they were filming the next day. We choose the HSW-20k load cell with the smart plug and play option (also known as our Cal-Teds option) because of the accuracy and the ease of placing it in the application. We supplied our smart plug and play DPM-3 load cell meter with an analog output option that sent real time data to their data acquisition system that they were pushing in a cart alongside of the test. Having the Cal-Teds option on the load cell allowed the load cell and the smart plug and play DPM-3 meter to automatically perform a system calibration by just plugging them together (meter reads the EPPROM chip in the Cal-Teds option that populates an IEEE 1451.4 template 33 calibrating the system instantly). We generally don’t recommend pushing a cart alongside of a test, but this was already taking place for other equipment. This was a very inexpensive load cell system that allowed them to film the next day as planned.
Below is a list of things to consider when selecting a load cell for your load / force measurement requirement:
Step 1
Price and availability are normally the first two things to consider. If you’re on a limited budget or need something the next day this may narrow your selection. However Transducer Techniques does offer educational discounts and we stock our standard products ready for next day shipping.
Step 2
Define how you want to conduct the measurement and how you will apply the load. Will your loading be static or dynamic? A dynamic application usually requires a load cell with a higher frequency response (a good rule of thumb is the lower the load cell deflection the high the frequency response). Will you be loading the load cell in-line or require a load cell that can handle extraneous loads? Will you be measuring bending, tension or compression or both, multi-axis such as thrust and torque?
Step 3
Define how this load cell will be mounted in your application. Do you require male or female threads or a flange mount? Do you need a through hole or compression load washer load cell that allows a structure to pass through the load cell?
Step 4
Define the environment in which the load cell is intended to be used in (laboratory, warehouse, outdoors, underwater). For extended outdoor use or in a marine environment or for underwater use, we recommend a hermetically seal load cell.
Step 5
Define the overall accuracy, output, bridge resistance, nonlinearity, hysteresis, nonrepeatability, frequency response.
Step 6
Define if there are any special options required, such as, connectors, addition cable lengths, high temperature,or if Cal-Teds (plug and play smart load cell option) is required.
Step 7
Define if load cell instrumentation is required. From a precision power supply, to an amplifier signal conditioner module, to a digital display with alarms, analog output or data logging, we have economical solutions for your load cell instrument requirements.
In summary, for someone using a load cell for the first time this can be overwhelming. But this is what we enjoy doing and we are always here for you. Please allow us to help you select the right load cell from installation, to setup, we will be here to assist you every step of the way.
THA Series Load Cell Applications.
The Transducer Techniques THA Series through-hole donut load cells, characterized by their compact design and multiple through-hole diameter options, find applications in various industries and scenarios where precise force measurement is essential. Manufactured from heat-treated 17-4 PH stainless steel, these load cells offer durability and reliability. Here are specific applications where the THA Series load cells are commonly used:
1. Force and Torque Measurement: The THA Series load cells are frequently used in force and torque measurement applications, including bench testing of motors, engines, and various mechanical components. They provide accurate data on forces and torques applied in both tension and compression modes.
2. Automotive Testing: Automotive manufacturers and testing facilities utilize THA Series load cells for testing and quality control of various vehicle components, such as suspension systems, steering mechanisms, and brake systems. These load cells help evaluate the performance and safety of automotive parts.
3. Robotics and Automation: THA Series load cells are integrated into robotic and automation systems for tasks that involve force sensing, such as robot end-effector force control, pick-and-place operations, and assembly line quality checks.
4. Materials Testing: In materials testing laboratories, THA Series load cells are used for various applications, including tensile and compressive testing of materials such as metals, plastics, textiles, and rubber. They provide data on material strength and deformation characteristics.
5. Aerospace and Aircraft Testing: The aerospace industry relies on THA Series load cells for structural testing of aircraft components, flight control systems, and materials used in aircraft construction. These load cells contribute to ensuring the reliability and safety of aerospace equipment.
6. Industrial Automation: THA Series load cells are integrated into industrial automation systems for monitoring and controlling forces in manufacturing processes, ensuring precise assembly and quality control in industries such as electronics and consumer goods manufacturing.
7. Product Development: Engineers and researchers use THA Series load cells during product development and prototyping. They assist in evaluating the performance and durability of new designs and components.
8. Biomechanics and Medical Devices: In biomechanics research and medical device testing, THA Series load cells measure forces applied to the human body or medical devices during testing and analysis. This is crucial for understanding physiological processes and validating medical equipment.
9. Educational Laboratories: Educational institutions incorporate THA Series load cells into engineering and physics laboratories to teach students about force measurement principles and conduct experiments related to mechanics and materials science.
10. Custom Machinery and Equipment: Manufacturers and research facilities integrate THA Series load cells into custom-built machinery and equipment designed for specialized testing and manufacturing processes that require precise force measurement.
The Transducer Techniques THA Series through-hole donut load cells, with their compact and versatile design, are valuable tools in a wide range of industries and applications where accurate force measurement is critical for safety, quality, and performance assessment. Their multiple through-hole diameter options make them adaptable to various testing and monitoring scenarios.
THB Series Load Cell Applications.
The Transducer Techniques THB Series through-hole donut load cell, characterized by their versatile design with multiple through-hole diameter options and made from heat-treated 17-4 PH stainless steel, are well-suited for various applications where precise force measurement is essential. Here are specific applications where the THB Series load cells are commonly used:
1. Industrial Automation: THB Series load cells are integrated into industrial automation systems for monitoring and controlling forces in robotic applications, material handling processes, and manufacturing operations. They ensure precise assembly and quality control in industries such as automotive, electronics, and consumer goods manufacturing.
2. Robotics and Automation: These load cells are used in robotics and automation systems for force sensing applications, such as robot end-effector force control, pick-and-place operations, and quality checks on assembly lines.
3. Force and Torque Measurement: THB Series load cells are employed for force and torque measurement tasks in research, testing, and quality control across various industries. They provide accurate data on forces and torques applied in both tension and compression modes.
4. Materials Testing: In materials testing laboratories, THB Series load cells are used for various testing applications, including tensile and compressive testing of materials such as metals, plastics, ceramics, and composites. They help assess material properties and product quality.
5. Automotive Testing: Automotive manufacturers and testing facilities use THB Series load cells for quality control and testing of vehicle components, including suspension systems, steering mechanisms, and brake systems. These load cells contribute to evaluating the performance and safety of automotive parts.
6. Aerospace and Aircraft Testing: The aerospace industry relies on THB Series load cells for structural testing of aircraft components, flight control systems, and materials used in aircraft construction. They play a crucial role in ensuring the reliability and safety of aerospace equipment.
7. Product Development: Engineers and researchers use THB Series load cells during product development and prototyping. They assist in evaluating the performance, durability, and structural integrity of new designs and components.
8. Biomechanics and Medical Devices: In biomechanics research and medical device testing, THB Series load cells measure forces applied to the human body or medical devices during experiments and analysis. This data is vital for understanding physiological processes and validating medical equipment.
9. Educational Laboratories: Educational institutions incorporate THB Series load cells into engineering and physics laboratories to teach students about force measurement principles and conduct experiments related to mechanics and materials science.
10. Custom Machinery and Equipment: Manufacturers and research facilities integrate THB Series load cells into custom-built machinery and equipment designed for specialized testing and manufacturing processes that require precise force measurement.
The Transducer Techniques THB Series through-hole donut load cells, with their versatile design and multiple through-hole diameter options, are valuable tools across a wide range of industries and applications where accurate and reliable force measurement is crucial for safety, quality, and performance assessment.
THC Series Load Cell Applications.
The Transducer Techniques THC Series through-hole donut load cells, featuring multiple through-hole diameter options and constructed from heat-treated 17-4 PH stainless steel, have diverse applications across various industries where precise force measurement is critical. Here are specific applications where the THC Series load cells are commonly used:
1. Industrial Automation: THC Series load cells are integrated into industrial automation systems for monitoring and controlling forces in robotic applications, material handling processes, and manufacturing operations. They ensure precise assembly and quality control in industries such as automotive, electronics, and consumer goods manufacturing.
2. Robotics and Automation: These load cells are used in robotics and automation systems for force sensing applications, including robot end-effector force control, pick-and-place operations, and quality checks on assembly lines.
3. Force and Torque Measurement: THC Series load cells are essential for precise force and torque measurement in research, testing, and quality control across various industries. They provide accurate data on forces and torques applied in both tension and compression modes.
4. Materials Testing: In materials testing laboratories, THC Series load cells are employed for various testing applications, including tensile and compressive testing of materials such as metals, plastics, ceramics, and composites. They help assess material properties and product quality.
5. Automotive Testing: Automotive manufacturers and testing facilities use THC Series load cells for quality control and testing of vehicle components, such as suspension systems, steering mechanisms, and brake systems. These load cells contribute to evaluating the performance and safety of automotive parts.
6. Aerospace and Aircraft Testing: The aerospace industry relies on THC Series load cells for structural testing of aircraft components, flight control systems, and materials used in aircraft construction. They play a crucial role in ensuring the reliability and safety of aerospace equipment.
7. Product Development: Engineers and researchers use THC Series load cells during product development and prototyping. They assist in evaluating the performance, durability, and structural integrity of new designs and components.
8. Biomechanics and Medical Devices: In biomechanics research and medical device testing, THC Series load cells measure forces applied to the human body or medical devices during experiments and analysis. This data is vital for understanding physiological processes and validating medical equipment.
9. Educational Laboratories: Educational institutions incorporate THC Series load cells into engineering and physics laboratories to teach students about force measurement principles and conduct experiments related to mechanics and materials science.
10. Custom Machinery and Equipment: Manufacturers and research facilities integrate THC Series load cells into custom-built machinery and equipment designed for specialized testing and manufacturing processes that require precise force measurement.
The Transducer Techniques THC Series through-hole donut load cells, with their versatile design and multiple through-hole diameter options, are valuable tools across a wide range of industries and applications where accurate and reliable force measurement is crucial for safety, quality, and performance assessment.
THD Series Load Cell Applications.
The Transducer Techniques THD Series through-hole donut load cells, featuring a versatile design with multiple through-hole diameter options and constructed from heat-treated 17-4 PH stainless steel, have diverse applications across various industries where precise force measurement is crucial. Here are specific applications where the THD Series load cells are commonly used:
1. Industrial Automation: THD Series load cells are integrated into industrial automation systems for monitoring and controlling forces in robotic applications, material handling processes, and manufacturing operations. They ensure precise assembly and quality control in industries such as automotive, electronics, and consumer goods manufacturing.
2. Robotics and Automation: These load cells are used in robotics and automation systems for force sensing applications, including robot end-effector force control, pick-and-place operations, and quality checks on assembly lines.
3. Force and Torque Measurement: THD Series load cells are essential for precise force and torque measurement in research, testing, and quality control across various industries. They provide accurate data on forces and torques applied in both tension and compression modes.
4. Materials Testing: In materials testing laboratories, THD Series load cells are employed for various testing applications, including tensile and compressive testing of materials such as metals, plastics, ceramics, and composites. They help assess material properties and product quality.
5. Automotive Testing: Automotive manufacturers and testing facilities use THD Series load cells for quality control and testing of vehicle components, such as suspension systems, steering mechanisms, and brake systems. These load cells contribute to evaluating the performance and safety of automotive parts.
6. Aerospace and Aircraft Testing: The aerospace industry relies on THD Series load cells for structural testing of aircraft components, flight control systems, and materials used in aircraft construction. They play a crucial role in ensuring the reliability and safety of aerospace equipment.
7. Product Development: Engineers and researchers use THD Series load cells during product development and prototyping. They assist in evaluating the performance, durability, and structural integrity of new designs and components.
8. Biomechanics and Medical Devices: In biomechanics research and medical device testing, THD Series load cells measure forces applied to the human body or medical devices during experiments and analysis. This data is vital for understanding physiological processes and validating medical equipment.
9. Educational Laboratories: Educational institutions incorporate THD Series load cells into engineering and physics laboratories to teach students about force measurement principles and conduct experiments related to mechanics and materials science.
10. Custom Machinery and Equipment: Manufacturers and research facilities integrate THD Series load cells into custom-built machinery and equipment designed for specialized testing and manufacturing processes that require precise force measurement.
The Transducer Techniques THD Series through-hole donut load cells, with their versatile design and multiple through-hole diameter options, are valuable tools across a wide range of industries and applications where accurate and reliable force measurement is crucial for safety, quality, and performance assessment.
LWO Series Load Cell Applications.
The Transducer Techniques LWO Series washer-shaped, strain gauge-based load cells are specialized devices with applications in fastener testing and through-hole load measurement scenarios. These load cells, designed for precision and durability, are primarily used in industries and applications where the measurement of compressive forces applied to bolts, fasteners, and through-holes is critical. Here are some specific applications where the LWO Series load cells excel:
1. Fastener Testing: The LWO Series load cells are commonly used in fastener testing applications, where they measure the compressive forces experienced by bolts, screws, and other fasteners during tightening, torque testing, and quality control. These load cells help ensure that fasteners meet specified torque and load requirements.
2. Structural Testing: These load cells are applied in structural testing scenarios, including load-bearing bolted connections in buildings, bridges, and other infrastructure. They provide data on the load distribution and performance of such connections, contributing to structural safety assessments.
3. Construction and Civil Engineering: In the construction and civil engineering industries, LWO Series load cells are used to assess the integrity of anchor bolts, foundation bolts, and other critical connections. They help verify that these components can withstand the expected loads.
4. Heavy Machinery and Equipment: The load cells find applications in the testing of heavy machinery and equipment that relies on bolted connections for structural integrity. This includes cranes, hoists, and industrial machinery.
5. Aerospace and Aircraft Assembly: The aerospace industry uses LWO Series load cells to measure the compressive forces applied to aircraft fasteners, ensuring that connections in critical areas are secure and compliant with safety standards.
6. Automotive and Manufacturing: In manufacturing and automotive assembly lines, LWO Series load cells are employed to monitor and control the torque and load applied during the assembly of components, ensuring proper fastening and product quality.
7. Research and Development: Engineers and researchers use these load cells during product development and testing to evaluate the performance of fasteners and through-hole connections in various applications.
8. Quality Control: Quality control processes in various industries, including aerospace, automotive, and manufacturing, benefit from LWO Series load cells to verify that fasteners meet specific load and torque specifications.
9. Load Monitoring: The load cells can be used for ongoing load monitoring of bolted connections in structures, machinery, and equipment to ensure they remain within safe operational limits.
10. Educational and Training: Educational institutions incorporate LWO Series load cells into engineering and materials science laboratories to teach students about bolted connection mechanics and conduct experiments related to fastener testing.
The Transducer Techniques LWO Series load cells, designed to be matched to specific bolt diameters and load characteristics, play a crucial role in maintaining safety, quality, and structural integrity in various industries where bolted connections are critical components. Their reliability and precision make them valuable tools for force measurement in demanding applications.
LPU Series Load Cell Applications.
The Transducer Techniques LPU Series low-profile, universal tension or compression "pancake" type load cells are versatile force sensors used in a wide range of applications that require precise force measurement in both tension and compression. These load cells are constructed from 17-4 PH heat-treated stainless steel and feature a design that allows for hold-down bolt holes through the outer diameter and a threaded hole through the center, enabling force measurement from either end. Here are some specific applications where the LPU Series load cells are commonly used:
1. Industrial Automation: LPU Series load cells are integrated into industrial automation systems for monitoring and controlling forces in manufacturing and assembly processes. They contribute to quality control and process efficiency.
2. Material Testing: Materials testing laboratories use LPU Series load cells for conducting a wide range of tests, including tensile, compressive, and fatigue tests on various materials. They provide accurate data on material properties.
3. Product Testing: Manufacturers use LPU Series load cells for product testing, including load testing, performance evaluations, and durability testing of various products and components.
4. Quality Control: Industries with stringent quality control requirements, such as automotive and aerospace manufacturing, rely on LPU Series load cells to verify that products meet specific force and load specifications. This ensures product quality and safety.
5. Assembly Line Testing: Manufacturers use these load cells to perform tests on components and assemblies during the production process to ensure that they meet design specifications and quality standards.
6. Research and Development: Engineers and researchers use LPU Series load cells during product development and prototyping to evaluate the performance, durability, and structural integrity of new designs and components.
7. Custom Machinery and Equipment: Manufacturers and research facilities integrate LPU Series load cells into custom-built machinery and equipment designed for specialized testing and manufacturing processes that require precise force measurement.
8. Compression Force Measurement: The LPU Series load cells are ideal for compression force measurement applications. They are often used with ALB load buttons for applications where accurate compression force measurement is essential.
9. Hydraulic and Pneumatic Systems: LPU Series load cells are used in hydraulic and pneumatic systems to monitor and control forces, ensuring safe and efficient operation.
10. Educational Laboratories: Educational institutions incorporate LPU Series load cells into engineering and materials science laboratories to teach students about force measurement principles and conduct experiments related to mechanics and materials science.
The Transducer Techniques LPU Series load cells offer a versatile and reliable solution for precise force measurement in a wide range of industrial and scientific applications. Their durability and accuracy contribute to improved product quality, safety, and process efficiency.
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