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How Does Tensile Testing Work?

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Tensile testing, also known as tension testing, is a type of mechanical test used to determine how a material responds to a stretching force. This test helps evaluate the mechanical properties of an object, such as metals, polymers, composites, and various other materials.

Performing a tensile test applies a load to specimen, and gradually increasing the load sometimes until failure or destruction. The tensile data is analyzed by using a stress-strain curve.

Interface stain gage load cells are commonly used in tensile testing due to their high precision and sensitivity. They work by measuring the strain in a material, which is directly related to the applied force. This strain data is then converted into force measurements. Learn more in Tension Load Cells 101.

Tensile testing is fundamental in test and measurement. It is used by researchers, testing labs, and engineers across industries including infrastructure, medical, manufacturing, aerospace, consumer goods, automotive, energy, and construction.

How Tensile Testing Works

Tensile testing is essential in materials science and engineering to understand the material’s behavior under tension and to ensure its suitability for specific applications.

First, a specimen of the material is prepared with a specific shape and dimensions. This sample is carefully controlled to meet testing standards based on the test plan.

Interface supplies a variety of load cells for these tests. The load cell is typically mounted in a tensile testing machine. The tensile test machine has two separate jaws, one of which will move away from the other at a controlled rate during the test. As it moves away, it is pulling on the material, stretching it until it the test is complete, or it breaks. This is also referred to as testing to failure or destruction. The controlled rate is called the strain rate, and materials will behave differently under different strain rates.

The specimen is then securely mounted in a testing machine, which is usually called a tensile testing machine or universal testing machine. The load cell is positioned in such a way that it bears the load applied to the specimen during the test.

Load cells are commonly used in tensile testing to measure and record the force or load applied to a specimen during the test. These sensor devices are crucial for accurately determining the mechanical properties of materials under tension.

The testing machine applies a pulling force (tensile force) to the specimen along its longitudinal axis. The force is gradually increased at a constant rate, causing the specimen to elongate.

As the tensile testing machine applies a pulling force to the specimen, the load cell measures the force in real-time. This force measurement is typically displayed on a digital instrumentation device or recorded by a data acquisition system.

The recorded data, including the applied force and the corresponding elongation or deformation of the specimen is usually plotted on a stress-strain curve for analysis. The stress-strain curve provides valuable information about the material’s mechanical properties, including its ultimate tensile strength, yield strength, Young’s modulus, and elongation at break.

Engineering Checklist for Tensile Test Plans

  • Identify the Purpose of the Tensile Test
  • Select the Material and Test Standard
  • Define the Mechanical Properties
  • Determine the Specific Mechanical Properties for Evaluation
    • Common properties include tensile strength, yield strength, modulus of elasticity (Young’s modulus), elongation, reduction in area, stress-strain curve characteristics
  • Establish Test Conditions
    • Include temperature, strain rate and testing environment
  • Define Sample and Specimen Requirements
  • Determine Measurement Accuracy Requirements
  • Prepare Instrumentation and Equipment
  • Plan for Data Recording and Reporting
  • Review Compliance Requirements and Safety Standards
  • Document Test Plan
  • Publish Verification and Validation Processes
  • Report Results

Defining measurement requirements for tensile tests by specifications is a crucial step in ensuring that the tests accurately and reliably assess the mechanical properties of materials.

Tensile Testing Terms to Know

Stress: Stress is the force applied per unit cross-sectional area of the specimen and is usually denoted in units of pressure. Stress is calculated by dividing the measured force by the cross-sectional area of the specimen. The load cell’s force measurement ensures that the stress values are accurate and precise. Simply, stress is the amount of force applied over a cross-cross-section.

Strain: Strain represents the relative deformation of the material and is the change in length (elongation) divided by the original length of the specimen. Strain is the amount of elongation in a sample as it is stretched or squashed.

Elastic Region: In the stress-strain curve, the initial linear region where stress is directly proportional to strain is known as the elastic region. Here, the material returns to its original shape when the load is removed.  As soon as a material is placed under any load at all, it deforms. Visually, the deformation may not be noticeable, but right away, the material is deforming. There are two types of deformation: elastic (not permanent) and plastic (permanent).

Yield Point: The yield point is the stress at which the material begins to exhibit permanent deformation without an increase in load. It marks the transition from elastic to plastic deformation.

Ultimate Tensile Strength (UTS): UTS is the maximum stress the material can withstand before breaking. It is the highest point on the stress-strain curve. If the material is loaded to its UTS, it will never return to its original shape, but it can be useful in engineering calculations, as it shows the maximum, one-time stress a material can withstand.  Load cells can detect the exact moment of specimen failure, such as fracture or breakage. This information is crucial for determining the ultimate tensile strength and other mechanical properties of the material.

Elongation at Break: Elongation at break is the amount the specimen stretches before it breaks, expressed as a percentage of the original length.

Load cells can also be used for real-time monitoring and control during the test. Test operators can set specific load or strain rate parameters to control the testing machine’s operation and ensure the test is conducted within specified conditions.

Load cells play a safety role by providing feedback to the testing machine’s control system. If the load exceeds a certain threshold or if the load cell detects an anomaly, the testing machine can be programmed to stop or take corrective actions to prevent damage to the equipment or ensure operator safety.

To discuss Interface products and experience in tensile testing, be sure to reach out to our global representatives in the field or contact us. We are always here to help!

Force Measurement Testing Improves Products and Consumer Safety

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Across every industry, force measurement solutions are utilized to improve product performance, safety and quality. Sensor technologies are used every day to test various consumer products’ weight, torsion, tension, compression, fatigue, impact, and materials.

Force measurement testing is used throughout the product development lifecycle, from concept and R&D, through engineering and testing, to manufacturing and distribution, leading to eventual utilization. Interface load cells are commonly integrated into actual consumer products for activation and to measure performance during use.

Interface force measurement solutions are also used in the testing of equipment, machines, and tools used in the production of all types of products and goods. Our products are used in industrial automation robotic arms as well as within lifting equipment deployed to move materials around a facility.

The key to all force measurement testing is accuracy and reliability of data, as well as selecting the right type of force sensor for the specific product being testing.

Types of Product Testing Applications Using Interface Measurement Solutions

  • Weighing Applications: Interface miniature load cells are often for product testing to measure the exact weight of consumer products, such as food, beverages, and electronics. This information is critical R&D, as well on the production line and to meet the exact product specifications. Our load cells help to ensure that the products are not underweight or overweight, and comply with regulations. Read more about Load Cells for Smarter and More Efficient Weighing
  • Material Applications: Interface LowProfile load cells are often found in product testing labs to assess the strength of materials used in consumer products such as plastics, metals, and mixtures of composites. The measurements gathered during the product testing safeguards consumers and confirms the product’s durability. Read Interface Solutions for Material Testing Engineers
  • Force Applications: Interface load cells, torque transducers, and instrumentation are used in complete test systems that examine the usability of products such as exercise equipment, appliances and electronics. The data acquired in shear, tensile and force testing is important to understand if the product meets design specifications, is easy to use and does not require excessive force to work.
  • Safety Applications: One of the most important product use cases for Interface measurement solutions is to test the safety of products such as furniture, toys and automobile features. It is a requirement for every maker of products that are not hazardous and will not cause injury to consumers. Read Interface Solutions for Safety and Regulation Testing and Monitoring

To give you a better idea of how our load cells and instrumentation are utilized in distinct types of product tests, we have included a few application notes below outlining real-world examples of force testing projects.

Bicycle Helmet Safety and Impact Product Testing

A high production bicycle manufacturing facility set up a product testing lab to measure the impact of the safety of their helmets when dropped from different heights onto a flat surface such as an anvil. This test is necessary to ensure consumer safety and that the products are made with the highest quality materials to protect the rider. Interface suggests installing the 1101 Compression-Only Ultra Precision LowProfile® Load Cellat the bottom of an anvil. The bike helmet is then dropped from multiple heights and at multiple angles onto the anvil. The measurements from impact are then recorded and logged throughout the product testing using Interface’s INF-USB3 Universal Serial Bus Single Channel PC Interface Module with supplied software. Every design or material change runs through the same rigorous testing protocols using these high accuracy measurement solutions.  Read CPG Bike Helmet Impact Test

Product Weighing of Consumer Water Bottles

A manufacturer of glass bottled water needs to dispense the exact amount of fluid into each bottle and then weigh the water bottle to ensure it is at the labeled weight on the product packaging. The product testing of the manufacturing equipment is used to minimize waste and to meet the weight requirements to ensure consumer satisfaction. Interface suggests using the MBP Miniature Beam Load Cell and attaching it under a plate or platform where the water bottle is placed on while it is being filled with fluids. The force weight is measured by the MBP Miniature Beam Load Cell and connected to the 9870 High Speed High Performance TEDS Ready Indicator where results are captured, displayed, and logged for quality control. Read CPG Water Bottle Dispensing and Weighing

Product Test Lab Conducts High Volume Tensile Force Testing

A product test lab is constantly requested to conduct a series of tensile force tests on different samples and materials until failure. These materials include plastic, steel, or woven fabric, and are utilized in the design and manufacturing of several consumer products. The lab professionals want to measure tensile strength, yield strength, and yield stress for every submitted product material sample. For the tensile test stand, we recommend using Interface’s 1200 Standard Precision LowProfile™ Load Cell be installed into the test frame. As the tensile test is conducted, force results captured by the load cell and extensometer are synchronized through the SI-USB4 4 Channel USB Interface Module. The results are displayed on the customer’s computer with supplied software. Learn more by reading Material Tensile Testing.

Interface’s high precision force sensor technologies used in robotics have revolutionized the manufacturing of consumer products. With automated assembly lines and robotic arms taking charge, these machines work efficiently to mass-produce consumer goods. Quality control of all the products we provide you for testing is one of the main focuses of Interface, as we want to keep your customers happy and safe.

Interface’s experienced team are renowned specialists in force, torque and weight measurement manufacturing and technology. Our depth of knowledge and wide range of capabilities create custom solutions of all types, whether special transducers made to your exact specifications or complete customized sensor, instrumentation, and software systems. We collaborate with you to ensure the product specifications you need are designed to match your precise requirements.

ADDITIONAL RESOURCES

Introducing the Interface Consumer Product Testing Case Study

Interface Solutions for Consumer Products

Force Measurement is Reducing Waste and Automating the Consumer Packaging Industry

Applications for Consumer Products and Packaging

Load Cells for Consumer Product Applications

Why Product Design Houses Choose Interface

Testing Labs Choose Interface High Accuracy Products

Interface Solutions for Material Testing Engineers

Interface Solutions for Structural Testing

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Interface products are used in many types of structural tests across industries, including for rockets, aircraft, EV batteries, heavy equipment, and infrastructure projects. Our loads cells provide the accurate and reliable data, which is why our force measurement solutions are a top choice for these complex and highly regulated industries.

Structural testing labs use Interface solutions to perform tensile, compression, bending, fatigue and hardness testing on materials, components, or assemblies. There are a variety of structural tests used for measuring tension of push and pull forces, design proofing, and lifecycle fatigue validation. Each of these tests plays a critical role in verifying the quality and safety of a product, component or materials, and each of these tests relies upon force measurement sensors.

Types of Structural Testing

  • Tensile Testing involves applying a pulling force to measure a structure’s strength and resistance. Load cells are used to measure the applied force and resulting tension from elongation or deformation of the material.
  • Compression Testing uses compressive force to evaluate the strength and resistance of a structure to crushing. Force measurement sensors are used to measure the magnitude of the applied force and the resulting deformation or failure.
  • Torque Testing measures the twisting or rotational forces applied to a structure. Torque transducers are utilized to assess the material’s torsional strength, stiffness, and behavior.
  • Load Capacity Testing determines the maximum load that a structure can withstand before failure. Force measurement sensors and load cells are used to gradually increase the load until failure occurs, enabling the determination of the structure’s load-carrying capacity.
  • Bending Tests assess the flexural strength and behavior of materials under force. Load cells measure forces applied during bending and to determine the bending moment, stress distribution, and deflection of the material within a structure.
  • Fatigue Tests in structural testing labs assess the durability and performance of materials under cyclic loading conditions. Force sensors measure the applied forces or loads helping to analyze the material’s fatigue life through various cycle counts.
  • Impact Testing involve subjecting a structure to sudden and high-intensity forces to assess its ability to withstand rapid loading conditions. This is particularly important for environmental condition testing to structures that endure extreme temperatures, winds, moisture. This type of testing is also important for submersible structures.
  • Shear Testing evaluates the resistance of a material to forces applied parallel to its surface, causing it to slide or deform. Force measurement devices measure the applied shear forces and determine the shear strength and behavior of the material used in a structure.

During the Testing Lab Essentials Webinar, Interface application experts detail various ways our products serve test labs. During this event, the experts detailed top considerations in selecting Interface products that serve test lab engineers in conducting structural tests. 

Structural testing labs use our LowProfile load cells because they are designed to fit into tight spaces and machines, making them ideal for use in small-scale structural applications. High-capacity load cells from Interface are designed to measure large forces and are commonly used in heavy machinery and structural testing. Universal load cells are capable of measuring tension and compression, making them ideal for quality control and structural testing applications.

Multi-axis sensors are valuable force measurement solutions as they provide more data across two, three and six axes during a single structural test. Implementing multi-axis sensors can provide a more complete picture of loads and moments being applied to the DUT providing additional insight for design and verification.

As noted in the webinar, key challenges involved in structural testing include managing and isolating extraneous loads such as off-axis load and bending, understanding which products are most suitable for the type of structural tests you are performing and ensuring the instrumentation you are using is compatible with force solutions. Equally, it is important to define your systems for optimal data collection in the planning phase of any project.

Structural Testing Applications

Performance Structural Loading

Performers and entertainers have special stages built to perform in concerts for their fans. From the largest sports events half-time shows to other complex staging, a force measurement system is needed to ensure the safety for all performers, equipment, and scenery on stage. The stage needs to hold all weight, and also maintain during dynamic movements, such as performers walking on stage. For this challenge, Interface’s A4200 Zinc Plated or A4600 Stainless Steel WeighCheck Load Cells paired with the 1280 Programmable Weight Indicator and Controller is able to measure the individual loads on each load cell, or the entire weight of the performance stage. Results from the 1280 Programmable Weight Indicator and Controller was sent to the customer’s control center. Using Interface’s A4200 Zinc Plated or A4600 Stainless Steel WeighCheck Load Cells as a customizable solution, the customer was able to monitor and weigh the performance stage.

Rocket Structural Test

NASA’s Space Launch System (SLS) core stage will be the largest ever built at 27 feet in diameter and 200+ feet tall. Core components including liquid hydrogen and oxygen tanks must withstand launch loads up to 9 million pounds-force (lbf). Interface load cells attached to hydraulic cylinders at various locations along test stands to provide precise test forces. Strain gages bonded to rocket structure surface and connected to data acquisition system for stress analysis. Using this solution, Engineers are able to measure loads applied at various areas on the rocket structure, verifying the structural performance under simulated launch conditions.

EV Battery Structural Testing

As electric vehicles push advancements in efficiency gains, structural battery packaging is at the forefront for optimization. This drives the need to validate structural battery pack design, both in terms of life expectancy against design targets as well as crash test compliance and survivability. Interface’s solution includes 1100 Ultra-Precision LowProfile Load Cells in-line with hydraulic or electromechanical actuators in customer’s test stand. Also utilized are 6A Series 6-Axis Load Cells to capture reactive forces transmitting through pack structure. Multi-axis measurement brings greater system level insight and improved product success.

Interface is a valued partner to test labs for providing solutions for structural testing.

Additional Resources

Modernizing Infrastructure with Interface Sensor Technologies

Rocket Structure Testing

Rigging Engineers Choose Interface Measurement Solutions

Load Cell Selection Guide

Tension Load Cells 101

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A tension load cell is a type of force sensor used to measure tensile forces in materials, structures, or machines. It is used to measure the maximum load that a material can support without fracture when being pulled or stretched under the applied load. A strain gage manufactured inside the load cell sensor measures the deformation and converts it into an electrical signal.

The main difference between a tension load cell and a compression load cell is the direction in which they measure the force being pushed or pulled. Though most Interface high performance load cells are designed for both tension and compression, specific load cells are calibrated in tension only to measure forces that pull or stretch a structure. As the load cell stretches, it measures the resulting force.

It is customary practice for most labs to use tension and compression load cells, then determine its specific tension use case based on the requirements of a test project or product design. Tension and compression load cells are easily used for tension only but will measure both. Load cells can be calibrated in either tension or compression, and both tension and compression. The combined is more economical for test labs and most use cases.

Benefits of Tension Load Cells

Load cells that measure tension are preferred over other types of load cells when the force being measured is tensile in nature. They are accurate, reliable, and can be calibrated to suit different applications and environments. Additionally, they are easy to use and require minimal maintenance.

Accurate measurement of tensile forces: Tension-only load cells are specifically designed to measure tensile forces accurately, without being influenced by compressive or bending forces. This makes them ideal for applications where the force being measured is purely tensile, such as in the testing of cables, wires, ropes, or chains used in lifting applications and equipment. Interface Tension Links are preferred for these types of lifting and weighing use cases.

High sensitivity and resolution: Tension-only load cells typically have high sensitivity and resolution, meaning they can detect slight changes in the applied force. This makes them useful in applications where precise measurements are required, such as in the testing of materials with low tensile strength.

Easy installation: Tension-only load cells are typically easy to install and use, requiring minimal setup time and equipment. They are often designed with attachment points or hooks for attaching to the load being measured, which makes them convenient for use in the field or in a testing lab.

Durability and reliability: Tension-only load cells are often constructed from durable materials, such as stainless steel, which makes them resistant to corrosion and wear over time. They are also designed to provide reliable and consistent measurements, ensuring accuracy and consistency in test results.

Tension Load Cell Applications

Tension load cells are standard and their versatility in application use makes them popular in test and measurement. Tension load cells are used for test and measurement industry applications including in manufacturing, automotive, energy, aerospace, and infrastructure. For example, the transportation sector uses load cells to measure the tension in cables, wires, ropes, and chains. They are used in a diverse range of testing equipment to measure the strength and durability of materials. They are designed to provide accurate and reliable measurements of tensile loads and can be calibrated to suit different applications and environments.

Tension load cells are commonly used in applications for material testing to evaluate the tensile strength and elasticity of varied materials, such as metals, plastics, and composites. Tension testing is a valuable tool in materials science and engineering, as it provides valuable information about the tensile properties of a material. Some examples of tension testing include:

  • Determining the strength of a material: Tension testing provides a way to measure the maximum load a material can withstand before it breaks or fails. This information is crucial in determining the strength of a material and its suitability for different applications.
  • Understanding the ductility of a material: Tension testing can also be used to measure the amount of deformation a material can undergo before it breaks. This information is important in determining the ductility of a material and its ability to withstand bending and stretching without breaking.
  • Identifying defects or weaknesses in a material: Tension testing can help identify defects or weaknesses in a material that may cause it to fail under stress. By subjecting a material to increasing levels of tension, engineers can pinpoint the point at which the material fails and investigate the cause of the failure.
  • Comparing the properties of varied materials: Tension testing can also be used to compare the tensile properties of different materials. This information is useful in selecting the best material for a specific application and designing structures that can withstand the required loads.

Tensile Testing For 3D Materials

A customer wants to conduct a tensile force test on different 3D printing materials until failure. These different 3D printing materials being tested included PLA, PETG and ASA to see how they performed. The customer wanted to test the materials quality, strength, ductility, and stiffness. Interface recommended using our 1200 Standard Precision LowProfile™ Load Cell be installed into the customer’s test frame. The tensile test is conducted, and force results captured by the load cell are synced through the INF-USB3 Universal Serial Bus Single Channel PC Interface Module. These results can be displayed on the customer’s computer with supplied software.

Tension load cells are used in structural testing to measure the tension in structures used in construction, aerospace, maritime, and infrastructure. For example, tension load cells are commonly used for bridges, buildings, and towers, to ensure they can withstand the forces in their design and application.

Tension load cells are often used within manufacturing machines and equipment for monitoring and real-time force measurement. For example, in a facility they are used to measure the tension in cables or wires during production, to ensure they meet the required specifications and are safe for use.

Research and development for all types of applications need to assess the tensile properties of new materials or structures, to assess their suitability for different applications, from medical devices to product simulations.

If your next project needs an accurate tension load cell, contact our application experts to see which model best fits your exact requirements.

ADDITIONAL RESOURCES

Interface Solutions for Material Testing Engineers

Tensile Testing for 3D Materials App Note

Testing Lab Essentials Webinar

Bolt Tension Monitoring

Mooring Line Tension Testing App Note

Tension Links 101

Types of Force Measurement Tests 101

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There are distinct types of force tests that engineers, product designers, manufacturers, and test labs perform to accurately measure factors that control quality, safety, and reliability.

Testing force helps to qualify how something will react when applying load, either by a normal application or by pulling and pushing it fails. The type of force measurement classifications are compression, fracture, tension, flexure, and shear.

Interface provides a broad range of solutions for static and dynamic force measurement tests including standard and custom transducers, instrumentation, accessories, frames, calibration equipment and other components used for in force testing.

The most common categories of force testing include:

  • Tensile testing
  • Shear testing
  • Compression testing
  • Fatigue testing
  • Torque testing
  • Hardness testing
  • Static testing
  • Mechanical strength testing
  • Material testing
  • Proof load testing
  • End of line testing

There are variations to each of these test classifications, such as cycle testing is often a subset of fatigue and mechanical strength tests. Hardness testing is frequently referred to as nondestructive testing. Initial R&D tests typically center around choosing materials, strength and durability tests, compression ergonomic and abrasion tests.

Here are the general characterizations of the most popular types of force tests.

Tensile Test

Tensile strength is the ability of a metal to withstand a pulling apart tension stress. Performing a tensile test, sometimes referred to as tension testing, applies uniaxial load to a test bar and gradually increasing the load until it breaks. The measurement of the load is against the elongation using an extensometer. The tensile data is analyzed by using a stress-strain curve. Interface load cells are commonly used for various tensile tests when accuracy of measurement matters.

Compression Test

Compression is the result of forces pushing towards each other. The compression test is like the tensile test. Place the object in a testing machine, apply a load and record the deformation. A compressive stress-strain curve is drawn from the data. Interface provides load cells that measure compression-only or tension and compression measurements from the same device.

Torque Test

Torque measurement determines how an object will react when it is turned or twisted. There are two common use cases, fastening tests of objects or by testing rotating parts in an assembly. The two types of torque measurement are reaction and in-line, which are important when selecting the type of torque transducer to use in your test. The wrong torque can result in the assembly failing due to several problems, whether that is by torque testing bolts or engine parts. Parts may not be assembled securely enough for the unit to function properly, or threads may be stripped because the torque was too high, causing the unit to fail. Torque is a force producing rotation about an axis. This type of testing is also extremely popular in automotive to measure a variety of components.

Shear Test

Shear strength is the ability to resist a “sliding past” type of action when parallel, but slightly off-axis, forces, applied in the test. Shear force is directional force that is over the top of a surface or part. Shear is measured by tension or compression using a shear or bending beam load cell.

Hardness Test

Hardness testing, which measures the resistance of any material against penetration, is performed by creating an indentation on the surface of a material with a hard ball, a diamond pyramid or cone and then measuring the depth of penetration. Hardness testing is categorized as a non-destructive test since the indentation is small and may not affect the future usefulness of the material. There are a wide variety of hardness testing types as well.

Examples of Testing Types

Compression Test Example

Interface’s customer wanted to measure the amount of compression force a piece of candy could withstand to ensure its label is marked correctly. The purpose of the test was to correctly calibrate the equipment to provide the same stamping force each time without breaking the candy apart. An Interface Model WMC Mini Load Cell and 9330 Battery Powered High Speed Data Logging Indicator are used to measure the results. Read more about this compression test here.

Torque Measurement Example

In this example torque testing accurately measures the forced needed to securely fasten a bolt. This type of test is critical in highly regulated industries like aerospace and automotive to ensure every screw and bolt are not over or under-tightened. Interface’s LWCF Clamping Force Load Cell along with Interface’s INF-USB3 Universal Serial Bus Single Channel PC Interface Module provide a solution that monitors the force being applied during bolt tightening.

Shear Test Example

This example shows how aerospace manufactures use shear testing to measure the affects of wind as it moves past the wings, hull, and other components of a plane. Interface measured this force using a Model 6A154 6-Axis Load Cell mounted in the floor of the wind tunnel, and connected  to the scaled model by a “stalk”. A BX8-AS Interface BlueDAQ Series Data Acquisition System was connected to the sensor to collect data.

As products become more complex and technologically advanced, the test and measurement industry must provide solutions to monitor a wide variety of factors. This is no different in force measurement.

Interface has been involved in every type of force measurement type across a variety of applications both large and small. To learn more about our more than 36,000 product SKUs designed to conduct all these tests, from single load cells and torque transducers to complete testing rigs and systems. We also provide calibration services for all types of force measurement transducers. Contact us if you are unsure which force measurement solution best fits your testing plan.

Additional Resources

Tensile Testing for 3D Materials

Material Tensile Testing

Interface Solutions for Material Testing Engineers

Bike Handlebar Fatigue Testing

Interface Specializes in Fatigue-Rated Load Cells

Specifying Accuracy Requirements When Selecting Load Cells

Spring Compression Testing App Note

Insights in Torque Testing Featured in Quality Magazine

Interface Solutions for Material Testing Engineers

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Force measurement inherently is part of all types of engineering throughout the entire development process of products, structures, consumer goods, and the materials used to construct them.

In the beginning of the design and development processes, material testing engineers utilize sensor technologies and instrumentation to measure the durability, fatigue, safety, and quality of the materials used for their projects.

The role of a materials engineer is to develop, process, combine, and test materials to be used in production. Based on data gathered, combined with their expertise, the materials engineer will identify and recommend the appropriate materials for specific applications. Ultimately, they are the foundation of product development because it is their responsibility to select materials based on the use of the product, its ability to perform its task and function, and durability of materials to hold up over time. They also test for environmental impact and exposure considerations.

Five Categories of Material Testing

  • Mechanical testing
  • Testing for thermal properties
  • Testing for electrical properties
  • Testing for resistance to corrosion, radiation, and biological deterioration
  • Nondestructive testing (NDT)

Force measurement is most often used is in the material testing category of mechanical testing. This applies to testing materials used in all types of industries, including infrastructure, aerospace, automotive, industrial automation, manufacturing of consumer goods and in the machines used to assemble products. In mechanical testing, Interface sensors are commonly used to conduct:

  • Hardness Testing
  • Tensile Testing
  • Impact Testing
  • Fracture Toughness Testing
  • Creep Testing
  • Fatigue Testing
  • Nondestructive Testing

Interface Material Test Engineer Solutions

Material testing has been around since the first invention, to determine quality, durability and resilience of products and parts. What has changed over the centuries and decades is the sophistication of force testing and measurement. Interface’s robust line of load cells, torque transducers, multi-axis sensors, and instrumentation are used in about every industry for material testing. If it must be measured, Interface has a solution.

Interface’s force measurement products are being used to gather data from testing materials in applications used for industrial automation, structures, medical devices, vehicles on the ground and in the air, packaging, sports equipment and more. Material testing engineers ensure reliability and safety of the chosen materials. Here are examples of how material testing engineers use our products.

Tensile Testing of 3D Printing Materials

Interface was contacted by a test engineering team in search of a solution for conducting a tensile force test on different 3D printing materials until failure. They wanted to test several types of material types. The 3D printing materials to be tested to see how it performed included PLA, PETG and ASA.  The test of the materials was to assess strength, quality, ductility, and stiffness. Interface supplied our most popular load cell, the 1200 Standard Precision LowProfile™ Load Cell, to install into the engineer’s test frame. The tensile test gathered the force results from the load cell that was synced through Interface’s instrumentation solution, the INF-USB3 Universal Serial Bus Single Channel PC Interface Module. The results were displayed on their computer with supplied software from Interface. Read more about this material testing application solution here.

Bike Frame Fatigue Testing

Fatigue testing is a critical material test used to ensure the materials used in a product hold up over time. A bike manufacturing company wanted to perform a fatigue test on their bike frames to analyze the strength of their frames, ensure durability and high-quality standards. Interface suggests installing Model 1000 Fatigue-Rated LowProfile™ Load Cell to the customer’s bike frame fatigue tester. This load cell will provide the customer highly accurate results through the fatigue cycling. Results are collected using the INF-USB3 Universal Serial Bus Single Channel PC Interface Module and displayed on the customer’s computer with Interface’s provided software. The bike manufacturing company successfully had their bikes undergo fatigue frame testing, receiving highly accurate results with Interface’s load cell and instrumentation. Watch the fatigue testing of the bike frame in this animated app note.

Spring Compression Testing

A customer wanted to evaluate the performance of their springs, but also the functionality of their spring test stand with a wireless solution. Interface suggested using one of their WTS-5200XYZ 3-Axis Force Moment Load Cell which has three integral WTSAM-1E Wireless Transmitters and installing it into the customer’s spring compression frame. The WTS-5200XYZ 3-Axis Force Moment Load Cell measured the force compression of the spring. The integral WTS-AM-1E Wireless Strain Bridge Transmitter Modules transmitted and displayed the information wirelessly to the LCCAXXX Wireless Instrument Enclosure. Using Interface’s solution, the customer was able to wirelessly get compression results on the spring being tested. They were also able to verify their spring compression test stand was working effectively.

Selecting the right material is critical to product develop and material testing engineers rely on Interface due to the accuracy and reliability of our solutions. If you have questions on what products are best suited for your material testing applications, please contact us.

ADDITIONAL RESOURCES

Tensile Testing for 3D Materials

Furniture Fatigue Cycle Testing

Bike Handlebar Fatigue Testing App Note

Aircraft Wing Fatigue App Note

Material Tensile Testing

Why Civil Engineers Prefer Interface Products

Beam Stress Test