We are independent & ad-supported. We may earn a commission for purchases made through our links.
Advertiser Disclosure
Our website is an independent, advertising-supported platform. We provide our content free of charge to our readers, and to keep it that way, we rely on revenue generated through advertisements and affiliate partnerships. This means that when you click on certain links on our site and make a purchase, we may earn a commission. Learn more.
How We Make Money
We sustain our operations through affiliate commissions and advertising. If you click on an affiliate link and make a purchase, we may receive a commission from the merchant at no additional cost to you. We also display advertisements on our website, which help generate revenue to support our work and keep our content free for readers. Our editorial team operates independently of our advertising and affiliate partnerships to ensure that our content remains unbiased and focused on providing you with the best information and recommendations based on thorough research and honest evaluations. To remain transparent, we’ve provided a list of our current affiliate partners here.
Engineering

Our Promise to you

Founded in 2002, our company has been a trusted resource for readers seeking informative and engaging content. Our dedication to quality remains unwavering—and will never change. We follow a strict editorial policy, ensuring that our content is authored by highly qualified professionals and edited by subject matter experts. This guarantees that everything we publish is objective, accurate, and trustworthy.

Over the years, we've refined our approach to cover a wide range of topics, providing readers with reliable and practical advice to enhance their knowledge and skills. That's why millions of readers turn to us each year. Join us in celebrating the joy of learning, guided by standards you can trust.

What Is a Tensometer?

By Doug Bennett
Updated: May 21, 2024
Views: 19,346
Share

A tensometer is a device used to determine a material's response to varying strains, called loads. The amount of stretch that a material has when it is under strain provides important information about the material’s tensile strength and fatigue strength. Tensometer devices are routinely used in the manufacturing industry to ensure that parts meet necessary strength and endurance requirements.

Tensometer devices consist of two grips that hold a section of test material in place. These grips are then used to apply a tensile or compression force, called a load, to the test piece. Tensometer instruments can create the force through the use of either a screw or a hydraulic ram, which are powered by mechanical or electrical means.

Sealed chambers can be used to house a tensometer. This configuration allows for the testing of a material’s strain characteristics under specific temperatures and pressures. This is critical for testing metals used in aircraft and submarines, which can experience drastic changes in atmospheric pressure. Chambers are also useful for testing materials that will be exposed to high temperature ranges.

Accurate results from tensometer devices depend upon the quality of the test piece. Any defect that is created during the cutting process can skew test results and lead to premature failure under strain. Even the tiniest surface inconsistency can rapidly enlarge and spread under strain, leading to early fractures and metal fatigue. This is the same process that causes poorly produced rivets and metal sheeting to fatigue and fail on aircraft when repeatedly exposed to the stresses of atmospheric pressure.

Results produced by tensometer instruments provide load as a function of extension. From this data, along with the cross-sectional area of the test piece, a stress-strain curve can be plotted. This curve is unique for every material and provides key measures. These measures include the material’s elastic limit, proportionality limit, yield strength and ultimate strength.

Tensometers enable engineers to determine the Young’s modulus for the material being tested. Young’s modulus represents the initial linear slope of a material’s stress-strain curve, defined as the tensile strength divided by the tensile strain. The tensile strength is determined by dividing the force applied by the cross-sectional area of the test piece. Tensile strain represents the amount of stretch produced, divided by the original length of the test piece. Materials exposed to a force within Young’s modulus, the initial linear portion of the stress-strain curve, will return to their original condition after the load is removed.

The point at which a material’s stress-strain line begins to curve represents the material’s elastic limit. Strain caused by loads greater than this limit will result in permanent deformation of the material, preventing it from returning to its original condition when the load is removed. The maximum force, or strain, absorbed by the material represents its ultimate strength. This might or might not be equal to the material’s fracture strength.

Share
All The Science is dedicated to providing accurate and trustworthy information. We carefully select reputable sources and employ a rigorous fact-checking process to maintain the highest standards. To learn more about our commitment to accuracy, read our editorial process.
Discussion Comments
Share
https://www.allthescience.org/what-is-a-tensometer.htm
Copy this link
All The Science, in your inbox

Our latest articles, guides, and more, delivered daily.

All The Science, in your inbox

Our latest articles, guides, and more, delivered daily.