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Guide

Hardness Testers: The Top Options on the Market & More [New for 2024]

A hardness tester is a device used to measure a material’s resistance to deformation, particularly its ability to withstand indentation or scratching, providing critical data on the material’s strength and durability.

→ Jump to hardness testers for sale and rent.

There are several names for hardness testers, which are used depending on the specific type of test or method being employed:

  • Indentation hardness testers refer to testers like the Rockwell hardness tester, Brinell hardness tester, and Vickers hardness tester.
  • Durometers refer to testers like the Shore hardness tester, also called the Shore durometer.
  • Portable testers refer to testers like the Leeb hardness tester or the Webster hardness tester.
  • Scale-specific hardness testers refer to testers like the HRC Tester (for Rockwell C scale) or the HB Tester (for Brinell hardness).
  • Functional names are also used to describe hardness testers, like the microhardness tester for very small indentations, or the macrohardness tester for larger indentations
  • Material-specific terms are also used, like metal hardness tester, plastic hardness tester, or the rubber hardness tester

As you can see, there are a lot of different types of hardness testers. And each one is suited for different materials and testing needs.

Hardness testers are crucial in a wide range of industrial applications, from metalworking and manufacturing to quality control and material testing. A hardness tester allows professionals to evaluate the durability, strength, and wear resistance of materials, ensuring that they meet the necessary standards for their intended use.

In this guide to hardness testers we’ll share the top hardness testers for sale, how hardness testers work, and a lot more.

Best Hardness Testers for Sale and Rent [New for 2024]

Want to buy or rent a hardness tester? Here are the top options on the market.

1. alphaDUR mini II UCI Hardness Tester

The alphaDUR mini II UCI Hardness Tester is a portable and precise device designed for on-site material hardness testing. It uses ultrasonic contact impedance (UCI) technology, making it ideal for testing on small and thin components. This versatile tester is suited for a variety of industries, including construction, manufacturing, and automotive.

  • Type of tester. Ultrasonic Contact Impedance (UCI) Hardness Tester
  • Measurement range. 20 – 70 HRC
  • Key features. Compact design, quick measurement, data storage, and transfer capabilities
  • Applications. Suitable for testing hardened steel, welds, and thin components
  • Display. Easy-to-read digital screen with backlight for dark environments

Learn more about the alphaDUR mini II UCI Hardness Tester.

2. GE MIC 20

The GE MIC 20 is a versatile portable hardness tester that utilizes the UCI (Ultrasonic Contact Impedance) and rebound hardness testing methods. Known for its durability and precision, this tester is used widely across industries like oil and gas, manufacturing, and construction for measuring material hardness in difficult-to-access areas and coatings.

  • How it works. Employs both UCI and rebound methods to measure hardness by evaluating material deformation under a test load.
  • Measurement range. Broad range to cover applications from soft to hardened metals.
  • Key features. Dual-method testing, user-friendly interface, large memory for data storage, and fast processing speed.
  • Applications. Suitable for testing metals, alloys, and coatings in hard-to-reach areas.
  • Display. High-resolution digital screen with easy navigation through testing modes and results.

Learn more about the GE MIC 20.

3. GE MIC 10

The GE MIC 10 is a portable UCI hardness tester designed for quick and efficient on-site hardness measurements, especially in areas that are hard to access. Its lightweight and durable design make it ideal for industrial applications such as coatings and protective layers in pipelines and other infrastructure.

  • How it works. Uses the Ultrasonic Contact Impedance (UCI) method by evaluating material hardness through the depth of indentation made by a vibrating probe.
  • Measurement range. Suitable for testing various materials, including metals and coatings, with a wide hardness scale.
  • Key features. Lightweight, portable, battery-operated, with easy-to-use controls and a durable design for field use.
  • Applications. Ideal for testing coatings, weld seams, and hard-to-reach surfaces in industries like oil and gas, infrastructure, and construction.
  • Display. Features a high-contrast, easy-to-read LCD screen for quick results in challenging environments.

Learn more about the GE MIC 10.

4. Brinell – Telebrineller System

The Brinell – Telebrineller System is designed for field and shop use to accurately measure hardness using the Brinell method. Known for its durability and precision, this system is ideal for testing metals and coatings in industrial applications.

  • How it works. A steel or carbide ball is pressed into the material surface under a constant load, and the indentation’s diameter is measured.
  • Measurement range. The system accommodates a broad range of materials, offering precise Brinell hardness values across various hardness scales.
  • Key features. Portable design, suitable for field use, with a sturdy build and easy-to-read measurement results.
  • Applications. Commonly used in testing large metal structures and coatings, especially in industrial sectors like construction and energy.
  • Durability. Built to withstand harsh environments, making it a reliable tool for frequent and heavy use in the field.

Learn more about the Brinell – Telebrineller System.

5. alphaDUR mini UCI Hardness Tester

The alphaDUR mini UCI Hardness Tester is a portable and lightweight device designed for quick, reliable hardness testing, especially in hard-to-reach areas. Its innovative UCI (Ultrasonic Contact Impedance) technology makes it ideal for testing thin and small parts, as well as hard surfaces with a fine-grained structure.

  • How it works. Utilizes ultrasonic contact impedance, measuring the shift in resonance frequency when the probe contacts the material, providing an accurate hardness reading.
  • Key applications. Ideal for testing hard-to-reach areas, thin materials, welds, and coatings in industries like oil & gas, construction, and power generation.
  • Accuracy. High precision readings even in challenging field conditions, ensuring dependable results.
  • Display. Features a user-friendly LCD display for real-time data visualization.
  • Data storage. Includes internal memory capable of storing up to 10,000 measurements.

Learn more about the alphaDUR mini UCI Hardness Tester.

6. Proceq Equotip 3

The Proceq Equotip 3 is a portable hardness tester renowned for its versatility and ease of use. It’s ideal for measuring the hardness of large parts and materials, including metals and alloys. The Proceq Equotip 3 offers reliable and accurate results, making it a valuable tool for both field and laboratory applications.

  • How it works. It operates using the Leeb rebound principle, where a test impact body is bounced off the material surface, and the rebound velocity is measured to determine hardness.
  • Key applications. Used for testing heavy, large, or complex-shaped metal parts in industries such as construction, power generation, and shipbuilding.
  • Measurement range. Can measure hardness across a wide range of materials including steel, cast iron, and aluminum alloys.
  • Data storage. Capable of storing up to 500 readings, allowing for convenient record-keeping and analysis.
  • Display. Features a user-friendly display that shows real-time results and averages for accurate data representation.

Learn more about the Proceq Equotip 3.

7. Proceq Equotip 550

The Proceq Equotip 550 is a versatile hardness tester designed for advanced material hardness testing, offering a wide range of applications and high portability. It supports various testing methods, including Leeb, Rockwell, and UCI, making it suitable for different materials and industries.

  • How it works. Uses Leeb rebound hardness testing, where an impact body strikes the material surface and the rebound velocity is measured to determine hardness.
  • Key applications. Widely used in metal production, heat treatment facilities, and weld inspections in industries such as aerospace, automotive, and construction.
  • Accuracy. Delivers precise and consistent readings with support for multiple hardness scales, including Leeb, Vickers, Brinell, and Rockwell.
  • Display. Features a high-resolution touchscreen display with customizable settings for optimal user experience.
  • Data storage. Equipped with advanced data logging capabilities and easy connectivity for exporting test results.

Learn more about the Proceq Equotip 550.

What Is a Hardness Tester? And How Does It Work?

A hardness tester is an instrument used to measure the hardness of materials, typically metals, plastics, or ceramics.

In the context of hardness testers, hardness means a material’s resistance to indentation or scratching, which is critical for understanding how a material will perform under stress or wear.

Hardness testers are commonly used by quality control technicians or materials testing engineers in industries like manufacturing, metal processing, and construction, to ensure materials meet quality and durability specifications.

How Does a Hardness Tester Work?

Hardness testers work by measuring a material’s resistance to permanent surface deformation.

Here’s an overview of how hardness testing typically works:

Basic Principle

A hardness tester presses a harder material (called an indenter) into the surface of the test material with a specific force for a set amount of time. The size or depth of the resulting indentation is then measured to determine the material’s hardness.

Hardness Tester Key Components

  • Indenter. A specifically shaped object (e.g. ball, cone, or pyramid) made of a very hard material like diamond or hardened steel.
  • Force application mechanism. Applies a precise, controlled force to the indenter. This can use weights, springs, or closed-loop control systems.
  • Measurement system. Measures the size or depth of the indentation, either optically or through depth sensing.

General Process

Although there are several different ways to do hardness testing—we cover the top eight methods in the next section—they typically follow these basic steps:

  • The test material is placed on a solid support.
  • The indenter is pressed into the material’s surface with a specific force for a set time.
  • The indenter is removed.
  • The resulting indentation is measured.
  • The measurements are converted to a hardness value on a particular scale.

Brief History of Hardness Testers

The concept of testing material hardness dates back to the early 19th century. One of the first hardness tests was created by Friedrich Mohs in 1812, who developed the Mohs Hardness Scale, which measured scratch resistance in minerals.

Credit: National Park Service

Over time, more advanced and reliable methods emerged, such as the Brinell Hardness Test (1900) and the Rockwell Hardness Test (1919). These methods introduced standardized procedures for measuring the hardness of metals and other materials, revolutionizing quality control processes in various industries.

Here is a brief history of the development of hardness testers:

  • 1812: Mohs Hardness Scale. Developed by Friedrich Mohs, this was one of the first methods for measuring the scratch resistance of various minerals, laying the foundation for modern hardness testing.

  • 1900: Brinell Hardness Test. Invented by Johan August Brinell, this method uses a steel or carbide ball to measure indentation hardness, becoming widely used for testing metals.

  • 1919: Rockwell Hardness Test. Stanley P. Rockwell introduced this method, which measures the depth of penetration of an indenter under load, offering a quicker and easier alternative to the Brinell method.

  • 1920s: Vickers Hardness Test. Developed by Robert L. Smith and George E. Sandland, this test uses a diamond-shaped indenter, making it suitable for testing both hard and soft materials, including thin sheets.

  • 1930s: Knoop Hardness Test. Invented by Fredrick Knoop, this test is ideal for testing brittle materials and thin layers, as it uses an elongated diamond indenter to measure hardness based on indentation length.

  • 1970s: Portable Hardness Testers. The introduction of portable devices, such as the Leeb rebound hardness testers, allowed for hardness testing in the field without needing stationary equipment.

The Top 8 Hardness Testing Methods—Including the 3 Most Common

Hardness testing is a critical process used across various industries to determine the resistance of materials to deformation.

The following methods each offer unique approaches tailored to specific material types and applications, helping to ensure the durability and performance of a wide range of products.

The Three Most Common Hardness Testing Methods

1. Rockwell Hardness Test

The Rockwell hardness test is one of the most widely used methods for measuring material hardness. It involves pressing a diamond cone or steel ball indenter into the material’s surface under a major load. The depth of penetration is measured to calculate the hardness value. Rockwell is commonly used for testing metals like steel and aluminum in industrial settings, including automotive and aerospace applications.

  • How it works. The depth of indentation is measured after a load is applied by the indenter.

  • Materials used for. Steel, aluminum, brass, and other metals.

  • Common applications. Automotive, aerospace, and manufacturing industries.

  • Type of hardness tester for this method. Rockwell hardness testers.

  • Advantages of this method. Provides quick, reliable results; suitable for a wide range of metals; minimal surface preparation is required.

2. Brinell Hardness Test

The Brinell hardness test uses a hardened steel or carbide ball pressed into the material surface to create an indentation. The diameter of the indentation is then measured to calculate the hardness value. This method is ideal for testing softer materials or those with rough surfaces, such as cast iron, aluminum, and copper.

  • How it works. A steel or carbide ball is pressed into the material surface under a constant load, and the indentation’s diameter is measured.

  • Materials used for. Softer metals like aluminum, cast iron, and copper.

  • Common applications. Foundries, construction, and material quality control.

  • Type of hardness tester for this method. Brinell hardness testers.

  • Advantages of this method. Ideal for testing rough surfaces and softer metals; provides accurate measurements for a wide range of materials.

3. Vickers Hardness Test

The Vickers hardness test uses a diamond pyramid-shaped indenter pressed into the material under a set load. The size of the resulting indentation is used to calculate hardness. Vickers testing is versatile and can be used for a wide range of materials, including metals, ceramics, and composites.

  • How it works. A diamond indenter is pressed into the material, and the diagonal length of the resulting indentation is measured.

  • Materials used for. Metals, ceramics, composites.

  • Common applications. Laboratories, material science, and research.

  • Type of hardness tester for this method. Vickers hardness testers.

  • Advantages of this method. Provides precise measurements across a wide range of materials; ideal for small or thin samples.

Other Hardness Testing Methods

Above we covered the three most common hardness testing methods—but there are actually five others that are used in some industries.

Here they are:

4. Knoop Hardness Test

The Knoop hardness test is similar to the Vickers test but uses an elongated diamond indenter that creates an asymmetrical indentation. It is often used for testing thin materials or brittle substances like ceramics and glass.

  • How it works. A diamond indenter creates a long, shallow indentation that is measured to determine hardness.

  • Materials used for. Thin materials, ceramics, and brittle substances.

  • Common applications. Material research, glass testing, and ceramic inspection.

  • Type of hardness tester for this method. Knoop hardness testers.

  • Advantages of this method. Useful for measuring thin or brittle materials; creates minimal damage to the sample.

5. Shore Hardness Test

The Shore hardness test is commonly used to measure the hardness of elastomers and polymers. A durometer device with a spring-loaded indenter is pressed into the material, and the hardness is determined based on the resistance to indentation.

  • How it works. A spring-loaded indenter measures the resistance of the material to indentation.

  • Materials used for. Rubber, elastomers, and polymers.

  • Common applications. Rubber manufacturing, polymer research, and quality control.

  • Type of hardness tester for this method. Shore durometers.

  • Advantages of this method. Quick, easy, and ideal for testing softer materials like rubber and plastics.

6. Leeb Hardness Test

The Leeb hardness test is a portable method that measures the rebound velocity of an indenter after it strikes the material surface. The hardness value is calculated based on the energy loss during the impact. Leeb testers are ideal for large or immovable objects in the field.

  • How it works. Measures the rebound velocity of an indenter after it strikes the material.

  • Materials used for. Large metallic structures, machinery, and pipelines.

  • Common applications. Field testing, pipeline inspection, and machinery testing.

  • Type of hardness tester for this method. Portable Leeb hardness testers.

  • Advantages of this method. Portable and ideal for field use on large, immovable structures.

7. Webster Hardness Test

The Webster hardness test is a quick and portable method for measuring the hardness of aluminum alloys. A hand-operated plier applies pressure to the material, and the indentation size indicates the hardness. This method is popular in the aerospace and automotive industries for on-site aluminum testing.

  • How it works. A plier-like tool applies pressure, and the resulting indentation is measured to determine hardness.

  • Materials used for. Aluminum alloys.

  • Common applications. Aerospace and automotive industries, particularly for aluminum testing.

  • Type of hardness tester for this method. Portable Webster hardness testers.

  • Advantages of this method. Quick and efficient; ideal for on-site aluminum testing.

8. Mohs Hardness Test

The Mohs hardness test is used to rank the hardness of minerals on a scale of 1 to 10. It is primarily used in geology and material science to determine the scratch resistance of minerals and gemstones.

  • Advantages of this method. Simple and effective for determining the scratch resistance of minerals.

  • How it works. A material’s hardness is determined by its ability to scratch another substance of known hardness.

  • Common applications. Geology, mineralogy, and gemstone testing.

  • Materials used for. Minerals, gemstones.

  • Type of hardness tester for this method. Mohs hardness scale tools.

Choosing the Right Hardness Tester

When selecting the best hardness tester for different industrial applications, several factors should be considered. Key elements include the type of material being tested, the required level of precision, and the specific environment in which the testing will occur.

Choosing the right tester ensures accurate measurements and effective quality control for various materials such as metals, plastics, and composites.

Material Type

The material being tested is a crucial factor in choosing the right hardness tester. For metals, metal hardness testers such as Rockwell or Brinell testers are ideal. Softer materials, like polymers, might require a different type of tester, such as the Shore hardness tester. Testing materials with varying hardness levels often requires different testing methods to ensure accurate results.

  • Rockwell hardness testers. Ideal for metals and alloys, providing fast and accurate results.

  • Brinell hardness testers. Suitable for larger, coarse materials like castings and forgings.

  • Vickers testers. Used for precision testing on thin materials, coatings, or small parts.

Precision Requirements

For high-precision applications, such as in the aerospace or medical industries, testers like the Vickers hardness testers or portable hardness testers are recommended, as they provide detailed measurements even on small or thin materials. Lower precision may suffice for applications in manufacturing or automotive industries where broader material strength testing is needed.

  • Vickers testers. Best suited for applications requiring detailed precision on small or intricate parts.

  • Portable hardness testers. Excellent for on-site testing where precision and portability are needed.

Testing Environment

Testing environments also impact the choice of tester. Stationary testers like Rockwell hardness testers are optimal for controlled laboratory environments, while portable hardness testers are suitable for fieldwork and remote testing sites. Brinell testers are often used in industrial settings for large-scale testing of heavy materials like metals and castings.

  • Rockwell testers. Ideal for laboratory environments with a need for consistent, reliable results.

  • Brinell testers. Commonly used in factories for large components that require testing in harsh environments.

  • Portable hardness testers. Perfect for on-the-go testing in outdoor or industrial settings.

Top 6 Sectors that Use Hardness Testers

Here are the six main sectors that rely on hardness testing to verify material strength, prevent failures, and maintain quality control across various applications.

1. Aerospace Industry

In the aerospace industry, safety and performance are paramount. Hardness testing is crucial for ensuring that materials used in aircraft construction can withstand the extreme conditions they are exposed to, including high pressure, temperature fluctuations, and corrosion. The aerospace sector often employs both Rockwell hardness testers and Vickers hardness testers to validate material properties, ensuring long-term reliability and safety.

Applications in the Aerospace Industry

  • Testing turbine blades for wear resistance under high-stress conditions.

  • Verifying the hardness of landing gear components.

  • Ensuring structural integrity of fuselage materials in extreme environments.

2. Metal Processing and Fabrication

In the metal processing and fabrication industry, hardness testers play a critical role in ensuring the integrity and quality of metal products. By using metal hardness testers, technicians can verify that metals meet required specifications for hardness, which directly influences their durability and wear resistance. Rockwell hardness testers are commonly used in this industry to assess steel, aluminum, and other alloys.

Applications in Metal Processing and Fabrication

  • Verifying hardness in steel plates for construction projects.

  • Quality control during the production of metal sheets and tubing.

  • Ensuring durability and strength of fabricated metal parts.

3. Manufacturing

Hardness testers are integral in manufacturing, particularly in quality control processes. They are used to ensure that materials like metals, plastics, and rubber meet specific hardness standards. By employing hardness testers, manufacturers can prevent product failures, enhance performance, and maintain compliance with industry standards. Both portable hardness testers and bench-mounted models are commonly used in manufacturing plants for quick and accurate results.

Applications in Manufacturing

  • Testing plastic and rubber components for automotive parts.

  • Ensuring proper hardness levels for metal gears and fasteners.

  • Verifying the hardness of finished tools and equipment.

4. Automotive Industry

The automotive industry relies heavily on hardness testers for material verification during the production of vehicle components. For example, engine parts, gears, and structural elements must be tested to ensure they can withstand high levels of stress and wear. Rockwell hardness testers and Brinell hardness testers are frequently used in automotive testing for metals such as steel and iron.

Applications in the Automotive Industry

  • Testing the hardness of engine components to ensure durability under high temperatures.

  • Verifying the hardness of gears to prevent early wear and failure.

  • Ensuring the toughness of metal body parts for crash resistance.

5. Research and Development

Hardness testers are commonly used in research and development (R&D) environments for testing new materials and products. In R&D, metal hardness testers are used to evaluate new alloys, composites, and polymers. This helps researchers and engineers understand how materials will perform in real-world applications, aiding in innovation and product development.

Applications in Research and Development

  • Evaluating new alloy formulations for strength and durability.

  • Testing the hardness of composite materials for future manufacturing uses.

  • Investigating the mechanical properties of advanced polymers.

6. Electronics Industry

The electronics industry requires precise hardness testing for materials like semiconductors, connectors, and housings. Hardness testers help ensure that these materials meet specific requirements for mechanical strength and durability. In this industry, portable hardness testers are often used for on-site testing of components and materials to verify their performance in harsh conditions.

  • Ensuring the toughness of device housings to protect internal components.

  • Testing the durability of semiconductors used in devices.

  • Verifying the hardness of connector components for long-term performance.

Hardness Tester FAQ

Here are some of the most commonly asked questions about hardness testers and how they work.

What is the best way to test hardness?

The best way to test hardness depends on the material being tested and the precision required. Common methods include the Rockwell, Brinell, and Vickers hardness tests, each suitable for different materials and applications. Rockwell is often preferred for metals, while Brinell works well for softer metals and alloys.

What are the three types of hardness tests?

The three main types of hardness tests are:

  • Rockwell Hardness Test: Measures the depth of penetration under a large load.

  • Brinell Hardness Test: Uses a hardened steel or carbide ball to create an indentation on the material’s surface.

  • Vickers Hardness Test: Utilizes a diamond pyramid indenter for precise hardness measurements, especially for thin materials.

Which hardness test is most widely used in the US?

The Rockwell hardness test is the most widely used in the United States due to its simplicity, speed, and suitability for a wide range of materials, particularly metals.

What is a hardness tester used for?

A hardness tester is used to measure the resistance of a material to deformation, typically by indentation. This is crucial in quality control for industries like metal manufacturing, where the hardness of materials must meet specific standards for durability and wear resistance.

What is the most accurate hardness tester?

The Vickers hardness tester is considered the most accurate for small materials and thin sections, while Rockwell hardness testers are preferred for their balance of precision and ease of use in industrial applications.

How do Rockwell and Brinell hardness testers differ?

Rockwell hardness testers measure the depth of an indentation under load, while Brinell testers measure the diameter of an indentation made by a steel or carbide ball. Rockwell is faster and typically used for harder metals, whereas Brinell is better suited for softer metals and alloys.

What is the best portable hardness tester?

Portable hardness testers, like the Leeb rebound hardness tester, are widely regarded for their ease of use and accuracy in field applications. They are ideal for testing large or immobile objects and provide quick, reliable results.

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