What is the hardness of rubber?
Rubber hardness refers to its resistance to indentation by external force, typically measured using Shore Hardness or International Rubber Hardness (IRHD). Higher numbers indicate greater hardness, while lower numbers denote softer material.
For example, 65A rubber may exhibit significant variations in elasticity depending on the formulation.
Hardness Units and Ranges
Shore Hardness: Divided into Type A (soft rubber, 20-95 degrees)—our company’s rubber flat belts fall within this range—and Type D (hard rubber, above 90 degrees)
Sealing rings typically use 20-50° (Type A), while industrial rollers can reach 80-95° (Type A) or Type D 50-90°.
IRHD: Applicable for the 10-100 IRHD range, measured by indentation depth using a ball indenter.
How is material hardness measured?
Shore hardness scales
Shore scales can be used as a method of measuring and comparing the hardness of rubbers and elastomers. They are also commonly used for softer plastics such as polyolefins, fluoropolymers, and vinyl. There are around fifteen different shore hardness scales which can be used to measure the hardness of the different materials.
The Shore A scale is most commonly used for measuring the hardness of rubbers and can be determined using a durometer gauge. The durometer consists of a metal truncated cone indenter, attached to a small spring as shown in the diagram above the indenter is extended 2.5mm into the material. The material will resist the indentation, deflecting the spring. Every 0.001 inch that the spring is deflected relates to 1-degree shore A. Harder materials will resist the indentation, this will cause the deflection of the spring to be higher and will result in a higher reading. The diagram below gives a representation of each of the shore hardness values. Shore 70 A is the standard hardness for rubber.
The great thing about the shore hardness scale is that you can measure any material. This scale has been adapted to meet the needs or requirements for any material measurement. The Shore A scale is often used for measuring softer rubbers and the Shore D scale is used for harder ones. The shore D scale was developed to measure the hardness of hard rubbers which have a value of over 90 degrees on the Shore A scale. Similarly, shore 0 was introduced to measure the hardness of soft rubbers which record less than 10 degrees on the Shore A scale. Shore 00 was introduced for very soft rubbers or gels which recorded less than 10 degrees on the shore 0 scale. Shore B and Shore C are intermediate scales intended for use on medium and moderately hard rubbers. A comparison of Shore Scales A, D, 0 and 00 are given in the table below.
The shape of the indenter that is used on the durometer and the spring force vary by scale. For example, shore D uses a sharply pointed indenter and a spring force of 10lbs (4.5 kg) whereas the indenter for shore 00 has a blunt point and a spring force of only 113g.
Shore hardness testing will often leave a permanent indentation in the test sample. Another consideration is that the material must be at least 6mm thick and positioned on a hard surface to get an accurate reading. If the material is too thin, the durometer will measure the hardness of the surface on which the material is placed. Due to the mechanical limits of the test instruments,hardness measurements in elastomers are normally expressed in 5-degree increments.
How to measure rubber and polyurethane roller hardness (Shore-A scale)
Roller hardness indicates how resistant the rubber surface is to indentation, which affects the roller’s performance in various applications. It’s measured using the Shore Hardness Scale, with the Shore A scale being the most common for rubber and polyurethane materials. A higher Shore A number signifies a harder material.
Precise hardness measurements ensure that your rollers perform optimally, leading to:
- Consistent product quality: maintaining the desired hardness ensures uniformity
- Extended roller lifespan: proper hardness reduces wear and tear, enhancing durability.
- Operational efficiency: accurate measurements prevent issues like excessive vibration or material deformation during use.
A tool called a durometer is used to measure the hardness. The scale runs from 0 to 100:
- Lower numbers = Softer rubber and PU.
- Higher numbers = Harder rubber and PU.
The Shore-A scale works for most rubber and polyurethane rollers. For very hard materials (like “ebonite”), we use a different scale called Shore-D.
Tips for accurate hardness measurements
To ensure accurate readings, keep these points in mind:
- Regular calibration: durometers need to be checked against a standard regularly to ensure they’re working correctly.
- Different durometers, different readings: using different tools can give slightly different results (up to 4 points or more).
Technique matters: measurements can vary based on how you use the durometer. Follow the correct method below.
Correct way to measure hardness
1. Roller surface:
Ensure the surface is clean, smooth, and free from contaminants. Imperfections can lead to inaccurate readings
2. Positioning:
Place the durometer perpendicular to the roller surface, ensuring full contact without tilting.
Start measuring 25 mm (1 inch) from each end of the roller.
3. Apply pressure:
Gently press the durometer down without slamming it. Use about 1 kg (2 pounds) of pressure.
Take the reading immediately upon full contact (within 2 seconds).
4. Temperature:
Measure at room temperature (around 23°C or 74°F). Temperature variations can affect rubber hardness readings.
By following these guidelines, you can reliably measure the hardness of your rubber and polyurethane rollers and optimize performance.
What properties are related to the hardness of rubber?
1. Tensile Strength and Tear Strength
Hardness exhibits a positive correlation with tensile strength and tear strength, but a critical threshold exists. As hardness increases from 50A to 70A, molecular chain crosslinking density rises, enhancing tensile and tear resistance. However, beyond 90A, material brittleness increases, making it prone to fracture due to stress concentration.
2. Compression Set
Low-hardness rubber (below 40A) exhibits superior recovery after compression, making it suitable for sealing applications. High-hardness rubber (above 70A) shows higher compression set rates, leading to seal failure under prolonged pressure.
3. Elasticity
Hardness is inversely related to elasticity:
– Low-hardness rubber (30-50A) offers excellent elasticity, ideal for shock absorbers. High-hardness rubber (60-80A) increases damping but reduces elasticity, suitable for wear-resistant components.
4. Wear Resistance
Increased hardness enhances wear resistance, e.g., extrusion haul off belts reach 65A hardness to withstand abrasion.
However, elasticity must be balanced to prevent fatigue cracks caused by excessive hardness.
5. Weather Resistance and Chemical Resistance
High-hardness rubber, with its dense molecular structure, offers superior resistance to UV radiation, ozone, and chemical media (e.g., oils).
However, rubber hardness decreases at high temperatures (e.g., nitrile rubber loses 20% hardness at 100°C), leading to degraded sealing performance; low temperatures may cause embrittlement.
6. Friction Coefficient
Low-hardness rubber (e.g., 35°C folder gluer paper feed belts) exhibits high surface adhesion and significant friction. High-hardness rubber (e.g., 65A extrusion haul off belts) has a low friction coefficient, making it unsuitable for paper transmission but ideal for traction applications due to its excellent wear re
Summary: Measuring rubber hardness is crucial for quality control and process optimization. As a manufacturer, Yonghang can adjust formulations, as hardness directly correlates with raw material composition (e.g., rubber content, filler type). A 10% decrease in rubber content typically increases hardness by approximately 3-5 degrees. Hardness testing enables optimization of formulation ratios.
Summary: The Significance of Measuring Rubber Hardness
Measuring rubber hardness is crucial for quality control and process optimization. As a manufacturer, Yonghang can adjust formulations, as hardness directly correlates with raw material composition (e.g., rubber content, filler type). A 10% decrease in rubber content typically increases hardness by approximately 3-5 degrees. Hardness testing enables optimization of formulation ratios.
Mechanical and dynamic performance insights: Hardness changes over time indirectly reflect material aging, providing a basis for predicting service life. Hardness testing is not only a fundamental step in rubber R&D and production but also a core metric for optimizing product performance and ensuring application reliability.
