What is fatigue strength

Factors Affecting Fatigue Strength

Several key factors influence the fatigue strength of a material. These factors determine how well a material can perform under cyclic loading and prevent fatigue failure.

Type of Load

Fatigue strength varies depending on the type of load applied to the material. Common types of loading include:

• Tension
• Compression
• Bending
• Torsion

The type and intensity of these loads significantly affect the material’s ability to resist fatigue failure.

Frequency of Load Changes

The number of load cycles a material undergoes impacts its fatigue strength. Even materials subjected to relatively low stresses can suffer fatigue if exposed to frequent cyclic loads over time. As load cycles increase, the risk of fatigue failure also grows.

Environmental Factors

Environmental conditions such as temperature, humidity, and exposure to corrosive substances (e.g., saltwater or chemicals) can further reduce fatigue strength. Materials that are consistently exposed to harsh environments are more likely to experience fatigue damage and require additional protective measures.

How to Increase Fatigue Strength

Fatigue strength can be improved through several methods, each aimed at enhancing a material’s ability to withstand repeated stresses.

Construction Design

Optimizing the design of components can reduce stress concentrations, which in turn lowers the likelihood of fatigue failure. Design strategies, such as using rounded edges or smooth transitions between different material sections, can help distribute stress more evenly across the component.

Surface Hardening

Surface hardening is one of the most effective methods for increasing fatigue strength. By hardening the outer layer of the material, surface hardening treatments improve resistance to wear and fatigue. This approach is particularly useful for components exposed to frequent cyclic loads.

Surface Hardening for Stainless Steel

For materials like stainless steel, surface hardening treatments play a crucial role in increasing fatigue strength without compromising other properties, such as corrosion resistance.

The BORINOX® Treatment

The BORINOX® treatment is a proprietary low-pressure, gas-based process that significantly enhances the fatigue strength of stainless steel. This method hardens the material’s surface without reducing its corrosion resistance, making it an ideal solution for stainless steel components in demanding environments.

Benefits of the BORINOX® Process:

• Increased Fatigue Strength: The BORINOX® process can increase fatigue strength by up to five times, allowing components to withstand more load cycles.
• Corrosion Resistance: Unlike traditional surface hardening methods, BORINOX® maintains the stainless steel’s natural corrosion resistance, ensuring long-term durability.
• Extended Component Life: By improving both fatigue strength and wear resistance, BORINOX® extends the service life of components used in high-stress environments.

Applications of Fatigue Strength in Industry

Fatigue strength is critical in many industries where materials face constant cyclic loads. Ensuring that materials can resist fatigue failure is essential for maintaining the reliability and safety of components.

Automotive Industry

In automotive applications, components such as axles, suspensions, and drive shafts are regularly subjected to cyclic stresses. Improving the fatigue strength of these components helps prevent breakdowns and extends the lifespan of vehicles.

Aerospace Industry

Aerospace components must withstand significant fatigue due to the stresses imposed by flight conditions. Enhanced fatigue strength ensures that these parts remain reliable and safe over long periods of use.

Medical Devices

Medical implants, such as joint replacements, often experience constant stress from the body’s movements. Ensuring high fatigue strength in these materials is essential for the longevity and safety of medical devices.