Six factors affect spring fatigue strength

There is a certain relationship between the yield strength of the yield strength material and the fatigue limit. In general, the higher the yield strength of the material, the higher the fatigue strength.

Several Factors Influencing Spring Fatigue Strength

1. There is a certain relationship between the yield strength of the yield strength material and the fatigue limit. In general, the higher the yield strength of the material, the higher the fatigue strength. Therefore, in order to improve the fatigue strength of the spring, the yield strength of the spring material should be improved. Or use a material with a high yield strength and tensile strength ratio. For the same material, the fine-grained structure has a higher yield strength than the coarse-grained structure.

2. The maximum stress in the surface state occurs mostly in the surface layer of the spring material, so the surface quality of the spring has a great influence on the fatigue strength. The defects such as cracks, flaws and flaws caused by the spring material during rolling, drawing and rolling are often the cause of spring fatigue fracture.

The smaller the surface roughness of the material, the smaller the stress concentration and the higher the fatigue strength. Effect of surface roughness of material on fatigue limit. As the surface roughness increases, the fatigue limit decreases. In the case of the same roughness, different steel grades and different coiling methods have different degrees of fatigue limit reduction. For example, the degree of reduction of the cold coil spring is smaller than that of the hot coil spring. Because the steel coil spring and its heat treatment are heated, the surface of the spring material is roughened due to oxidation and decarburization occurs, which reduces the fatigue strength of the spring.

The surface of the material is ground, pressed, shot blasted and rolled. All can increase the fatigue strength of the spring.

3. The larger the size of the size-effect material, the higher the likelihood of defects due to various cold and hot-working processes and the greater the potential for surface defects, all of which can lead to reduced fatigue performance. Therefore, the effect of size effect must be considered when calculating the fatigue strength of the spring.

4. Metallurgical Defects Metallurgical defects refer to the segregation of non-metallic inclusions, bubbles, and elements in the material, and so on. Inclusions present on the surface are stress concentration sources that can cause premature fatigue cracks between the inclusions and the substrate interface. Vacuum smelting, vacuum casting and other measures can greatly improve the quality of steel.

5. When corrosive medium springs work in corrosive media, pitting or surface grain boundaries are corroded and become fatigue sources, and they gradually expand under the stress and cause fractures. For example, in spring steel working in fresh water, the fatigue limit is only 10% to 25% in the air. The effect of corrosion on the fatigue strength of the spring is not only related to the number of times the spring is subjected to variable loads, but also related to the service life. Therefore, when designing and calculating the spring affected by corrosion, the working life should be taken into consideration.

For springs operating under corrosive conditions, in order to ensure their fatigue strength, materials with high corrosion resistance, such as stainless steel, non-ferrous metals, or surfaces with protective layers such as plating, oxidation, spray, and paint, may be used. Practice shows that cadmium plating can greatly increase the fatigue limit of the spring.

6. The fatigue strength of the temperature carbon steel decreases from room temperature to 120°C and rises from 120°C to 350°C. After the temperature exceeds 350°C, it decreases again, and there is no fatigue limit at high temperatures. For springs operating at high temperatures, heat-resistant steels should be considered. Below room temperature, the fatigue limit of the steel increases.

For details on these factors that affect the fatigue strength factor, see the relevant information.

Mixed Powder

Tungsten carbide mixed Metal Alloy Powder is commonly used in PTA (Plasma Transferred Arc) welding. PTA welding is a process that involves the deposition of a hardfacing material onto a base metal to provide wear resistance, corrosion resistance, and improved mechanical properties.

Tungsten carbide is a very hard and wear-resistant material, making it ideal for applications where high abrasion resistance is required. It is often mixed with other metals, such as nickel, cobalt, or chromium, to form a metal alloy powder. These metal alloys enhance the properties of the tungsten carbide and improve its compatibility with the base metal.

The tungsten carbide mix metal alloy powder is typically fed into the PTA welding torch, where it is melted and propelled onto the surface of the base metal using a high-energy plasma arc. The molten powder forms a hard, dense coating that bonds with the base metal, providing excellent wear resistance and protection.

The specific composition of the tungsten carbide mix metal alloy powder can vary depending on the application requirements. Different ratios of tungsten carbide and other metals can be used to achieve desired properties, such as hardness, toughness, and corrosion resistance.

Overall, tungsten carbide mix metal alloy powder is a versatile and effective material for PTA welding, offering superior wear resistance and protection for various industrial applications.

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