The performance of stainless steel plates is indeed affected by temperature, especially at high temperatures. Temperature changes affect the mechanical properties, corrosion resistance and microstructure of stainless steel. Here are a few key aspects of the impact of temperature on the performance of stainless steel plates:
There are several key differences between 316 stainless steel strip and 304 stainless steel strip in performance and application, mainly reflected in corrosion resistance, strength, processability and application scenarios: 1. Chemical composition 304 stainless steel strip: mainly composed of 18% chromium (Cr) and 8% nickel (Ni), with good corrosion resistance and strength. 316 stainless steel strip: In addition to containing 18% chromium and 8% nickel, it also contains 2%~3% molybdenum (Mo), which makes it more corrosion resistant, especially in chlorine-containing environments.
Stainless steel foils made of different materials do have certain differences in performance, which are mainly reflected in the following aspects: Corrosion resistance: 304 stainless steel: This stainless steel has good corrosion resistance and is suitable for most common environments, but may be affected in some strong acid and alkali environments.
Hot-rolled stainless steel coils have a series of remarkable performance characteristics, which make them widely used in many industries. The main performance characteristics are as follows: 1. Corrosion resistance: Hot-rolled stainless steel coils have excellent corrosion resistance due to their alloy composition, especially in corrosive environments such as chemicals and seawater. Austenitic stainless steel is particularly resistant to oxidation and corrosion.
18-8 stainless steel is a common austenitic stainless steel containing about 18% chromium and 8% nickel. Due to its unique composition and structure, 18-8 stainless steel dowel pins have significant advantages in corrosion resistance and strength, as shown below:
321 stainless steel coil has high work hardening characteristics, and is prone to surface roughness, cracks and other problems during processing. To avoid these problems, the following measures can be taken: 1. Control processing speed Work hardening is caused by a high deformation rate, so the processing speed should be controlled to avoid too fast processing speed. The cutting speed can be appropriately reduced to ensure that the contact between the tool and the material is more stable and reduce hardening.
