Grinding components play an indispensable role in high-precision manufacturing across numerous mechanical processing fields, thanks to their unique processing characteristics and wide-ranging applications. Grinding, a method that utilizes abrasives and tools to perform micro-cutting and finishing on workpiece surfaces, aims to enhance dimensional accuracy, shape precision, and reduce surface roughness, thereby meeting diverse high-precision application requirements.
Stainless steel is widely used in construction, machinery, chemical engineering, and other fields due to its excellent corrosion resistance, strength, and aesthetic appeal. However, different applications have varying performance requirements for stainless steel, making it crucial to select the appropriate processing technology. This article will outline common stainless steel processing methods and their suitable scenarios to help you quickly find the optimal solution.
Titanium alloys can be classified according to tensile strength, generally divided into low strength (≤600 MPa), medium strength (600-900 MPa), high strength (900-1200 MPa) and ultra-high strength (≥1200 MPa) four grades.
The global titanium alloy processing field is ushering in a new round of technological revolution. With the rapid development of aerospace, medical devices and new energy industries, titanium alloy has become a strategic material in high-end manufacturing with its advantages of high strength, corrosion resistance and biocompatibility.
