In the field of precision manufacturing, the precision requirements for small parts such as micro gears, medical implant components, and electronic connectors often reach the 0.01 mm level. Traditional processing techniques often fall into the dilemma of "difficult to form and difficult to control p

The aerospace industry, as the "crown" of high-end manufacturing, imposes nearly stringent requirements on components: they must not only possess extreme properties such as high strength, heat resistance, and corrosion resistance but also balance lightweight design, complex irregular structures, and

To achieve high-precision metal parts production through Metal Injection Molding (MIM), the following key aspects can be addressed:Raw Material Selection and Preparation: Select metal powders with fine and uniform particle sizes, typically ranging from 2 to 25 micrometers. For instance, the particle

304 stainless steel is highly sought after in precision manufacturing due to its excellent corrosion resistance and mechanical properties. Powder metallurgy technology achieves dual breakthroughs in material utilization and part precision through a net-shaping process of "powder → forming → sinterin

Metal Injection Molding (MIM), as an advanced technology that integrates plastic injection molding and powder metallurgy, has become a key process in high-end manufacturing due to its advantages of "complex molding + mass production." The process involves four core stages, each relying on breakthrou

In the field of precision manufacturing, the processing of complex components (such as parts with microholes, thin walls, and non-standard structures) has always been a major industry challenge. Metal injection molding (MIM), with its unique process characteristics, has become a key technology for o