Before purchasing or using a high-temperature sintering furnace, it is important to understand its application range. Using it improperly can lead to poor results or equipment issues. Below is a summary of its main applications:
- Ceramic Materials
- Sintering various white porcelain, stoneware, thin-bodied porcelain, and bone china in a high-temperature furnace can reduce firing costs by over 50% compared to traditional gas or oil furnaces, while improving product yield.
- Large red porcelain and blue-and-white porcelain can be sintered with higher yield, shorter firing time, and lower energy consumption.
- High-temperature furnaces can sinter oxide, nitride, carbide, and multiphase ceramic materials, significantly reducing firing time and temperature, minimizing deformation, increasing yield, saving energy, and lowering production costs.
- Powder Metallurgy Materials
- Hard Alloys: High-temperature furnaces enable large-scale industrial production of sintered hard alloy tools. Rapid sintering produces fine carbide grains, greatly improving product performance.
- Sintering various tungsten alloys.
- Sintering various iron-based and copper-based powder metallurgy components.
- Magnetic Materials
- Sintering Ni-Zn soft ferrite materials and Mn-Zn soft ferrite materials with improved high-frequency characteristics compared to conventional sintering furnaces.
- Sintering oriented ferrite materials, which under the same formula achieve lower losses and better performance.
- Synthetic Vanadium Nitride and Iron-Based Nitride Alloys
- High-temperature synthesis enables large-scale production of silicon-iron nitride, manganese-iron nitride, chromium-iron nitride, and other special iron nitride alloys, reducing unit energy consumption and improving product performance.