Traditional ceramics are limited by brittleness, fragility, low impact resistance, not easy to process, and other shortcomings, it is difficult to be widely used, and Ti3AlC2 new ceramics make up for this vacancy; it integrates the performance of ceramics and metals: The metal has good electrical conductivity, high thermal conductivity, machinability, thermal shock resistance, high-temperature plasticity, and high-temperature strength, and has good corrosion resistance, high modulus, low friction coefficient and self-lubrication of ceramic materials. In addition, Ti3AlC2 also has a low density, in line with the development requirements of the lightweight era, given the many excellent properties of MAX phase, corrosion-resistant material. Corruption is one of the main culprits of material loss and scrap, and corrosion failure caused by pollution has brought significant economic losses to people. It may even endanger people's life safety. As a new era of corrosion-resistant material, the MAX phase has high surface hardness after carbonization. It is ingenious and can form an excellent corrosion resistance protective layer with excellent corrosion resistance.
Moreover, this surface treatment process is very cheap and easy to operate. In addition, the density of MAX phase material is much lower than that of the most widely used steel material, and it can withstand a specific impact force. Therefore, when partially replacing steel components, it can not only realize the demand for lightweight times but also meet the traditional demand for anti-corrosion, especially in the Marine industry and ship transportation where the corrosive environment is harsh. For example, some need to replace the anti-corrosion treatment of the filter and seals—high-temperature structural materials. The hardness of nickel alloy, which is an excellent high-temperature structural material, is only half that of MAX phase material. When the temperature exceeds 1200℃, Ti3AlC2 can still maintain good strength, but the failure transition of Ni-based alloy begins. It can be seen that the high-temperature stability of the MAX phase is more vital than that of Ni-based alloy. In addition, the MAX phase has excellent processing performance and can fully meet the requirements of high-temperature structural materials. It is an ideal candidate material for preparing high-temperature components such as guide blades, turbine blades, high-pressure compressor discs, turbine discs, and combustion chambers of a gas engine If you are looking for high quality, high purity and cost-effective titanium aluminum carbide, or if you require the latest price of titanium aluminum carbide, please feel free to email contact mis-asia.
