Silicon carbide is widely used in the nonferrous metal industry thanks to its exceptional properties. It is highly resistant to high temperatures, boasts impressive strength, and provides excellent heat conduction capabilities. Additionally, it offers exceptional impact resistance, making it an ideal material for use in high-temperature direct heating applications. Examples of devices that benefit from its use include hard pot distillation furnaces, distillation furnace trays, aluminum electrolytic cells, copper melting furnace linings, zinc powder furnace arc plates, and thermocouple maintenance tubes. These applications require reliable and durable materials, making silicon carbide an optimal choice due to its superior qualities.
Silicon carbide has proven to be highly beneficial in the iron and steel industry due to its remarkable properties. Its corrosion resistance, thermal shock resistance, wear resistance, and excellent heat conduction make it a valuable material. One of its prominent applications is in improving the service life of large blast furnace linings. Additionally, it finds extensive use in metallurgical beneficiation processes. Consequently, the usage of silicon carbide has greatly contributed to enhanced performance and longevity in the iron and steel sector.
The ceramic grinding wheel industry utilizes the thermal conductivity of building materials. This is due to its unique characteristics of heat radiation and high heat intensity. By leveraging these properties, the industry is able to produce thin plate kiln furniture. The use of thin plate kiln furniture offers several advantages. Firstly, it reduces the capacity of kiln furniture, thereby creating more space for other materials. Secondly, it improves the installed capacity and product quality of the kiln. Lastly, it helps to shorten the production cycle. These advantages directly contribute to the ambition of ceramic glaze baking and sintering, ultimately resulting in enhanced productivity and efficiency.
By utilizing exceptional thermal stability and heat conduction as a heat exchanger, significant energy savings can be achieved. Fuel consumption can be reduced by up to 20%, while fuel usage can be cut by 35%. Additionally, production rate can be improved by 20-30%. The discharge and transportation pipes employed in mine concentrators also benefit from increased wear resistance, boasting 6-7 times greater durability than general wear-resistant materials.