With the development of renewable energy sources such as wind and solar, along with the increased demand for electric power in industries and automobiles, enhancing the efficiency of energy transmission has become increasingly important. Utilizing high DC voltage transmission lines can reduce energy losses; however, operating at higher voltages can induce mechanical stresses, potentially leading to the early failure of key components.
Silicon Carbide (SiC) particles are widely utilized due to their nonlinear response characteristics, which help dissipate electric fields, lower electrical conductivity, and reduce stress concentrations at critical points. The continuous “on” state of Silicon Carbide ensures a stable and gradual electrical response across a wide range of electric fields. Additionally, the high thermal conductivity of SiC powders aids in heat dissipation, preventing chemical and electrical degradation.
Incorporating Silicon Carbide powders into various materials operating under high electric fields and electric stress conditions can effectively manage and adjust electric fields, thereby extending the lifespan of critical electrical components and reducing failure rates. By precisely controlling the purity, particle size, shape, and electrical conductivity of Silicon Carbide powders, customized solutions can be developed for specific electrical applications, meeting stringent performance requirements.