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Silicon Carbide ceramic - The Future of Advanced Ceramics

时间:2024-1-23 20:45     作者:emer     分类: news


Silicon carbide ceramic is an engineering ceramic distinguished by its superior strength, high temperature resistance and wear resistance. Naturally occurring examples are found within Canyon Diablo meteorite's moissanite minerals.

SiC is used in multiple industries such as automotive, aerospace, electronics, and energy for components that must withstand extreme conditions. This article will outline some of its major advantages.
Thermal Conductivity

Silicon carbide is one of the hardest materials known, requiring diamond-tipped blades to cut. Produced as powder and crystal form, silicon carbide can be found in applications requiring high endurance such as car brakes and clutches as well as bulletproof vest ceramic plates. Furthermore, cutting and grinding operations use this material; electronic applications include light emitting diodes (LED) as well as detectors.

Thermal conductivity of silicon carbide ceramic goes beyond its hardness and resistance to corrosion; it offers lower melting point than silicon and conducts heat more effectively at higher temperatures than traditional ceramics, making it an excellent choice for high voltage power applications where heat damage may occur.

Silicon carbide's wide bandgap enables it to withstand higher voltages than standard silicon semiconductors, making it an excellent choice for applications like electric vehicles where higher voltages increase efficiency and speed of operation. Furthermore, silicon carbide's thermal conductivity makes active cooling systems unnecessary which adds weight and costs significantly more than using passive cooling methods like active fans.

Silicon carbide and other advanced ceramics offer many unique properties, enabling them to be utilized in an array of applications with considerable advantages over more conventional metals. Their ability to withstand high temperatures, pressures, voltages, and other properties make these materials increasingly useful in various industries and can even replace metals altogether in certain circumstances.
High Strength

Silicon Carbide is one of the hardest synthetic materials known, boasting a Mohs hardness rating of 9. It can withstand impact without damage and chemical reaction and high temperature resistance make it popular as grinding wheel material, while its resistance is an integral component in making refractory materials.

Silicon carbide's crystalline structure lends it exceptional wear resistance, and its corrosion-resistance allows it to stand up well against aggressive media such as water/steam at several hundred degrees Celsius. Furthermore, silicon carbide's thermal shock resistance makes it suitable as a seal material in bearings or mechanical seals.

Silicon carbide ceramic boasts impressive strength due to their zero porosity properties; therefore no air pockets can form. Furthermore, this feature contributes to their dimensional stability; maintaining their strength even when subjected to extreme temperatures or rapid heating/cooling cycles.

Silicon Carbide ceramics excel at increasing both their strength and durability due to their low thermal expansion coefficient, meaning that they maintain their shape at high temperatures while withstanding thermal shock - making them particularly suitable for applications like petrochemical equipment, metallurgical machinery and aerospace components.

Silicon carbide can be produced using various sintering methods, depending on its end product requirements. Sintered silicon carbide (SiSiC) is typically formed from pure SiC powder treated with oxide-free sintering aids in an inert atmosphere at temperatures exceeding 2,000degC through dry pressing or extrusion processes, while reaction bonded silicon carbide (SiC-RB) is formed by adding porous carbon to molten SiC during additive sintering casting for reaction bonding which results in fully densified ceramic with outstanding chemical, abrasion, and impact resistance in end use conditions extreme environments.
High Temperature Resistance

Silicon Carbide (SiC) is one of the hardest and heat-resistant engineering ceramics. With strength reaching 27 GPa for polycrystalline silicon carbide (SiC), creep resistance is outstanding and thermal expansion and corrosion resistance low - all characteristics which make SiC an excellent candidate for applications where temperature control is important.

Silicon Carbide not only stands up well to abrasion resistance, but is also highly resistant to corrosion and chemicals such as acids and lyes. Furthermore, its stability at temperatures above 1600 degC makes it extremely chemical inert.

So it can withstand conditions ranging from corrosion, high vibration and shock loads, and extreme temperatures to be used in power applications, including electric motors, onboard chargers and converters. Its versatility also makes it a valuable material choice.

Silicon Carbide stands out among other materials because of its wide bandgap, or energy gap that determines whether a material conducts electricity or insulates. This property allows silicon carbide to withstand both electrical and mechanical stress caused by high voltages - essential in power applications.

Silicon Carbide fabrication can be challenging due to its wide bandgap. Regular sintering methods typically fail in producing fully dense material due to SiC powder's tendency to form neck regions which then volatize out of the body and form SiO2. To combat this issue, clay-bonded silicon carbide production can be done by mixing SiC powder with 10-50% clay powder before firing it; this prevents neck regions and results in more consistent dense bodies without neck regions forming.
High Wear Resistance

Silicon carbide is one of the hardest ceramic substances, offering exceptional wear resistance and corrosion protection, making it suitable for demanding conditions such as 3D printing, ballistics or parts for pump shafts and drive systems.

SiC is often used in applications that require resistance against abrasion and erosion; when combined with carbon it forms a harder material with increased resilience. Common examples include sandpaper, cutting tools and grinding wheels made of this material. Refractory linings for industrial furnaces often feature this hardy substance too as do pump and rocket engine parts with increased wear resistance as well as semiconductor substrates used as light emitting diodes (LEDs).

SiC is enhanced with graphene by fivefold in terms of strength and hardness, as well as added ductility that allows it to be used in high pressure/temperature environments such as automotive brakes/clutches.

Silicon Carbide, an advanced ceramic with an extremely high Young's modulus of over 400GPa and excellent tensile strength, provides outstanding resistance against bending and stretching as well as acids/lyes as well as having exceptional electrical properties including low thermal expansion.

silicon carbide's unique properties have made it an indispensable material for advanced circuit elements in electric vehicles and solar power inverters, offering protection from high voltages as well as sudden current changes. It can withstand high voltages while safeguarding electronics against damage caused by sudden current changes.
Low Thermal Expansion

Silicon Carbide boasts a low coefficient of thermal expansion, making it an excellent material choice for applications requiring high temperature resistance and chemical environmental tolerance. Capable of withstanding temperatures up to 1400oC without losing strength or dimension stability, its corrosion and abrasion resistance make it suitable for industrial components like wear-resistant grinding wheels, cutting tools and refractory linings; its ability to resist ballistic impact makes it perfect as an ingredient in bulletproof vests.

Silicon carbide (SiC) can be found naturally in moissanite, though synthetic production has become the main form of production since late 19th century. Since that time, silicon carbide has been widely utilized as an abrasive, refractory material and wear-resistant part for industrial furnaces; semiconductor components and electrical insulation components (such as brushes for electric motors ) also utilize it.

Electrical properties of silicon carbide ceramic make it an attractive material for power electronics applications, where its resistance to high voltage and extreme temperatures makes it suitable. In comparison with traditional semiconductor silicon, its much wider bandgap allows more efficient transference of electrical energy between its conducting and insulating states - something particularly beneficial in applications like traction inverters or DC-to-DC converters on electric vehicles, where increased efficiency helps lower overall vehicle weight, complexity and fuel consumption.

标签: Silicon Carbide Silicon Carbide ceramic