Overview of Silicon Carbide Ceramic

Silicon carbide (SiC) ceramic is a high-performance material known for its exceptional hardness, wear resistance, and thermal stability. It is widely used in cutting tools, abrasives, automotive components, and high-temperature applications due to its superior mechanical properties and chemical inertness.

Features of Silicon Carbide Ceramic

High Hardness: SiC ceramics are among the hardest known materials, making them ideal for abrasive and cutting applications.
Thermal Stability: They can withstand extreme temperatures without degrading, making them suitable for high-temperature environments.
Wear Resistance: Exceptional resistance to wear and abrasion ensures long-lasting performance.
Chemical Inertness: Resistant to most chemicals, including acids and alkalis, enhancing their durability in harsh conditions.
Low Thermal Expansion: Minimal expansion or contraction with temperature changes, ensuring dimensional stability.
Electrical Conductivity: Some forms of SiC ceramics exhibit semiconducting properties, useful in electronic devices.

(Pressureless Silicon Carbide Ceramic SiC Ceramic Plate 100/150, Wear-resistant Thermal Conductive Substrate)

Specifications of Pressureless Silicon Carbide Ceramic SiC Ceramic Plate 100/150, Wear-resistant Thermal Conductive Substrate

The Pressureless Silicon Carbide Porcelain SiC Porcelain Plate 100/150 is a high-performance material created for requiring industrial applications. It is used a pressureless sintering procedure. This method guarantees consistent density and structural stability. Home plate determines 100mm x 150mm in standard dimensions. Custom dimensions are available upon request. Thickness options variety from 5mm to 25mm. This product suits settings requiring severe wear resistance and thermal conductivity.

The material make-up is 99% pure silicon carbide. It has a density of 3.1 g/cm SIX. The hardness gets to 9.5 on the Mohs range. This makes it harder than a lot of metals and porcelains. Its thermal conductivity is 120 W/m · K. This permits effective warmth dissipation in high-temperature arrangements. The maximum operating temperature is 1650 ° C. It withstands thermal shock and preserves toughness under quick temperature level adjustments.

Surface area roughness is managed listed below Ra 0.4 μm. This makes sure smooth contact with various other elements. The plate is chemically inert. It stands up to acids, antacid, and harsh gases. Applications consist of semiconductor production, heater components, and mechanical seals. It is optimal for warmth exchanger parts and wear-resistant cellular linings.

Trick advantages include long life span and low maintenance. The product stands up to abrasion from fragments and rubbing. It lessens energy loss in thermal systems. Its high strength stops deformation under lots. Electrical insulation residential properties include flexibility. This makes it suitable for digital substrates and protecting parts.

The Pressureless Silicon Carbide Ceramic Plate works with vacuum cleaner and high-pressure atmospheres. It is made use of in aerospace, metallurgy, and chemical processing markets. The product fulfills ISO 9001 requirements for quality assurance. Customized surface treatments or coverings are available. These enhance performance for particular use instances.

Packaging includes protective foam and rigid containers. This prevents damages during shipping. Handling standards recommend making use of tidy handwear covers. Straight contact with oils or greases ought to be prevented. Storage space conditions require a dry, temperature-controlled environment.

(Pressureless Silicon Carbide Ceramic SiC Ceramic Plate 100/150, Wear-resistant Thermal Conductive Substrate)

Applications of Pressureless Silicon Carbide Ceramic SiC Ceramic Plate 100/150, Wear-resistant Thermal Conductive Substrate

Pressureless silicon carbide ceramic SiC ceramic plates (100/150) are advanced materials made for high-performance applications. These plates incorporate wear resistance, thermal conductivity, and structural stability. The pressureless sintering process produces a dense, uniform structure without high-pressure devices. This technique reduces production costs while maintaining material honesty.

These ceramics master extreme atmospheres. Their severe solidity stands up to abrasion from bits, chemicals, or friction. Industries like metallurgy use them for lining high-wear tools such as cyclones or chutes. Mining procedures mount them in machinery components revealed to consistent grinding. The thermal conductivity of silicon carbide permits effective heat dissipation. Electronics producers use these plates as substrates for power components or LED parts. Heat produced throughout procedure transfers rapidly, avoiding overheating.

Quality 100 and 150 describe particle size. Grade 100 has a coarser framework for sturdy wear protection. Quality 150 offers finer grains, ideal for accuracy parts needing smooth surface areas. Both grades take care of temperature levels going beyond 1600 ° C without deteriorating. This makes them optimal for heater cellular linings or kiln furniture in glass manufacturing. Their low thermal growth makes certain dimensional security during quick temperature level adjustments.

Chemical plants take advantage of the material’s rust resistance. Acids, alkalis, and solvents trigger very little damages. Elements like pump seals or shutoff components last longer in aggressive media. The material’s lightweight nature decreases stress on sustaining structures contrasted to steels.

In energy industries, these plates serve in heat exchanger systems. Their thermal efficiency improves power transfer rates. Solar energy installations use them as protective layers for receivers. Automotive industries use them in brake systems or crossbreed engine parts. The combination of durability and heat monitoring supports longer service life.

Silicon carbide porcelains are electrically conductive. This building makes it possible for uses in electrical discharge machining (EDM) or as grounding elements. Their versatility spans aerospace, defense, and semiconductor manufacturing. Custom-made shapes and sizes adjust to certain machinery requirements.

Company Introduction

Welcome to It-Chuiko, a premier international supplier of high-quality silicon carbide powder and silicon carbide ceramics. Our products are renowned for their exceptional hardness, thermal stability, and wear resistance, making them ideal for abrasives, cutting tools, refractory materials, and advanced semiconductor applications. We serve a diverse range of industries, including automotive, aerospace, and electronics, with a commitment to quality and innovation. With state-of-the-art production facilities and rigorous quality control, we ensure that our customers receive superior products tailored to their specific needs. Partner with us for reliable, high-performance materials that drive your business forward.

If you have any questions, please feel free to contact us(nanotrun@yahoo.com).

Payment Methods

T/T, Western Union, Paypal, Credit Card etc.

Shipment Methods

By air, by sea, by express, as customers request.

5 FAQs of Pressureless Silicon Carbide Ceramic SiC Ceramic Plate 100/150, Wear-resistant Thermal Conductive Substrate

1. What is the Pressureless Silicon Carbide Ceramic Plate used for? The plate is mainly used in industrial machinery parts. It works in high-wear environments like mining equipment or pump components. It is also applied in electronics as a thermal conductive substrate. The material manages heat efficiently in devices like LED modules or power electronics. Its structure supports heavy mechanical stress without breaking.

2. Why is this ceramic plate wear-resistant? Silicon carbide has a high hardness level. It ranks close to diamonds on the Mohs scale. The pressureless sintering process creates a dense structure. This reduces pores in the material. The tight grain boundaries prevent abrasive particles from causing damage. It lasts longer than metals or plastics in rough conditions.

3. How does the plate conduct heat effectively? The atomic bonds in silicon carbide transfer heat quickly. The ceramic’s purity ensures minimal impurities block thermal flow. It moves heat away from sensitive components faster than metals like aluminum. This prevents overheating in high-power applications. The plate maintains stability even with rapid temperature changes.

4. What is the difference between 100 and 150 grades? The numbers refer to grain sizes. Grade 100 has finer grains for smoother surfaces. It suits precision applications needing tight tolerances. Grade 150 has slightly larger grains. It offers better fracture resistance for heavy-impact settings. Both grades share high wear resistance and thermal performance. The choice depends on specific use cases.

5. Can this ceramic plate handle high temperatures? Yes. It operates reliably up to 1650°C in air. The material does not soften or deform under extreme heat. It resists oxidation better than many metals. This makes it ideal for furnace parts or aerospace components. Thermal shock resistance prevents cracking during sudden temperature shifts.

(Pressureless Silicon Carbide Ceramic SiC Ceramic Plate 100/150, Wear-resistant Thermal Conductive Substrate)