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1. Corrosion Resistance: In a 3.5% NaCl solution, the average annual corrosion depth is only 0.02 μm, which is four orders of magnitude lower than that of 316 stainless steel. 2. Wear Resistance: Hardness HV ≥ 1500, and the performance remains stable in environments with abrasive particle media. 3. Lightweight: Density is approximately 3.2 g/cm³, significantly reducing component inertia. 4. Thermal Shock Resistance: Can withstand rapid heating and cooling conditions (ΔT > 800℃) without easily cracking. 5. Long Lifespan: In high-pressure seawater erosion tests, the edge wear after 1000 hours of operation is only 3-5 μm.
Bulk Density: 3.1-3.3 g/cm³ Flexural Strength: 600-800 MPa Appearance Color: Blackish gray Product Purity: 99.9% Common Specifications: φ55×20×15MM, 150×20×10MM, etc.
1. Mechanical Properties: Vickers hardness can reach over 1600 HV (HRA 90+). Bending strength is as high as 600-800 MPa. It possesses high toughness and can withstand complex mechanical loads without easily fracturing or deforming. 2. High Temperature Resistance: It can operate stably in air up to 1200℃. Under a protective atmosphere, it can even reach 1400℃. It has a low thermal expansion coefficient (3.0×10⁻⁶/℃) and excellent thermal shock resistance (can withstand rapid temperature changes from 1000℃ to cold water). 3. Corrosion Resistance: It has strong resistance to acids, bases, and various corrosive media (such as molten salts and organic solvents). There is almost no corrosion in sodium hydroxide solutions with a concentration below 30%. It reacts very weakly with inorganic acids except hydrofluoric acid. 4. Self-Lubricating Properties: The SiO₂ thin film formed by surface oxidation can significantly reduce the friction coefficient (0.02-0.1). It reduces wear on the sealing interface, with a wear rate only 1/10 of traditional metal materials.
Thermal conductivity: 80±10 W/(m·K). Flexural strength: ≥700 MPa. Fracture toughness: ≥6.5 MPa·m¹/². Coefficient of thermal expansion: ≈3.2×10⁻⁶/K. Maximum operating temperature: 1400℃. Density: 3.1-3.3 g/cm³.
1. Low Density: The density is only 3.20 g/cm³ (approximately 40% of bearing steel), resulting in low centrifugal force during high-speed rotation, which significantly increases the speed limit. 2. High Hardness and Strength: Hardness reaches HV10 1480, with high fracture toughness, enabling it to withstand extreme load conditions. 3. High Temperature Resistance: It maintains its original hardness up to 400℃, and its performance only begins to decline above 800℃. It can be used up to 1000℃ (in air) or 1400℃ (in a protective atmosphere). 4. Excellent Thermal Stability: It has a low thermal expansion coefficient (3.2×10⁻⁶/℃), a thermal conductivity of 20-25 W/m·K, and good thermal shock resistance. 5. Self-Lubricating Properties: It has a low coefficient of friction and can be used in environments without lubricating media, reducing friction loss. 6. Chemical Stability: It is resistant to most acids and bases (except hydrofluoric acid and concentrated strong bases).
Bulk Density: 3.1-3.3 g/cm³. Flexural Strength: 600-800 MPa. Appearance Color: Blackish gray. Product Purity: 99.9%. Coefficient of Thermal Expansion: 3.2×10⁻⁶/℃. Maximum Operating Temperature: 1200°C.
Flexural strength: 600-800 MPa. Compressive strength: 3447 MPa. Vickers hardness: 1480-1560 HV. Coefficient of thermal expansion: 3.0-3.5 × 10⁻⁶/℃ (room temperature - 1000℃) Thermal conductivity: 20-25 W/(m·K). Fracture toughness: 6-8 MPa·m¹/².
Bulk Density: 3.1-3.3 g/cm³. Appearance Color: Blackish gray. Product Purity: 99.9%. Porosity: <1% .
This product is manufactured using silicon nitride (Si₃N₄) ceramic material, which possesses excellent characteristics such as low density, high temperature resistance, creep resistance, and high hardness. It can significantly improve engine thermal efficiency and thrust. Compared to metal blades, silicon nitride ceramic blades can withstand higher temperatures and stresses while reducing engine weight and fuel consumption.
1、High-temperature stability: It retains over 80% of its room-temperature strength at 1200°C, while the strength of metal materials decreases significantly at the same temperature. 2、Creep resistance: Under a continuous load of 50 MPa at 1200°C for 100 hours, the creep deformation is <0.1%, which is far superior to metal materials. 3、Self-lubricating properties: The dry friction coefficient is as low as 0.4-0.6, and can be further reduced to 0.3 through surface treatment, reducing friction loss. 4、Lightweight design: The density is only 2/5 that of steel, reducing equipment load while maintaining strength. Non-magnetic: Suitable for applications sensitive to electromagnetic environments, such as semiconductor manufacturing.
1、Vickers Hardness: 1450-1480 HV. 2、Flexural Strength: 850-900 MPa. 3、Fracture Toughness: 5-7MPa·m¹/². 4、Density: 3.2 g/cm³. 5、Coefficient of Thermal Expansion: 3.0-3.5×10⁻⁶ /K. 6、Thermal Conductivity: 20-30 W/m·K. 7、Maximum Operating Temperature (in air): 1000℃. 8、Maximum Operating Temperature (in protective atmosphere): 1400℃.
1. Dimensional accuracy: Up to 0.003mm. 2. Surface finish: Up to Ra0.03. 3. Applicable temperature: ≤1000℃ in air, ≤1400℃ in protective atmosphere. 4. Minimum thread size: Internal thread M2. 5. Typical specifications: φ75×20×15MM, φ185×20×15MM, etc.
1. High Hardness and Wear Resistance: Vickers hardness can reach over Hv1500, and flexural strength exceeds 800 MPa. 2. Excellent Thermal Stability: Can withstand high temperatures of 1200℃, with a low thermal expansion coefficient (approximately 3.2 × 10⁻⁶/℃). 3. Chemical Stability: Resistant to acid and alkali corrosion; the SiO₂ passivation layer formed on the surface enhances oxidation resistance. 4. Mechanical Properties: High fracture toughness (approximately 6-7 MPa·m¹/²), capable of withstanding significant mechanical stress and impact. 5. Low Friction Coefficient: Possesses a certain degree of self-lubrication, reducing friction with other materials.
1. High Hardness and Wear Resistance: Hardness is close to that of diamond (Mohs hardness 9.0), and wear resistance far surpasses traditional metal materials. 2. Excellent Thermal Stability: Withstands high temperatures up to 1200°C, has an extremely low coefficient of thermal expansion, and maintains dimensional stability under temperature changes. 3. Strong Chemical Inertness: Exhibits excellent resistance to corrosive media such as acids and bases, making it suitable for harsh environments. 4. Lightweight and High Strength: Density is only 40% of steel, but it has high bending strength and can withstand significant impact. 5. Insulating Properties: Non-conductive, suitable for applications requiring insulation, such as electronic equipment.
1. Operating Temperature: Suitable for long-term use at 1200-1600℃. 2. Mechanical Properties: Flexural strength at room temperature > 980 MPa, Young's modulus 290 GPa.
1. High-temperature performance: Strength is maintained up to 1200℃ without degradation, and decomposition only begins at 1900℃, far superior to metal materials. 2. Wear resistance: Hardness is second only to diamond, and surface roughness is superior to steel parts, reducing vibration and noise. 3. Chemical stability: Excellent corrosion resistance to most acids, bases, and molten salt media.
1、High Strength and High Hardness: Vickers hardness reaches 15-18 GPa, and flexural strength is as high as 800-1000 MPa, approaching that of alloy steel. 2、High Temperature Resistance: Can operate stably at high temperatures of 1200-1400℃, with short-term temperature resistance up to 1600℃. 3、Low Thermal Expansion Coefficient: Approximately 3.2×10⁻⁶/°C, resulting in high dimensional stability under temperature changes. 4、Excellent Thermal Shock Resistance: Can withstand rapid heating and cooling temperature changes above 800℃.
1. Density: 3.2 g/cm³. 2. Flexural Strength: 600-800 MPa. 3. Vickers Hardness: 1450-1480 HV. 4. Coefficient of Thermal Expansion: 2.7×10⁻⁶/K. 5. Thermal Conductivity: 20-30 W/m·K. 6. Fracture Toughness: 5-7MPa·m¹/². 7. Maximum Operating Temperature: 1000℃ in air / 1400℃ in protective atmosphere.
1. Hardness: HV10 > 1450. 2. Flexural Strength: >850 MPa at room temperature, >350 MPa at 1200℃. 3. Thermal Expansion Coefficient: 2.7×10⁻⁶/°C. 4. Operating Temperature: Up to 1000℃ in air, up to 1400℃ in a protective atmosphere. 5. Porosity: <0.5% (optimally 0.3%).
1. Hardness: HRA 92-94 (Vickers hardness approximately 1500 HV). 2. Bending Strength: ≥900 MPa. 3. Fracture Toughness: 6.0-8.0 MPa·m¹/². 4. Thermal Expansion Coefficient: 3.1×10⁻⁶/℃. 5. Thermal Conductivity: 23-25 W/(m·K). 6. Operating Temperature: Up to 1600℃. 7. Density: 3.2-3.3 g/cm³.
1. Superior mechanical properties: Bending strength >800 MPa (up to 1000 MPa or more), fracture toughness >6 MPa·m¹/², effectively resisting impact loads and crack propagation. 2. High hardness and wear resistance: Vickers hardness reaches Hv 1400-1600, suitable for high-wear environments. 3. Excellent thermal properties: Coefficient of thermal expansion ~3.2×10⁻⁶/K, thermal conductivity 20-30 W/m·K, excellent thermal shock resistance. 4. Chemical stability: Resistant to most acids, alkalis, and molten metal corrosion; oxidation resistance temperature can reach above 1200℃. 5. Low density: Approximately 3.2-3.3 g/cm³, contributing to lightweight equipment.
1. Lighter than metal materials but with higher strength. 2. Excellent wear resistance and self-lubricating properties. 3. Good thermal shock resistance. 4. Strong chemical inertness and corrosion resistance.
1. Excellent mechanical properties: High flexural strength (above 800 MPa) and good toughness, capable of withstanding heavy loads. 2. Superior high-temperature resistance: Maintains stable performance even in high-temperature environments of 1200°C. 3. Outstanding wear resistance: Hardness approaches that of diamond, resulting in low wear rate and long service life. 4. Excellent chemical stability: Good resistance to corrosive media such as acids and alkalis. 5. Lightweight advantage: Lower density than metal materials, reducing the overall weight of the equipment.
1. High strength: Hot-pressed silicon nitride is one of the hardest materials in the world, with a bending strength of over 800 MPa at room temperature. 2. High temperature resistance: It can operate stably for extended periods at 1400℃, and still maintains a strength of 500 MPa at high temperatures (1200℃). 3. Wear resistance: It has a Mohs hardness of 9.0, and its wear rate is only 1/10 of that of metal materials. 4. Thermal properties: It has a low coefficient of thermal expansion (3.2×10⁻⁶/℃), a thermal conductivity of 15-30 W/m·K, and excellent thermal shock resistance (ΔT>800℃). 5. Chemical stability: It exhibits good corrosion resistance to most molten metals, acids, and bases.
1. High Pressure Resistance: Can withstand alternating loads exceeding 50 MPa, suitable for high-pressure pumps, valves, and other equipment. 2. High Temperature Resistance: Maintains stable physical and chemical properties even at temperatures up to 1200°C. 3. Chemical Inertness: Exhibits strong resistance to strong acids (except hydrofluoric acid), strong bases, and various corrosive media. 4. Self-Lubricating: A silicon dioxide lubricating film can form on the surface, enabling low-wear operation without external lubrication. 5. High Mechanical Strength: Bending strength reaches 600-800 MPa, and fracture toughness is >6.0 MPa·m¹/².
1. Density: 3.20 g/cm³ (approximately 1/3 of steel). 2. Bending Strength: >900 MPa (high load capacity). 3. Fracture Toughness: ≥6 MPa·m⁻¹/² (impact resistance). 4. Operating Temperature: ≤1000℃ in air, ≤1400℃ in protective atmosphere (high-temperature stability). 5. Hardness (HV10): 1480 (wear resistance).
1. Dimensions: Common sizes include 20×20×9mm, 30×30×4mm, 50×50×0.32mm, 100×100×4mm, 107×107×4mm, and various other specifications. 2. Density: 2200-3200 kg/m³ (theoretical density 3100 kg/m³). 3. Working Temperature: Can withstand 1200℃ for short periods, with a high-temperature strength retention rate of up to 85%. 4. Bending Strength: 800-1000 MPa at room temperature, and still maintains over 500 MPa at 1200℃.
1. High temperature resistance: Can operate stably in high-temperature environments above 1200°C, with a low coefficient of thermal expansion (approximately 2.5×10⁻⁶/K), reducing thermal stress. 2. Chemical stability: Exhibits excellent resistance to molten non-ferrous metals, acidic salt spray, and organic solvents. 3. Self-lubricating properties: The glass phase at the grain boundaries, combined with a low surface roughness (Ra≤0.2μm), improves anti-adhesive wear performance. 4. Lightweight: Density is 59% lower than steel, reducing centrifugal force during high-speed operation.
1. Physical properties: Vickers hardness up to HV10 ≥ 1600, second only to superhard materials such as diamond; excellent fracture toughness (6-7 MPa·m¹/²), bending strength >800 MPa. 2. Thermal properties: High temperature resistance (stable in air up to 1000-1200℃), low thermal expansion coefficient (2.3-3.2 × 10⁻⁶/K), and strong thermal shock resistance. 3. Chemical stability: Corrosion resistance (except to hydrofluoric acid), oxidation resistance, suitable for harsh environments.
1. Mechanical Properties: Fracture toughness is twice that of alumina (6.5-8.5 MPa·m½). 2. Thermal Properties: The coefficient of thermal expansion (3.0×10⁻⁶/°C) matches that of semiconductor chips. 3. Electrical Properties: Volume resistivity >10¹⁴ Ω·cm, dielectric breakdown strength >15 kV/mm. 4. Chemical Stability: Almost no reaction with molten metals and acid/alkaline solutions below 1200°C.
1. High hardness and wear resistance: Vickers hardness reaches 1600-1800 HV, second only to a few superhard materials, effectively resisting scratches and abrasive wear. 2. Excellent thermal stability: Long-term operating temperature can reach over 1200℃, with a low thermal expansion coefficient (3.1-3.2×10⁻⁶/K), maintaining good dimensional stability under temperature changes. 3. High mechanical strength: Bending strength of 800-1200 MPa, fracture toughness of 6-8 MPa·m¹/², able to withstand considerable mechanical stress. 4. Chemical stability: Strong resistance to most acid and alkali solutions, suitable for corrosive environments. 5. Low density and lightweight: Density is approximately 3.2 g/cm³, only 40% of steel, reducing equipment weight. 6. Electrical insulation: Resistivity of 10¹⁴-10¹⁶ Ω·cm, dielectric strength up to 20 kV/mm.
1. Adaptability to Special Environments: Covers over 90% of industrial high-stress application scenarios. 2. Long Lifespan: 5-10 times longer lifespan than metal materials in corrosive environments. 3. High Precision: Low thermal expansion coefficient reduces temperature-induced deformation errors, suitable for precision manufacturing. 4. Insulation and Anti-static: Resistivity >10¹⁴ Ω·cm, suitable for environments with flammable dust.
1. High-temperature performance: Extremely low oxidation rate below 1400℃, and maintains structural stability at 1600℃. 2. Mechanical properties: Bending strength of 700-800 MPa, and fracture toughness of 6-8 MPa·m¹/². 3. Chemical stability: Corrosion rate in 98% concentrated sulfuric acid is only 0.002 mm per year.
1. High temperature resistance: Maintains strength without degradation at temperatures up to 1200℃, with short-term temperature resistance up to 1400℃. 2. Thermal shock resistance: Low thermal expansion coefficient (3.2×10⁻⁶/℃), able to withstand drastic temperature changes without cracking. 3. Abrasion resistance: High hardness and self-lubricating properties, resulting in a low coefficient of friction. 4. Chemical stability: Resistant to most acids and bases (except hydrofluoric acid and concentrated strong alkalis). 5. High mechanical strength: Compressive strength can reach over 2000 MPa, and flexural strength is 300-600 MPa.
1. Extended service life: High wear resistance significantly extends maintenance cycles. 2. Improved operating efficiency: Low friction coefficient reduces energy loss. 3. Adaptability to special environments: Stable operation under high temperature, corrosive, and high load conditions. 4. Precision machining capabilities: Capable of machining complex and irregularly shaped structures with dimensional accuracy up to 0.01mm. 5. Environmentally friendly and safe: Non-polluting, non-magnetic, and electrically insulating.
1、Density: 3.1-3.3 g/cm³. 2、Flexural Strength: 600-800 MPa. 3、Fracture Toughness: 6.5-8.5 MPa·m¹/². 4、Thermal Conductivity: 20-25 W/(m·K). 5、Coefficient of Thermal Expansion: 3.0×10⁻⁶/°C. 6、Operating Temperature: ≤1600℃. 7、Hardness: HV10 ≥ 1500.
1. High Hardness and Wear Resistance: Vickers hardness ≥1500HV, 2-3 times that of bearing steel, significantly reducing wear. 2. Low Density: Density is only 3.20 g/cm³ (approximately 40% of steel), reducing centrifugal force during high-speed rotation. 3. High Temperature Resistance: Maintains stable performance in high-temperature environments up to 800℃, with some products resistant to temperatures up to 1200℃. 4. Corrosion Resistance: Strong resistance to corrosive media such as acids, alkalis, and salts. 5. Electrical Insulation: Suitable for electrical equipment to prevent electrolytic corrosion. 6. Self-Lubricating: Low friction coefficient of 0.1-0.2, allowing use in environments without lubricating media. 7. Long Lifespan: Service life is 3-5 times that of all-steel bearings.
1、Bulk Density: 3.1-3.3 g/cm³. 2、Flexural Strength: 600-800 MPa (at room temperature). 3、Fracture Toughness: >6 MPa·m¹/². 4、Coefficient of Thermal Expansion: ~3.2×10⁻⁶/K (20-1000℃). 5、Thermal Conductivity: 20-25 W/m·K. 6、Vickers Hardness: 1500-1700 HV. 7、Maximum Operating Temperature: 1200℃ (in air), 1400℃ (in protective atmosphere).
1、Long lifespan: Excellent wear resistance significantly extends service life and reduces replacement frequency. 2、Low maintenance costs: Self-lubricating properties reduce the need for lubricants, lowering operating costs. 3、Stable performance: Maintains dimensional and performance stability at both high and low temperatures. 4、Lightweight: Lower density than metal materials, suitable for weight-sensitive applications.
1. High Temperature Stability: Can operate stably at high temperatures up to 1600℃, suitable for special environments. 2. Superior Wear Resistance: The aperture expansion is less than 0.5% after 800 hours of molten steel jetting. 3. Chemical Inertness: Resistant to all inorganic and organic acids except hydrofluoric acid and concentrated NaOH. 4. Mechanical Strength: Compressive strength reaches 2500-3447 MPa, and its lifespan is 16 times longer than that of metal materials.
1、Bulk Density: ≥2.65-2.7 g/cm³. 2、Thermal Conductivity: 160 W/(m·K). 3、Apparent Porosity: ≤14-18%. 4、Compressive Strength at Room Temperature: ≥200 MPa. 5、High-Temperature Flexural Strength: ≥50 MPa. 6、Dimensions: Plate shape (150x20x10 mm), irregular shape (70x10x10 mm), etc.
1. High hardness: Silicon nitride ceramics have a hardness second only to diamond, making them suitable for processing hard materials. 2. Wear resistance: Long service life, suitable for mass production. 3. High temperature resistance: Can maintain stable performance in high-temperature environments. 4. Chemical stability: Corrosion resistant and does not react with most chemical substances.
The performance of silicon nitride ceramic curved plates is based on the properties of the silicon nitride material itself, whose key characteristics include: 1. Excellent Mechanical Properties: High strength and high toughness: Bending strength is typically above 800 MPa, and fracture toughness can reach 6-7 MPa·m¹/², significantly superior to traditional ceramics such as alumina, making it less prone to damage under load and impact. High hardness and wear resistance: Vickers hardness can reach HV10 ≥ 1600, providing strong resistance to fretting wear and abrasive wear, making it suitable for long-term service in friction environments. High elastic modulus: Approximately 310 GPa, giving the material high rigidity and helping to maintain the shape stability of the curved structure under load. 2. Excellent Thermal and Chemical Properties: Good thermal conductivity: Thermal conductivity is in the range of 20–30 W/(m·K), outstanding among non-oxide ceramics, facilitating heat transfer and dissipation. Low thermal expansion coefficient and high thermal shock resistance: The thermal expansion coefficient is approximately 2.3-3.2 × 10⁻⁶ /K, much lower than metal materials. Combined with its high strength, it can withstand drastic temperature changes exceeding 800°C without cracking. Stable chemical inertness: Resistant to corrosion from almost all inorganic acids except hydrofluoric acid, with an oxidation resistance temperature above 1400°C, and non-wetting to many molten metals and non-metals. 3. Other Key Characteristics: Low density: Density is approximately 3.1-3.3 g/cm³, contributing to lightweight design. Excellent insulation: Resistivity is higher than 10¹⁴ Ω·cm, possessing excellent electrical insulation capabilities. Self-lubricating tendency: During friction, especially in the presence of trace amounts of water vapor, a silicon dioxide lubricating film may form on the surface, helping to reduce the friction coefficient.
1、Lightweight and high rigidity. 2、Wear resistance and long service life. 3、High temperature resistance and chemical stability. 4、Low friction and electrical insulation. 5、High rotational speed and high precision.
-High-performance grinding and dispersion balls made of silicon-based ceramics, possessing high hardness and excellent wear resistance. -Excellent wear resistance and low impurity content in the balls. -Suitable for sub-micron grinding of high-performance materials. -Supports grinding and dispersion under high impact conditions in rolling ball mills, planetary mills, vibratory mills, and sand mills.
(1)、 Corrosion resistance: It can be used in strong acids and bases. Except for hydrofluoric acid, it does not react with other inorganic acids. (2) 、High temperature resistance: The strength and hardness of silicon nitride ceramics remain almost unchanged at 1200℃, and it does not melt into a liquid state when heated; it only decomposes at 1900℃. (3) 、Non-magnetic, electrically insulating, and low thermal conductivity: It can be used as an insulating and heat-insulating material. (4) 、Wear resistance, lightweight, and higher strength and hardness than general ceramic materials. (5)、 Low thermal expansion coefficient: It can withstand rapid temperature changes. Even when heated to above 1000℃ in air, then rapidly cooled and rapidly reheated, it will not crack.
This silicon nitride ceramic locating pin is sintered under 100 bar atmospheric pressure and is a high-strength material with excellent properties. Preferred for welding applications: - Ultra-high hardness and bending strength. - High thermal shock resistance. - Electrical insulation. - High temperature resistance. - High tensile and compressive strength. - Less cold welding. - No welding spatter adhesion.
This silicon nitride ceramic locating pin is sintered under 100 bar atmospheric pressure and is made of a high-strength material with excellent properties. Preferred for welding applications: - Ultra-high hardness and bending strength. - High thermal shock resistance. - Electrical insulation. - High temperature resistance. - High tensile and compressive strength. - Less cold welding. - No welding spatter adhesion.
1、High hardness and wear resistance. 2、Excellent high-temperature resistance. 3、Outstanding corrosion resistance. 4、Lightweight design combined with high strength. 5、High precision and dimensional stability. 6、Good electrical insulation and non-magnetic properties.
1. Excellent wear resistance. 2. Wear resistance, less impurities in the ball. 3. Suitable for submicron grinding of high functional materials.
1. High Hardness and High Strength. 2. Low Density and Lightweight. 3. Excellent Wear Resistance and Long Lifespan. 4. High Temperature Resistance and Thermal Stability. 5. Corrosion Resistance and Chemical Stability. 6. Electrical Insulation and Non-magnetic Properties. 7. Self-lubricating and Low Maintenance Requirements.
Material: Silicon nitride ceramic. Density: 3.23-3.27g/cm³. Color: Black & Gray. Grade: G3~G100. Specification: φ0.6-φ110mm. Sintering process: HIP&GPS.
该氮化硅陶瓷定位销在 100 bar 大气压力下烧结,是具有高强度和出色特性材料。 用于焊接的首选: -超高硬度和弯曲强度 -高抗热冲击性能 -电绝缘性 -耐高温性能 -高张力强度和压缩强度 -更少冷焊 -无焊接溅洒黏着
This silicon nitride ceramic locating pin is sintered under 100 bar atmospheric pressure and is a high-strength material with excellent properties. Preferred for welding applications: - Ultra-high hardness and bending strength - High thermal shock resistance - Electrical insulation - High temperature resistance - High tensile and compressive strength - Less cold welding - No welding spatter adhesion
Product features: Lightweight, wear-resistant, long-lasting, high-strength, self-lubricating, and electrically insulating. It provides reliability and safety in applications requiring high rotational speed, maintenance-free operation, and protection against electrochemical corrosion.
● High-performance grinding and dispersion balls possessing the high hardness and excellent wear resistance of silicon-based ceramics. ● Excellent wear resistance and low impurity content in the balls. ● Suitable for sub-micron grinding of high-performance materials. ● Supports grinding and dispersion under high impact conditions in rolling ball mills, planetary mills, vibratory mills, sand mills, etc.
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