Mechanical Properties
Silicon nitride ceramic shafts are known for their high strength and hardness, which can reach a hardness of HV1200 or more (Vickers hardness), a bending strength of 800 – 1000MPa, and a compressive strength of 600MPa or more. This makes it perform well under high loads and high stresses and can effectively resist wear and deformation, suitable for heavy-duty mechanical components. For example, in some key rotating parts of automotive engines, silicon nitride ceramic shafts can operate stably and ensure efficient engine operation.
The mechanical properties of boron nitride ceramic shafts are different. Hexagonal boron nitride ceramic hardness is low, and Mohs hardness is only 2, which makes it easy to carry out mechanical processing and can be made into a variety of complex shapes of ceramic products. However, its strength and modulus of elasticity are relatively low, and it withstands higher loads than the silicon nitride ceramic shaft. However, some of the hardness requirements are not high, but the material processability and self-lubricating needs of the occasion, boron nitride ceramic shafts show unique advantages.
Thermal Performance
From the point of view of thermal stability, silicon nitride ceramic shafts can maintain good performance in high-temperature environments; its oxidation temperature can be as high as 1400 ℃, in the dry oxidizing atmosphere below 1400 ℃ can remain stable, the use of the temperature is generally up to 1300 ℃ and can be applied even to 1800 ℃ in a neutral or reducing atmosphere. Moreover, silicon nitride has a low coefficient of thermal expansion, good dimensional stability in temperature change, and can effectively avoid material rupture due to thermal stress, which is widely used in high-temperature furnaces, heat exchangers and other equipment.
Boron nitride ceramic shaft also has excellent high-temperature resistance; in the oxidation atmosphere of 900 ℃, a nitrogen atmosphere of 2800 ℃ can be used. Its thermal conductivity is high, and hot-pressing boron nitride ceramics have excellent thermal shock resistance and can be used for rapid cooling and heating environments of the structural components. However, under vacuum conditions, boron nitride ceramics are prone to decomposition, which, to some extent, limits its application in some special environments.
Chemical stability
Silicon nitride ceramic axis of good chemical stability, in addition to hydrofluoric acid, does not react with other inorganic acids; a variety of non-ferrous metal solutions, especially aluminum solution, do not wet, can withstand strong radiation, in the chemical industry, metallurgy, and other corrosive environments have good applicability.
Boron nitride ceramic shafts in chemical stability also have a good performance, just compared to its corrosion resistance is slightly inferior in some strong corrosive environments and is not as resistant as silicon nitride ceramic shafts.
Comments
0 comment