SILICON CARBIDE GRIT AND METHOD FOR PRODUCING SAME

Abstract

A silicon carbide gravel usable, for example, for refractory products, and a method for the production of different qualities and grain sizes of silicon carbide gravel. The silicon carbide gravel includes SiC particles having a high density. Particles of the silicon carbide gravel consist to an extent of at least 85 mass % of SiC waste products and have a density of 2.89 to 3.20 g/cm3, a compressive strength of >2500 MPa, a fraction of <5% of pores with an equivalent diameter of >100 m and a fraction of open porosity of <10%. The silicon carbide gravel consists at least predominantly of particles with particle sizes of greater than or equal to 2 mm and the particles have an irregular shape produced by a mechanical loading.

Claims

1. A silicon carbide gravel, whose particles consist of at least 85% by mass silicon carbide from SiC waste products and have a density of 2.89 to 3.20 g/cm3, a compressive strength of >2500 MPa, a fraction of <5% of pores with an equivalent diameter of >100 m, and a fraction of open porosity of <10%, wherein the silicon carbide gravel consists at least predominantly of particles with particle sizes of greater than or equal to 2 mm and the particles have an irregular shape with a roundness of 0.5 to 0.8 produced by a mechanical loading with an energy input of between 0.1 and 5 MJ/kg.

2. The silicon carbide gravel according to claim 1, in which products from the Acheson process or SiC sintering scrap or manufacturing-related SiC waste from product manufacturing are present as SiC waste products, whose particles, which consist of at least 85% by mass silicon carbide and have a density of 2.89 to 3.20 g/cm3, a compressive strength of >2500 MPa, a fraction of <5% of pores with an equivalent diameter of >100 m, and a fraction of open porosity of <10%, wherein the particles have at least predominantly particle sizes of greater than or equal to 2 mm and the particles have an irregular shape with a roundness of 0.5 to 0.8 produced by a mechanical loading with an energy input of between 0.1 and 5 MJ/kg

3. The silicon carbide gravel according to claim 2, in which such products made from SSiC, LPS-SiC, SiSiC, RSiC, NSiC and/or OBSiC ceramics and/or fiber composites from C-SiC and/or SiC-SiC are present as SiC waste products.

4. The silicon carbide gravel according to claim 1, which consists of at least 90% by mass, advantageously 95% by mass, more advantageously 98% by mass of silicon carbide.

5. The silicon carbide gravel according to claim 1, whose particles have a density of 3.05 to 3.20 g/cm3.

6. The silicon carbide gravel according to claim 1, which consists at least predominantly, advantageously at least 85%, more advantageously at least 95% of particles with a particle size greater than or equal to 2 mm.

7. The silicon carbide gravel according to claim 1, in which particle sizes between greater than or equal to 2 to 20 mm, or 5 mm to 63 mm, are present.

8. The silicon carbide gravel according to claim 1, which has particle shapes, which are achieved after a mechanical loading of the SiC waste products by applying a mechanical impulse, advantageously, by mixing, milling, more advantageously, by autogenous milling, or have been produced by using eddy currents and/or ultrasound, or by grinding, hammering, breaking or by electrical discharges or shock waves.

9. The silicon carbide gravel according to claim 1, which has irregular completely and/or partially sharp-edged and/or irregular completely or partially rounded particle shapes.

10. A method for the production of silicon carbide gravel, in which SiC waste products, except for SiC dust, are processed into SiC particles by mechanical loading with an energy input between 0.1 and 5 MJ/kg, which consist of at least 85% by mass of silicon carbide and have a density of 2.89 to 3.20 g/cm3, a compressive strength of >2500 MPa, a fraction of <5% of pores with an equivalent diameter of >100 m, and a fraction of open porosity of <10%, and with particle sizes greater than or equal to 2 mm and an irregular shape with a roundness of 0.5 to 0.8, or in which for the production of silicon carbide gravel, SiC waste products are processed into SiC particles before and/or after a temperature treatment under vacuum or non-oxidizing atmosphere at temperatures of 1400 to 2600 C. by mechanical loading with an energy input between 0.1 and 5 MJ/kg, which consist of at least 85% by mass of silicon carbide and have a density of 2.89 to 3.20 g/cm3, a compressive strength of >2500 MPa, a fraction of <5% of pores with an equivalent diameter of >100 m, and a fraction of open porosity of <10%, and with particle sizes greater than or equal to 2 mm and an irregular shape with a roundness of 0.5 to 0.8, or in which for the production of silicon carbide gravel, in which SiC waste products are processed into SiC particles before and/or after a temperature treatment under vacuum or non-oxidizing atmosphere at temperatures of 1400 to 2600 C. by mechanical loading with an energy input between 0.1 and 5 MJ/kg, which consist of at least 85% by mass of silicon carbide and have a density of 2.89 to 3.20 g/cm3, a compressive strength of >2500 MPa, a fraction of <5% of pores with an equivalent diameter of >100 m, and a fraction of open porosity of <10%, and with particle sizes greater than or equal to 2 mm and an irregular shape with a roundness of 0.5 to 0.8, wherein such particles may be mechanically treated again, and at the same time or thereafter are physically separated into two fractions, of which the mass of impurities in one fraction is at least higher by a factor of 2 than in the other fraction.

11. The method according to claim 10, in which a physical separation of the SiC particles in fractions is carried out at least after one or the last treatment under mechanical loading of the SiC particles.

12. The method according to claim 10, in which SiC waste products are subjected to a temperature treatment under vacuum or non-oxidizing atmosphere at temperatures of 1400 to 2600 C., then a treatment under mechanical loading, and then a physical separation of the SiC particles in fractions.

13. The method according to claim 10, in which SiC waste products with a density of 3.05 to 3.20 g/cm3 are used.

14. The method according to claim 10, in which the mechanical loading of the SiC waste products is achieved by applying a mechanical impulse, advantageously by mixing, milling, more advantageously by autogenous milling, or by using eddy currents and/or ultrasound, or by milling, hammering, breaking or by electrical discharges or shock waves.

15. The method according to claim 10, in which particles with particle sizes greater than or equal to 2 mm to 20 mm, or 5 mm to 63 mm, are achieved.

16. The method according to claim 10, in which a temperature treatment is carried out at temperatures between 2000 C. and 2600 C.

17. The method according to claim 10, in which a temperature treatment is carried out under an argon or nitrogen atmosphere.

18. The method according to claim 10, in which a temperature treatment is carried out at temperatures of at least 2000 C. between 10 and 300 min.

19. The method according to claim 10, in which the physical separation of the particles after the temperature treatment is carried out according to the particle size, the particle shape, the density and/or the physical and/or chemical surface properties of the particles.

20. The method according to claim 10, in which the separation is carried out according to the particle size and/or particle shape by sieving, sifting and/or cyclone method, or the separation is carried out by the effect of mass forces with regard to particle density by flotation, sedimentation, sifting, centrifugation and/or cyclone method, or the separation is carried out according to the density of the particles by flotation and/or cyclone method.

21. A process using the silicon carbide gravel according to claim 1 for the production of SiC-containing ceramics, in particular refractory ceramics.

Description

EXAMPLE 1

[0113] 100 kg of SSiC sintering scrap in lump form with an SiC content of 99.5% by mass is crushed using roller mills with metallic rollers with an energy input of 0.5 MJ/kg within 20 min. The resulting sharp-edged broken SSiC particles are sieved and a fraction having a particle size of >10 mm is separated with a yield of >80%, which is the silicon carbide gravel according to the invention.

[0114] The individual particles in this fraction have SiC contents of 99.5% by mass and have a density of 3.10 g/cm3, a compressive strength of 3200 MPa, a fraction of <0.1% of pores with an equivalent diameter of >100 m and a fraction of open porosity of 0.1%.

[0115] The irregularly shaped particles have an average roundness of 0.6.

EXAMPLE 2

[0116] 200 kg of NSiC from refractory applications in lump form with a composition of SiC of 90% by mass, SiO.sub.2 of 9.6% by mass and free fractions of C of 0.15% by mass, and Si of 0.14% by mass, and Fe of 0.128% by mass, is crushed using a jaw crusher with an energy input of 2 MJ/kg within 10 min. 79 g C per kg NSiC is added during the mechanical loading in the jaw crusher, such that a stoichiometric composition of the SiC waste product is achieved.

[0117] The mixed material is then treated at 2200 C. for a period of 300 min under vacuum.

[0118] Due to the partial sintering, the SiC particles are separated by pneumatic energy input of 1 MJ/kg in an autogenous mill and then fractionated by means of sifting. Irregularly shaped particles with sharp edges and partially rounded edges with a particle size of 2-5 mm are obtained with a yield of 90%.

[0119] The SiC particles that result from the process have an SiC content of >98% by mass and a density of 3.02 g/cm.sup.3, a compressive strength of 2850 MPa, a fraction of 2.3% pores with an equivalent diameter of >100 m, and a fraction of open porosity of 3%. The irregularly shaped particles have an average roundness of 0.7.

EXAMPLE 3

[0120] 100 kg of jagged-coarse Si-SiC sintering scrap with a composition of 80% by mass SiC, 14% by mass Si, a free C fraction of 0.13% by mass, an SiO2 fraction of 3.97% by mass, and a Fe fraction of 0.968% by mass, and 33 kg of pyrolyzed mineral concrete waste with 65% by mass SiC and 30% by mass C and 5% by mass ash are crushed using a hammer mill with an energy input of 5 MJ/kg. The material then has an additional Fe concentration of 2 ma.-%.

[0121] The ground material is then treated at 2250 C. for a period of 40 min under argon atmosphere.

[0122] The particles are separated by pneumatic energy input of 2 MJ/kg in autogenous mills. During the subsequent wind screening, impurities accumulate in a fine fraction <500 m. This fine fraction then has Fe and Si impurities [sic: >] 5% by mass.

[0123] The coarse fraction with particle sizes of 4 mm with a yield >95% has an SiC content of 98% by mass.

[0124] The irregularly shaped particles produced in doing so have sharp-edged and partially rounded edges, and a roundness of 0.75.

[0125] The partially sintered particles that result from the process have an SiC content of 98% by mass and a density of 2.95 g/cm.sup.3, a compressive strength of 2600 MPa, a fraction of 4% pores with an equivalent diameter of >100 m, and a fraction of open porosity of 3%.