US2019368011A1PendingUtilityA1
Cemented carbide material and method of making same
Est. expiryFeb 11, 2033(~6.6 yrs left)· nominal 20-yr term from priority
C22C 2026/006C22C 29/067C22C 29/08C22C 26/00B22F 2005/001C22B 7/001B22F 3/15C22C 1/051
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Claims
Abstract
A cemented carbide material comprises WC, between around 3 to around 10 wt. % Co and between around 0.5 to around 8 wt. % Re. The equivalent total carbon (ETC) content of the cemented carbide material with respect to WC is between around 6.3 wt. % to around 6.9 wt. % and the cemented carbide material is substantially free of eta-phase and free carbon. There is also disclosed a method of producing such a material and use of such a material.
Claims
exact text as granted — not AI-modified1 . A cemented tungsten carbide (WC) material further comprising:
between around 3 to around 10 wt. % Co; and between around 0.5 to around 8 wt. % Re; the equivalent total carbon (ETC) content of the cemented tungsten carbide material with respect to WC being between around 6.3 wt. % to around 6.9 wt. %; the cemented tungsten carbide material being substantially free of eta-phase and free carbon.
2 . The cemented tungsten carbide material of claim 1 , wherein the cemented tungsten carbide material comprises between around 0.5 to around 6 wt % Re.
3 . The cemented tungsten carbide material of claim 1 , wherein the WC in the material has a mean grain size less than around 0.6 μm.
4 . The cemented tungsten carbide material of claim 1 , wherein the cemented tungsten carbide material has a magnetic saturation of at least around 40 percent to around 80 percent of the magnetic saturation of nominally pure Co.
5 . The cemented tungsten carbide material of claim 1 , wherein the carbide phase is formed of carbide grains having a mean grain size of at least around 0.1 μm to at most around 10 μm.
6 . The cemented tungsten carbide material of claim 1 , wherein the cemented tungsten carbide material has an associated magnetic coercive force varying from around 2 kA/m to around 70 kA/m.
7 . The cemented tungsten carbide material of claim 1 , further comprising a carbide of one or more metals in form of the second carbide phase, or dissolved in a binder phase in the material, said one or more metals comprising Ti, V, Cr, Mn, Zr, Nb, Mo, Hf and/or Ta.
8 . The cemented tungsten carbide material of claim 1 , wherein the material comprises a binder phase having one or more residual compressive stresses.
9 - 10 . (canceled)
11 . The cemented tungsten carbide material of claim 8 , wherein the binder phase comprises a binder material, the binder material comprising or a solid solution of Re, carbon and W and one of more of Fe, Co, and Ni.
12 . The cemented tungsten carbide material as claimed in claim 1 , wherein the cemented tungsten carbide material has a coercive force Hc in kA/m as a function of the WC mean grain size D wc in μm determined on the basis of EBSD images of the carbide microstructure equal to or less than values given by the equation:
Hc= 10× D wc −0.62
13 - 15 . (canceled)
16 . The cemented tungsten carbide material as claimed in claim 1 , wherein the Young's Modulus of said material is above around 700 GPa.
17 . The cemented tungsten carbide material as claimed in claim 1 , wherein the hardness-toughness coefficient calculated by multiplying the Vickers hardness in GPa and fracture toughness in MPa m 1/2 is above around 190.
18 . (canceled)
19 . The cemented tungsten carbide material as claimed in claim 1 , wherein the material comprises at least about 0.01 weight percent and at most about 2 weight percent of one or more of Ru, Rh, Pd, Os, Ir and Pt
20 . A polycrystalline superhard construction comprising:
a substrate comprising the cemented tungsten carbide material of claim 1 ; and a body of polycrystalline superhard material bonded to the substrate along an interface.
21 . The polycrystalline superhard construction of claim 20 , wherein the body of polycrystalline superhard material comprises polycrystalline diamond (PCD) material or PCBN.
22 - 25 . (canceled)
26 . A method of producing the cemented tungsten carbide material of claim 1 , the method comprising:
milling a cemented tungsten carbide mixture containing WC and carbon with Re, Co, Ni and/or Fe and optionally grain growth inhibitors comprising one or more of V, Cr, Ta, Ti, Mo, Zr, Nb and Hf or a carbide thereof; pressing the cemented carbide article from the mixture; sintering the article at a temperature of above around 1450° C. in vacuum for between around 1 to 10 minutes and a pressure of Ar (HIP) for around 5 to 120 minutes; and cooling the article from sintering the temperature to approximately 1300 degrees Centigrade (° C.); wherein the step of cooling the article comprises: cooling the article in an atmosphere comprising one or more of an inert gas, nitrogen, hydrogen or a mixture thereof, at a cooling rate of approximately 0.2 to 2 degrees per minute; or cooling the article in a vacuum at a cooling rate of approximately 0.2 to 2 degrees per minute.
27 - 29 . (canceled)
30 . A method of recycling the cemented tungsten carbide material of claim 1 , the method comprising melting the carbide tungsten material in a protective atmosphere with liquid Zn, evaporating the Zn to form a resultant product; and milling the resulting product to recover Re from the product.
31 . A method of recycling the cemented tungsten carbide material of claim 1 , the method comprising subjecting the cemented tungsten carbide material to an acid leaching mixture to remove the binder phase from the cemented tungsten carbide material; and chemically recovering Co and Re from the removed binder phase.
32 . A method of recycling the cemented tungsten carbide material of claim 1 , the method comprising oxidation of the cemented tungsten carbide material to dissolve the carbide, Re and Co, and recovering the Re.
33 - 51 . (canceled)Cited by (0)
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