Composite tungsten carbide insert with heterogeneous composition and structure and manufacturing method thereof

Abstract

A composite tungsten carbide insert (B, I) with heterogeneous composition and structure has a working part (W) and a non-working part (N). The working part (W) is made of a tungsten carbide material consisting of tungsten carbide powder and cobalt powder or nickel. The non-working part (N) is made of a low density tungsten carbide material consisting of titanium carbide powder, tungsten carbide powder, and cobalt powder or nickel powder. During pressing, the tungsten carbide material for the working part (W) and the low density tungsten carbide material for the non-working part (N) are weighed and added to a steel die successively for molding and then sintering. The non-working part (N) which accounts for most of the overall product volume has low density and less material consumption, and can greatly reduce the raw material costs of the product, significantly improving the performance-cost ratio of the insert (B, I).

Claims

1. A composite tungsten carbide insert with heterogeneous composition and structure, comprising: the insert being a button or cylindrical insert for cutter compact products having a working part and a non-working part; the working part is made of a tungsten carbide material consisting of tungsten carbide powder (80-92%) uniformly mixed with cobalt powder or nickel powder (8-20%) by weight, with a layer thickness of 5-30 mm; the non-working part is made of a uniform mixture of a low density tungsten carbide material consisting of 30-60% of titanium carbide powder (with a density of 4.93 g/cm.sup.3), 20-60% of tungsten carbide powder (with a density of 15.79 g/cm.sup.3), and 10-20% of cobalt powder or nickel powder (with a density of 8.9 g/cm.sup.3) by weight; and wherein during pressing, the tungsten carbide material for the working part is weighed and added to a steel die, then the low density tungsten carbide material for the non-working part is weighed and added to the die, a pressure is exerted on the two materials for molding, then the molded product is placed in a sintering furnace for sintering, and the resulting sintered product forms the composite tungsten carbide insert.

2. The composite tungsten carbide insert with heterogeneous composition according to claim 1, wherein the insert is formed such that the working part is semi-spherical in shape.

3. The composite tungsten carbide insert with heterogeneous composition according to claim 1, wherein the insert is formed such that the working part is cylindrical in shape, having an end face.

4. A method for manufacturing a composite tungsten carbide insert with heterogeneous composition and structure, wherein the composite tungsten carbide insert is a button or cylindrical insert for cutter compact products having a working part and a non-working part, the method comprising the following steps: A. preparing a first mixture of tungsten carbide material for the working part by: (a) uniformly mixing 80-92% of tungsten carbide powder and 8-20% of cobalt powder or nickel powder by weight; (b) placing the first mixture in a ball mill for wet milling at room temperature for 24 hours at a ball-to-material ratio of 4:1 and solid-to-liquid ratio of 1 kg/300 ml; (c) recovering alcohol from the milled wet material of the first mixture using a vacuum dryer, and drying in a steam drying oven; and (d) adding a rubber molding agent to a resulting dried powder from the first mixture at the rubber addition rate of 90 ml/kg, uniformly stirring for 2 minutes, and then sieving through 60-100 meshes; B. preparing a second mixture of a low density tungsten carbide material for the non-working part by: (a) uniformly mixing 30-60% of titanium carbide powder (with a density of 4.93 g/cm.sup.3), 20-60% of tungsten carbide powder (with a density of 15.79 g/cm.sup.3), and 10-20% of cobalt powder or nickel powder (with a density of 8.9 g/cm.sup.3) by weight; (b) placing the second mixture in a ball mill; (c) wet milling the second mixture in the ball mill at room temperature for 24 hours at a ball-to-material ratio of 4:1 and solid-to-liquid ratio of 1 kg/300 ml; (d) recovering alcohol from milled wet material of the second mixture placed in the ball mill using a vacuum dryer, and drying in a steam drying oven; and (e) adding a rubber molding agent to a resulting dried powder from the second mixture at the rubber addition rate of 120 ml/kg, uniformly stirring for 2 minutes, and then sieving through 60-100 meshes; C. pressing for molding: (a) prefabricating a convex pressed compact, a crosshead end being used as the working part, with shrinkage coefficient of 1.20-1.25, and a butt end being used as the non-working part, with shrinkage coefficient of 1.26-1.30, and a joint interface between the working part and the non-working part to be in smooth transition; and (b) weighing and adding the first mixture of the tungsten carbide material for the working part to a steel die, then weighing and adding the second mixture of the low density tungsten carbide material for the non-working part to the steel die, with the second mixture uniformly mixed, and exerting 60-100 Mpa/cm.sup.3 pressure for molding; D. sintering by placing the molded product in a sintering furnace for sintering at temperature of 1420-1460 C., and holding for 2-3 hours; and E. machining product surface by grinding the surface of the sintered product to size, and warehousing after satisfactory inspection.

5. The method for manufacturing a composite tungsten carbide insert with heterogeneous composition and structure according to claim 4, wherein the insert is formed such that the working part is semi-spherical in shape.

6. The method for manufacturing a composite tungsten carbide insert with heterogeneous composition and structure according to claim 4, wherein the insert is formed such that the working part is cylindrical in shape, having an end face.

Description

DESCRIPTION OF THE DRAWINGS

(1) For a more complete understanding of the present invention and the advantages thereof, reference is now made to the following description taken in conjunction with the accompanying Drawings in which FIGS. 1 through 6 show various aspects for a method for manufacturing composite tungsten carbide insert with heterogeneous composition and structure devices made according to the present invention, as set forth below:

(2) FIG. 1 is a schematic diagram of the shape of a pressed compact of a composite tungsten carbide spherical button insert with heterogeneous composition and structure;

(3) FIG. 2 is a schematic diagram of the shape of a pressed compact of the composite tungsten carbide cylindrical insert with heterogeneous composition and structure;

(4) FIG. 3 is a schematic diagram of a sintered blank of the composite tungsten carbide spherical button insert with heterogeneous composition and structure;

(5) FIG. 4 is a schematic diagram of a sintered blank of the composite tungsten carbide cylindrical insert with heterogeneous composition and structure;

(6) FIG. 5 is a diagram of a blank sample of the composite tungsten carbide spherical button insert with heterogeneous composition and structure; and

(7) FIG. 6 is a diagram of a ground sample of the composite tungsten carbide cylindrical insert with heterogeneous composition and structure.

DETAILED DESCRIPTION OF THE INVENTION

(8) Referring to the Figures, all dimensions shown are in mm FIG. 1 is a schematic diagram of the shape of a pressed compact of a composite tungsten carbide spherical button insert B with heterogeneous composition and structure. The cylindrical button insert B has a working part W, a smooth transition part T, and a non-working part N. The button insert B has a height h and a diameter d. The non-working part N has a button height H and a button diameter D. The spherically shaped profile of the working part W of the button insert B is typically used in mining tools for crushing rock.

(9) FIG. 2 is a schematic diagram of the shape of a pressed compact of the composite tungsten carbide cylindrical insert I with heterogeneous composition and structure. The insert I has a non-working part N, a working part W and a convex transition part T. The non-working part N has a diameter D, and a height H. The working part W has an insert height h and a diameter d. The end face of the working part W of the cylindrical insert I is typically used in mining tools for shearing rock.

(10) FIG. 3 is a schematic diagram of a sintered blank of the composite tungsten carbide spherical button insert B with heterogeneous composition and structure. The button insert B has a working part W, a convex transition part T, and a non-working part N. The button insert B has a height h equal to 10 mm and a diameter d equal to 13.6 mm. The non-working part N has a button height H equal to 10 mm and a button diameter D equal to 13.6 mm.

(11) FIG. 4 is a schematic diagram of a sintered blank of the composite tungsten carbide cylindrical insert I with heterogeneous composition and structure. The cylindrical insert I has a non-working part N, a working part W and a smooth transition part T. The non-working part N has a diameter D equal to 16.5 mm and a height H equal to 25 mm. The working part W has an insert height h equal to 15 mm and a diameter d equal to 16.5 mm.

(12) FIG. 5 is a diagram of a blank sample of the composite tungsten carbide spherical button insert B with heterogeneous composition and structure. The button insert B has a working part W, a compound interface C and a non-working part N. The spherically shaped profile of the working part W of the button insert B is typically used in mining tools for crushing rock

(13) FIG. 6 is a diagram of a ground sample of the composite tungsten carbide cylindrical insert I with heterogeneous composition and structure. The cylindrical insert I has a working part W, a compound interface C and a non-working part N. The end face of the working part W of the cylindrical insert I is typically used in mining tools for shearing rock.

(14) A method for manufacturing the composite tungsten carbide spherical button insert B or cylindrical insert I with heterogeneous composition and structure, comprising the following steps: A. Preparing the Tungsten Carbide Material Mixture for the Working Part W: a) uniformly mixing 80-92% of tungsten carbide powder and 8-20% of cobalt powder or nickel powder by weight; b) placing the mixture in a ball mill for wet milling at room temperature for 24 hours at a ball-to material ratio of 4:1 and solid-to-liquid ratio of 1 kg/300 ml; c) recovering alcohol from the milled wet material using a vacuum dryer, and drying in a steam drying oven; and d) adding a rubber molding agent to the resulting dried powder at the rubber addition rate of 90 ml/kg, uniformly stirring for 2 minutes, and then sieving through 60-100 meshes. B. Preparing the Low Density Tungsten Carbide Material Mixture for the Non-working Part N: a) uniformly mixing 30-60% of titanium carbide powder (with a density of 4.93 g/cm.sup.3), 20-60% of tungsten carbide powder (with a density of 15.79 g/cm.sup.3), and 10-20% of cobalt powder or nickel powder (with a density of 8.9 g/cm.sup.3) by weight; b) placing the mixture in a ball mill for wet milling at room temperature for 24 hours at a ball-to material ratio of 4:1 and solid-to-liquid ratio of 1 kg/300 ml; c) recovering alcohol from the milled wet material using a vacuum dryer, and drying in a steam drying oven; and d) adding a rubber molding agent to the resulting dried powder at the rubber addition rate of 120 ml/kg, uniformly stirring for 2 minutes, and then sieving through 60-100 meshes. C. Pressing for Molding: a) due to some differences in shrinkage of the two mixtures, in order to prevent distortion of the button B or the insert I after sintering affecting dimensional tolerance, and failing to meet the use requirements, prefabricating a convex pressed compact, the crosshead end being used as the working part W, with shrinkage coefficient of 1.20-1.25, and the butt end being used as the non-working part N, with shrinkage coefficient of 1.26-1.30, and allowing the joint interface between the working part W and the non-working part N to be in smooth transition; and b) weighing and adding the mixture of the tungsten carbide powder and cobalt powder (or nickel powder) for the working part W to a steel die, then weighing and adding the mixture of the titanium carbide powder, tungsten carbide powder and cobalt powder or nickel powder for the non-working part N to the steel die, and exerting 60-100 Mpa/cm.sup.3 pressure for molding; D. Sintering: a) placing the molded product in a sintering furnace for sintering at temperature of 1420-1460 C., and holding for 2-3 hours. E. Machining Product Surface: grinding the surface of the sintered product to size, and warehousing after satisfactory inspection.

(15) The rubber molding agent from steps A(d) and B(d) above may be provided by SD Liquid Cement, which is a rubber molding agent commercially available from Zhuzhou Cemented Carbide Group Co., Ltd. of China. A gasoline rubber molding agent may also be used. The rubber molding agent holds the holds the material in place during sintering, and burns off during sintering since it is formed of rubber.

(16) The sieve sizes noted correlate to 60 mesh having opening sizes of 250 (m) and 100 mesh having opening sizes of 150 (m).

(17) The tungsten carbide for the non-working part N refers to electrolytic tungsten carbide from recovered tungsten carbide scraps or crushed powder from recovered tungsten carbide, and the tungsten carbide costs less than primary tungsten carbide.

(18) In a formulation of the composite tungsten carbide spherical button insert B and the cylindrical insert I with heterogeneous composition and structure of the invention, the working part W is made of a conventional tungsten carbide, cobalt or nickel tungsten carbide material, and the non-working part N is made of a low-cost and low-density tungsten carbide material. The tungsten carbide spherical button insert B and the cylindrical insert I product manufactured using the preparation process has the following advantages: compared with the tungsten carbide spherical button insert B or the cylindrical insert I with heterogeneous composition and structure in the patent application (patent No.: CN201210181531) entitled Nano-sized Rare Earth Surface Enhanced Gradient Tungsten Carbide Composite Spherical Button for Mining and Preparation Method Thereof and that in patent document (patent No.: CN102699330A) entitled Method for Preparing Tungsten Carbide Roll Surface Insert, the composite tungsten carbide spherical button insert B or the cylindrical insert I with heterogeneous composition and structure of the invention has the non-working part N accounted for most of the overall product volume, has low density, less material consumption of a single product and low raw material costs, and can greatly reduce the raw material costs of the product without changing quality performance and use requirements of the tungsten carbide spherical button insert B or the cylindrical insert I product, thus achieving the purpose of significantly improving the performance-cost ratio of the product.

Example 1. A Composite Tungsten Carbide Spherical Button Insert with Heterogeneous Composition and Structure

(19) The product is composed of two parts, i.e. a working part W consisting of 90% of tungsten carbide and 10% of cobalt by weight, and a non-working part N consisting of 50% of titanium carbide, 30% of tungsten carbide and 20% of cobalt and nickel by weight. Refer to FIG. 1, FIG. 3 and FIG. 5 for the shapes of the pressed compact, the sintered blank and the physical blank required. The process steps are briefly stated as follows: weighing and uniformly mixing the components by weight percentage; placing the mixtures for the working part W and the non-working N part into different ball mills for wet milling at room temperature for 24 hour at a ball-to-material ratio of 4:1 and solid-to-liquid ratio of 1 kg/300 ml; recovering alcohol from the milled wet powder for the working part W and the non-working part N using vacuum dryers (Z mixer) respectively, and drying in steam drying ovens; adding an SD liquid cement or gasoline rubber molding agent to the resulting dried powder at the rubber addition rate of 90 ml/kg for the working part W and the rubber addition rate of 120 ml/kg or the non-working part N, uniformly stirring for 2 minutes, and then sieving through 60-100 meshes; weighing 7.5 g powder for the working part W and adding the powder to a steel die, then weighing 11.5 g powder for the non-working N part and adding the powder to the steel die, and exerting 60-100 Mpa/cm.sup.3 pressure for molding (refer to FIG. 1 for the shape of the pressed compact); placing the pressed and molded product in a sintering furnace for sintering at temperature of 1420-1460 C., and holding for 2-3 hours (refer to FIG. 3 and FIG. 5 for the shape and dimension of the resulting sintered product); and machining the surface of the sintered product by coreless grinding to allow the product dimension to meet requirements, and warehousing after satisfactory inspection. The product is determined by sampling to obtain the following results: integrated density: 9.20 g/cm.sup.3, hardness of the working part W: 88.5 HRA, porosity of the working part: A02, BO3O and COO.

Example 2. A Composite Tungsten Carbide Cylindrical Insert I with Heterogeneous Composition and Structure

(20) The product is composed of two parts, i.e. a working part W consisting of 85% of tungsten carbide and 15% of cobalt by weight, and a non-working part N consisting of 30% of titanium carbide, 55% of tungsten carbide and 15% of cobalt and nickel by weight. Refer to FIG. 2, FIG. 4 and FIG. 6 for the shapes of the pressed compact, the sintered blank and the physical blank required. The process steps are briefly stated as follows: weighing and uniformly mixing the components by weight percentage; charging the mixtures for the working part W and the non-working part N into different ball mills for wet milling at room temperature for 24 hours at a ball-to-material ratio of 4:1 and solid-to-liquid ratio of 1 kg/300 ml; recovering alcohol from the milled wet powder for the working part W and the non-working part N using vacuum dryers (Z mixer) respectively, and drying in steam drying ovens; adding a rubber molding agent to the resulting dried powder at the rubber addition rate of 90 ml/kg for the working part W and the rubber addition rate of 120 ml/kg for the non-working part N, uniformly stirring for 2 minutes, and then sieving through 60-100 meshes; weighing 44.5 g powder for the working part W and adding the powder to a steel die, then weighing 49 g powder for the non-working N part and adding the powder to the steel die, and exerting 60-100 Mpa/cm.sup.3 pressure for molding (refer to FIG. 2 for the shape of the pressed compact); placing the pressed and molded product in a sintering furnace for sintering at temperature of 1420-1460 C., and holding for 2-3 hours (refer to FIG. 4 for the shape and dimension of the resulting sintered product); and machining the surface of the sintered product by coreless grinding to allow the product dimension to meet requirements, and warehousing after satisfactory inspection (refer to FIG. 6 for the machined physical sample). The product is determined by sampling to obtain the following results: integrated density: 10.5 g/cm.sup.3, hardness of the working part: 86.5 HRA, porosity of the working part: A02, B02 and COO.

(21) The present invention provides advantages over conventional tungsten carbide compact inserts with composite tungsten carbide spherical button inserts and cylindrical inserts having heterogeneous composition and structure. The non-working part of the spherical button inserts and the cylindrical inserts account for most of the overall product volume, and according to the present invention is provided with low density and less material consumption to greatly reduce the raw material costs of the products, thus achieving the purpose of significantly improving the performance to cost ratio of the product.

(22) Although the preferred embodiment has been described in detail, it should be understood that various changes, substitutions and alterations can be made therein without departing from the spirit and scope of the invention as defined by the appended claims.