RU2484888C1 - Method of making polycrystalline material based on cubic boron nitride containing diamonds - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to production of synthetic polycrystalline materials based on polycrystalline cubic boron containing diamond grains. Said materials are used for making cutting elements to be incorporated with drill bits, grinding wheel dressing, drilling and cutting of natural and artificial construction materials. Proposed method comprises subjecting the blend containing cubic boron nitride and diamond powder to pressure in the range of thermal stability of aforesaid components at state graphs. Note here that grain sixe of diamond powder used in amount of 5.0-37.5 vol. % makes 200-3000 mcm while that of hexagonal boron nitride makes 1-3 mcm and that of cubic boron nitride makes 1-5 mcm.

EFFECT: higher efficiency in drilling rocks of V-XII rock drillability index.

3 cl

Description

The invention is directed to the production of synthetic polycrystalline materials, the basis of which is polycrystalline cubic boron nitride containing diamond grains. The material is intended for the manufacture of cutting elements, which are equipped with drill bits.

Known methods for producing sintered materials, including cubic boron nitride and diamond. EP patent No. 0181258 proposes a sintered diamond compact for a drilling tool obtained by sintering cubic boron nitride with a silicon-based binder. A carbon source is additionally introduced into the mass, and diamond is preferably used as this to obtain silicon carbide binder in the finished material. In RU No. 487845, material for a drilling tool is obtained by sintering diamond, cubic boron nitride and complex compounds based on alkaline earth metal oxides. In US patent No. 3767371 material for cutting, drilling is obtained by sintering cubic boron nitride, diamond and metal carbides. In all of the above solutions for sintering, proportionate micro and grinding powders of cubic boron nitride and diamond with grain sizes up to 160 microns are used. Sintering is carried out under conditions of high pressures and temperatures. The disadvantage of the method for producing sintered material is that during sintering a composite material with a significant binder content is formed, which impairs its wear resistance as a whole.

Known methods for producing polycrystalline materials based on cubic boron nitride with the inclusion of diamond powders. In US patents Nos. 3852078 and 3894850, polycrystalline material is made from a mixture of hexagonal boron nitride and diamond powders, while diamond powders are taken in sizes of less than 10 microns, cubic boron nitride powders are taken in sizes up to 3 microns. As a result of the synthesis, fine-grained material is obtained, which is used in cutting tools, drills, abrasive tools and in the form of wear-resistant parts of machines. The use of this material in a drilling tool is not foreseen since drill bits equipped with such a material will have insufficient abrasive ability.

The closest technical solution is the method described in patent EP No. 0482372, class B01J 3/06, 1992. In accordance with this invention, powders of diamond and cubic boron nitride or a mixture of powders of cubic and hexagonal boron nitride are taken to obtain a polycrystalline material, the mixture is subjected pressure and heating with parameters lying in the stability region of cubic boron nitride. A dense heat-resistant and wear-resistant polycrystalline material with a crystal-crystal bond without an additional binder is obtained. To obtain the material, the initial diamond powders are taken with a grain size of preferably 4-75 microns, cubic boron nitride powders - 0.1-10 microns. The proportion of diamonds is 50-95 wt.%. In a polycrystal, diamond powders are almost commensurate with cubic boron nitride powders. The high content of diamond powders and the proportionality of all powders contribute to the production of a material with a uniform dense fine-grained structure, which is based on sufficiently densely laid diamond powders. Such a material has increased wear resistance, a sharp cutting edge can be obtained on cutting elements from this material and it can be successfully used as cutting inserts in blade tools - cutters, drills, straightening tool, etc. In rock cutting tools for drilling rocks of V-XII drillability category with coring, the efficiency of such a material, namely its performance is low, because the large contact area of the working surface with the bottom leads to significant axial forces with a small introduction of diamond grains in the rock.

The technical task is to increase the working capacity of the material when drilling rocks of V-XII drillability categories, which allows drilling operations with higher drilling modes and thereby increase productivity.

The technical result is achieved by the fact that in the method for producing a polycrystalline material based on cubic boron nitride containing diamonds, by acting on a charge including hexagonal and cubic boron nitride and diamond powders, by pressure at a temperature in the region of thermodynamic stability of cubic boron nitride and diamond state diagrams, diamond powders are taken with a grain size of 200-3000 microns in an amount of 5.0-37.5 vol.%.

Hexagonal boron nitride is taken in the size of 1-3 microns

Cubic boron nitride is taken in the size of 1-5 microns.

The essence of the invention lies in the fact that for the manufacture of a polycrystalline material take diamond powders with a coarse grain of 200-3000 μm, which are firmly held by a fine-grained polycrystalline cubic boron, obtained as a result of synthesis and acting as a binder. Large diamonds contained in the polycrystal in an amount of 5.0-27.5 vol.%, Play the role of many additional cutting diamond edges, providing the effect of chipping of the rock and thereby contributing to its effective destruction. Higher performance of the material makes it possible to increase drilling modes and thus increase the productivity and resource of work of the material (tool) as a whole.

The method is as follows.

A mixture containing hexagonal and cubic boron nitride and diamond powders is placed in the reaction cell of the high-pressure chamber. The equipped cell is placed in a high-pressure chamber and compressed to a pressure of 60-80 kbar with simultaneous heating to values corresponding to the thermodynamic stability region of cubic boron nitride and diamond state diagrams. After holding for a predetermined time, the electric current is turned off, the pressure is reduced to normal, and the finished product is removed from the chamber. From the finished product by machining form the cutting element of the required shape, which is mounted on the body of the drill bit. The fastening can be made by any known method, mainly by soldering, by the method of powder metallurgy, etc.

The synthesized material is a polycrystal in which large diamond grains are firmly held by a binder of cubic boron nitride, which has a thin dense structure with intercrystalline bonding of cubic nitride grains to each other.

Hexagonal boron nitride powders under the synthesis conditions in the field of thermodynamic stability of cubic boron nitride and diamond state diagrams are converted to cubic boron nitride. Powders of cubic boron nitride introduced into the charge contribute to a more complete conversion of hexagonal boron nitride into a cubic form. Typically, it is recommended to introduce 10-15 vol.% Cubic boron nitride into the charge.

The granularity of powders of hexagonal boron nitride of 1-3 microns and cubic boron nitride of 1-5 microns provides a material with a thin dense structure that firmly holds large diamond grains. Powders of hexagonal and cubic nitride of finer grain size are not rational to use, in addition, the complexity of manufacturing the tool increases significantly; when using powders of higher granularity, the retention of diamond grains, especially large diamond grains, in the finished material will not be strong enough due to the increased porosity of the material.

A polycrystalline material with diamond grains 200-3000 microns in size, firmly held by a bundle of fine-grained cubic boron nitride, works as a "multi-cut" abrasive tool. This allows you to increase the operating modes of the tool and accordingly increase the productivity of drilling, because tool productivity increases in proportion to the grain of the diamond. When using diamond grains of finer grain size, a significant increase in cutting conditions is problematic. Introduction to the charge of larger diamond grains is not economically feasible, because diamond grains larger than 3000 microns are practically not synthesized, and the use of natural diamond grains of such sizes will sharply increase the cost of the tool, not comparable with an increase in cutting performance. The amount of diamond powder is 5.0-37.5 vol.%. A diamond powder content of less than 5.0 vol.% Will not allow to increase drilling modes due to the small number of cutting edges on the surface of the material. When the content of diamond powder is more than 37.5 vol.%, The amount of a binder, polycrystalline cubic boron nitride, is significantly reduced, which will lead to the possibility of contact of diamond grains with each other, and, accordingly, to a decrease in the reliability of holding diamond grains in a binder. In addition, a matrix of cubic boron nitride, which constitutes the bulk of the material in a sufficient volume, having higher heat resistance, will reliably protect diamond grains from oxidation by atmospheric oxygen.

As powders of cubic boron nitride, synthesized powders can be used, as well as powders of crushed polycrystalline superhard materials based on cubic boron nitride.

As diamond powders, in addition to natural and synthetic diamonds, powders of crushed composite or polycrystalline diamond materials (ballas, carbonado, etc.) can be used.

The mixture may further comprise a solvent catalyst, for example magnesium diboride, aluminum nitride, and other known catalysts used in the synthesis of cubic boron nitride. The introduction of solvent catalysts will reduce the synthesis of cubic boron nitride. In addition, various additional materials can be introduced into the charge, for example, metals or borides, carbides, metal nitride oxides, etc. These inclusions can change the characteristics of the material obtained in accordance with specific requirements.

The pressure and heating of the charge are selected from the conditions of the synthesis process in the field of thermodynamic stability of cubic boron nitride and diamond state diagrams. The pressure is in the range of 50-80 kbar, the temperature is above 1100 ° C. Under such conditions, hexagonal boron nitride is rearranged into a cubic lattice and remains stable until the end of the synthesis process. Diamonds in these conditions retain their state.

When studying the obtained samples with an optical microscope, a dense fine-grained structure of cubic boron nitride was visible with large diamond grains spaced over the surface of the sample at a sufficient distance from each other, which, when the drill bit is used, act as free-standing cutting edges that ensure high performance of the polycrystal.

Thus, the introduction of large crystals of diamond into a material based on polycrystalline cubic boron nitride can significantly increase the operability of a drilling tool equipped with cutting elements from such material, and drilling regimes of rocks V-XII of drillability categories. An increase in drilling conditions provides an increase in drilling productivity.

The use of polycrystalline material from cubic boron nitride containing large diamond grains is not limited to drill bits. Such material can also be used in other tools, such as, for example, tools for dressing grinding wheels, for drilling and cutting natural and artificial building materials, etc.

Claims (3)

1. A method of producing a polycrystalline material based on cubic boron nitride containing diamonds by acting on a charge including hexagonal and cubic boron nitride and diamond powders, by pressure at a temperature in the region of thermodynamic stability of cubic boron nitride and diamond state diagrams, characterized in that the diamond powders take with a grain size of 200-3000 microns in an amount of 5.0-37.5 vol.%. 2. The method according to claim 1, characterized in that the hexagonal boron nitride is taken in the size of 1-3 microns. 3. The method according to claim 1, characterized in that the cubic boron nitride is taken in the size of 1-5 microns.