RU2756407C1 - Method for producing tungsten-free hard alloy knt from powder materials obtained in alcohol - Google Patents

Abstract

FIELD: powder metallurgy.

SUBSTANCE: invention relates to powder metallurgy, in particular to a method for producing tungsten-free hard alloys. It can be used for the manufacture of metalworking tools. The powder material is obtained by electroerosive dispersion of waste of tungsten-free hard alloys of KNT 16 in alcohol. Hot pressing is carried out in a vacuum with a high-ampere current passing through the mold and the pressed powder material at a temperature of 1200°C for 5 minutes.

EFFECT: invention provides increased operational properties.

1 cl, 5 dwg, 3 ex

Description

The invention relates to methods for producing sintered products from tungsten-free hard alloys, in which powders of a binder phase with spherical non-agglomerated particles are used, and can be used in the manufacture of products for general metalworking purposes.

A known method of producing a hard alloy. Powdered carbonitride or oxycarbonitride or doped oxycarbonitride are mixed with powders of metallic nickel and molybdenum at a certain ratio, taken in the amount necessary to obtain the proposed ratio of the alloy. The resulting mixture is subjected to grinding in ethanol in a mill lined with hard alloy for 60 - 84 hours to a dispersion of 2 - 3 microns. Then the mixture is dried, kneaded with a plasticizer (5% solution of synthetic rubber in gasoline), dried again, granulated and pressed into products of the required shape. After that, it is sintered in a vacuum furnace at a pressure of (2 - 5) · 10 ^-1 and a temperature of 1500 - 1600 ^o C for 0.5 - 1 hour at a heating and cooling rate of 16 - 18 ^o / min. (patent of the Russian Federation No. RU 2133296 C1, 1998).

There is also known a method of manufacturing a hard alloy based on titanium carbonitride. Powder of titanium carbonitride is mixed with powdered metal titanium, nitride, carbide or carbonitride of IVA-VIA metal groups and titanium nickelide in the claimed ratios, the resulting mixture is milled in a liquid medium, for example, in ethanol in a mill lined with hard alloy, for 1 , 5-2 hours. Then the mixture is dried, a plasticizer is added, for example a 5% solution of synthetic rubber in gasoline, and molded into articles of the required shape. Products are sintered in a vacuum of 10 ^-3 -10 ^-4 mm Hg. Art. within 10-20 minutes at a temperature of 1360-1450 ^o C. (patent of the Russian Federation No. RU 2164542 C2, 2001).

The disadvantages of these methods are the multi-operation, resource intensity, relatively high time spent on preparing the components and sintering the product.

The basis of the invention is the task of developing a production technology that provides a high yield of high-quality hard-alloy products that are suitable for practical use, characterized by high operational resistance.

The task is achieved by the fact that in the method of producing tungsten-free hard alloy KNT from powder materials obtained in alcohol, including hot pressing of powder material in a mold, use is made of powder material obtained by electroerosive dispersion of waste of tungsten-free hard alloys KNT16 in alcohol, while hot pressing is carried out in a vacuum with a high-ampere current passing through the mold and the pressed powder material at a temperature of 1200 ° C for 5 minutes.

Tungsten-free hard alloy KNT16 was dispersed in an experimental setup for producing powders from conductive materials. Ethyl alcohol was used as a working fluid.

The process was carried out with the following electrical parameters: capacity of the discharge capacitors 25.5 μF, voltage 195 ... 205 V, pulse repetition rate 95 ... 105 Hz.

As a result of the local impact of short-term electrical discharges between the electrodes, the waste material was destroyed with the formation of dispersed particles of the powder material.

Sintered billets were obtained from powder materials obtained from waste of tungsten-free hard alloys of the KNT16 brand in ethyl alcohol. Carbide blanks were obtained by hot pressing with the passage of a high-ampere current in a vacuum at a temperature of 1200 ° C for 5 minutes, from a powder obtained by electroerosive dispersion of waste of tungsten-free hard alloys KNT16.

The process is based on a modified hot-pressing method, in which an electric current is passed: directly through the mold and the pressed workpiece, and not through an external heater. With the help of a pulsed electric current and the so-called "spark plasma effect", very fast heating and extremely short cycle times are achieved. This makes it possible to suppress grain growth and obtain an equilibrium state, which opens up possibilities for creating new materials with previously inaccessible compositions and properties, materials with submicron or nanoscale grains, as well as composite ones.

Figure 1 shows a diagram of the EED process, figure 2 - the microstructure of the sintered product, figure 3 - the elemental composition of the sintered product, figure 4 - the diffractogram of the sintered sample, figure 5 - the histogram of the pore size distribution.

The powder material was obtained in the following sequence.

At the first stage, the waste was sorted, washed, dried, degreased and weighed. The reactor was filled with a working liquid - ethyl alcohol, the waste was loaded into the reactor. The electrodes were mounted. The mounted electrodes were connected to the generator. The necessary process parameters were set: pulse repetition rate, electrode voltage, capacitance.

At the second stage, the stage of electroerosive dispersion, the installation was turned on. The EED process is presented in figure 1. The pulse voltage of the generator 1 is applied to the electrodes 2 and then to the waste 3 (waste lead bronze also served as electrodes, respectively) in the reactor 4. When a voltage of a certain value is reached, an electrical breakdown of the working medium 5 occurs, located in interelectrode space, with the formation of the discharge channel. Due to the high concentration of thermal energy, the material melts and evaporates at the discharge point, the working medium evaporates and surrounds the discharge channel with gaseous decomposition products (gas bubble 6). As a result of significant dynamic forces developing in the discharge channel and the gas bubble, drops of molten material are thrown out of the discharge zone into the working environment surrounding the electrodes and freeze in it, forming drop-like powder particles 7. Voltage regulator 8 is designed to set the required voltage values, and shaker 9 moves one electrode, which ensures the continuous flow of the EED process.

At the third stage, the working fluid with powder material is unloaded from the reactor.

At the fourth stage, the solution is evaporated, dried, weighed, filled, and packed. Then, the resulting dispersed material was compressed and sintered.

Example 1.

To obtain powder materials from wastes of tungsten-free hard alloy grade KNT16 by the method of electroerosive dispersion in ethyl alcohol, an EED unit was used (Pat. 2449859 Russian Federation, IPC С22F 9/14, С23Н 1/02, B82Y 40/00. materials [Text] / Ageev E.V. and [others]; applicant and patentee of the South-West State University - No. 2010104316/02; application 08.02.2010; publ. 10.05.2012, bull. 13). When receiving the powder, the following setup parameters were used: waste of tungsten-free hard alloy grade KNT16 was dispersed at a voltage across the electrodes of 195-205 V, capacitance of discharge capacitors of 25.5 μF, and a pulse repetition rate of 95-105 Hz. As a result of the local action of short-term electrical discharges between the electrodes, the material was destroyed with the formation of dispersed particles of the powder material.

Tungsten-free hard-alloy billets were obtained by hot pressing with the passage of a high-ampere current in vacuum at a temperature of 1200 ° C for 5 minutes, from a powder material obtained by electroerosive dispersion of waste of tungsten-free hard alloys of the KNT16 brand.

The resulting sintered body was examined by various methods.

By the method of optical microscopy, a study of the microstructure of the samples (on a transverse section) was carried out. The surface of the sample was ground and polished. Grinding was carried out with metallographic paper with coarse (No. 60-70) and fine grain (No. 220-240). During grinding, the sample was periodically turned 90 °. In the process of grinding, the edges of the samples were loose, which led to the chipping off of particles and destruction of the surface of the thin section. The abrasive particles were washed off with water and subjected to polishing on a wheel with suspensions of metal oxides (Fe ₃ O ₄ , Cr ₂ O ₃ , Al ₂ O ₃ ). After reaching a mirror finish, the surface of the section was washed with water, alcohol, and dried with filter paper.

To study the elemental composition and morphology of the resulting sintered product using an EDAX energy-dispersive X-ray analyzer built into a QUANTA 200 3D scanning electron microscope, characteristic X-ray spectra were obtained at various points on the sample surface and along a transverse section. The microstructure of the sintered sample is shown in figure 2. The elemental composition of the sintered sample is shown in figure 3. It has been established that the main elements are Ti (66.1%); Ni (20.02%); C (7.41%); Mo (6.47%).

The phase composition of the sintered sample was studied by X-ray diffraction on a Rigaku Ultima IV diffractometer in Cu-K _α radiation (wavelength λ = 0.154178 nm) using Soller slits. Based on figure 5, it was found that the main phases in the sintered sample are TiC, MoNi ₃ , Ni, Mo.

Porosity was determined using an Olympus GX51 inverted optical microscope with quantitative image analysis software. The prepared samples had no traces of grinding, polishing, or chipping of structural components. The section was made according to the cross-section (fracture) of the whole product or part of it with an area of <2 cm ² . The SIAMS Photolab software, which the microscope is equipped with, has been developed taking into account the specific application of digital microscopy and image analysis methods for metallographic analysis of compounds. The results of the study of porosity are presented in figure 5, the porosity is 0.14%.

Testing the hardness of the samples on the surface and cross-sectional section was carried out using an automatic system for analyzing microhardness DM-8 according to the micro-Vickers method with a load on the indenter of 50 g for ten prints with a free choice of the injection site in accordance with GOST 9450-76 (Measurement of microhardness by indentation of diamond tips ). The indenter loading time was 15 s. As a result, the average hardness was 1303 HV.

Example 2.

To obtain powder materials from wastes of tungsten-free hard alloy grade KNT16 by the method of electroerosive dispersion in ethyl alcohol, an EED unit was used (Pat. 2449859 Russian Federation, IPC С22F 9/14, С23Н 1/02, B82Y 40/00. materials [Text] / Ageev E.V. and [others]; applicant and patentee of the South-West State University - No. 2010104316/02; application 08.02.2010; publ. 10.05.2012, bull. 13). When receiving the powder, the following setup parameters were used: waste of tungsten-free hard alloy grade KNT16 was dispersed at a voltage across the electrodes of 195-205 V, capacitance of discharge capacitors of 25.5 μF, and a pulse repetition rate of 95-105 Hz. As a result of the local action of short-term electrical discharges between the electrodes, the material was destroyed with the formation of dispersed particles of the powder material.

Tungsten-free hard-alloy billets were obtained by hot pressing with the passage of a high-ampere current in vacuum at a temperature of 1000 ° C for 5 minutes, from a powder material obtained by electroerosive dispersion of KNT16 grade wastes of tungsten-free hard alloys.

The workpiece obtained under these sintering modes does not have the best physical and mechanical properties.

Example 3.

To obtain powder materials from wastes of tungsten-free hard alloy grade KNT16 by the method of electroerosive dispersion in ethyl alcohol, an EED unit was used (Pat. 2449859 Russian Federation, IPC С22F 9/14, С23Н 1/02, B82Y 40/00. materials [Text] / Ageev E.V. and [others]; applicant and patentee of the South-West State University - No. 2010104316/02; application 08.02.2010; publ. 10.05.2012, bull. 13). When receiving the powder, the following setup parameters were used: waste of tungsten-free hard alloy grade KNT16 was dispersed at a voltage across the electrodes of 195-205 V, capacitance of discharge capacitors of 25.5 μF, and a pulse repetition rate of 95-105 Hz. As a result of the local action of short-term electrical discharges between the electrodes, the material was destroyed with the formation of dispersed particles of the powder material.

Tungsten-free hard-alloy billets were obtained by hot pressing with the passage of a high-ampere current in vacuum at a temperature of 1100 ° C for 5 minutes, from a powder material obtained by electroerosive dispersion of waste of tungsten-free hard alloys of the KNT16 brand.

The workpiece obtained under these sintering modes does not have the best physical and mechanical properties.

Claims (1)

A method of producing a tungsten-free hard alloy KNT from powder materials obtained in alcohol, including hot pressing of a powder material in a mold, characterized in that a powder material obtained by electroerosive dispersion of waste of tungsten-free hard alloys KNT16 in alcohol is used, while hot pressing is carried out in a vacuum with the passage of a high-ampere current through the mold and the pressed powder material at a temperature of 1200 ° C for 5 minutes.

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