RU2631548C1 - Method for producing tungsten carbide-based hard alloy products - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: method includes sintering of powder in a furnace at a temperature ranging from 1360 to 1550°C to produce product and its cooling. Cooling of the product is carried out together with the furnace to 950°C, then the product is cooled to 800°C with a speed of 1.0°C/minute to 3.5°C/minute, then the product is cooled with the furnace to the room temperature.

EFFECT: improvement of hard alloy products quality due to the production of more fine and uniform structure of the hard alloy.

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Description

The invention relates to the field of powder metallurgy, in particular to the production and hardening of hard alloys based on tungsten carbide, which can be used for the manufacture of drilling tools, wear-resistant parts and cutting tools.

The following solutions are known from a patent study.

A known method of hardening of hard alloys, including sintering of hard alloys at a temperature of 1650 ° C, cooling, vacuum tempering with heating to a temperature of 1050 ° C - 1250 ° C and holding for 1 hour, followed by cooling with the furnace for 4 hours (RF Patent No. 2534670 published on 12/10/2014).

The disadvantage of this method is the need for an additional heat treatment operation, which leads to an increase in the complexity and cost of products, as well as insufficiently high quality of the obtained alloys.

The closest analogue to the patented solution is a method of manufacturing carbide metal-ceramic products (see RF patent No. 2145916, published on 02.27.2000), including the preparation of WC-Co charge components, grinding, mixing, filling the charge into a mold, molding and sintering by heating and aging at sintering temperature. According to one variant of the method, after sintering the product, it is subjected to cooling to a temperature of 1250-900 ° C with a cooling rate of not more than 3 ° C / s, and further cooling is carried out in the hardening mode with a cooling rate of at least 3 ° C / s to a temperature of +300 ° C - (-196 ° C), after which the product is subjected to stabilizing annealing by heating to a maximum temperature of 0.35-0.5 of the maximum temperature of the hardening mode, then the product is cooled, and after the first hardening cycle or after stabilizing annealing, the product is subjected to They provide at least one repeated quenching regime, including repeated heating to a temperature of 900–1250 ° С and holding.

The disadvantages of this method are the need for several additional heat treatment operations, the high complexity and duration of the process, as well as the insufficiently high quality of the obtained ceramic-metal products.

The objective of the patented solution is to eliminate these disadvantages. Improving the quality of the hard alloy, obtaining a finer and more uniform structure is carried out in one sintering process. By eliminating the operations of additional heat treatment, a simplification of the technology for producing a hard alloy and a significant reduction in the time of manufacturing parts are achieved.

The technical result of the patented solution is to improve the quality of the obtained hard alloy by obtaining a finer and more uniform structure, reducing labor costs and simplifying the process of producing hard alloys.

The claimed technical result is achieved through the implementation of the patented method of obtaining products from a hard alloy based on tungsten carbide, according to which sintering of the alloy is carried out at a temperature in the range from 1360 to 1550 ° C and cooling to room temperature, while the alloy is cooled together with the furnace to 950 ° C, then the alloy is cooled to 800 ° C at a speed of 1.0 ° C / min to 3.5 ° C / min, followed by cooling together with the furnace to room temperature.

Due to the low cooling rate from 1 ° C / min (0.017 ° C / s) to 3.5 ° C / min (0.058 ° C / s) in the temperature range from 950 ° C to 800 ° C, the tungsten compounds dissolved in the binder precipitate into a bunch in the form of nanoparticles. There is a uniform refinement of the structure, dispersion hardening of the binder and an increase in the mechanical properties of the resulting alloy.

Cooling together with the furnace from sintering temperatures to 950 ° C and from 800 ° C to room temperature saves energy, since at that time the furnace heaters are turned off.

The proposed method for producing a tungsten carbide-based carbide is as follows.

Sintering of hard alloys is carried out at a temperature in the range from 1360 ° C to 1550 ° C. When heated from room temperature to 750 ° C, the process is carried out in a hydrogen atmosphere, from 750 ° C to sintering temperature in a vacuum. At maximum temperature, exposure is carried out for 45 minutes. Then argon is supplied under a pressure of 6-10 MPa and the heating is turned off. Subsequent cooling from sintering temperature to 950 ° C occurs together with the furnace in an argon atmosphere. The average cooling rate in this temperature range is 12 ° C / min. When the temperature reaches 950 ° C, the heaters turn on and then there is controlled cooling at a speed of 1 ° C / min to 3.5 ° C / min to a temperature of 800 ° C. The cooling rate is set by the program on the thermostat. After 800 ° C, the heaters turn off and then to a temperature of 100 ° C, cooling occurs together with the furnace. At a temperature of 100 ° C, the furnace opens. Up to 600 ° C, the cooling rate is 4.5 ° C / min, then the cooling rate gradually slows down to zero.

At a controlled cooling rate from 1.0 ° C / min to 3.5 ° C / min in the temperature range from 950 to 800 ° C, the processes of precipitation of the dissolved tungsten, carbon and cobalt compounds in the form of nanoparticles occur.

The invention is further illustrated by way of examples.

Example 1. Obtaining hard alloys VK8, VK10, VK15 and VK20 was carried out according to the schedule presented in figure 1, by heating the sintered powder to a temperature of 1450 ° C, holding at this temperature and cooling to room temperature with the furnace.

Example 2. Obtaining carbides VK8, VK10, VK15 and VK20 was carried out according to the schedule presented in figure 4, in accordance with the proposed method.

As a result of tests of the obtained samples according to the first and second examples, their mechanical properties were determined. The test results are shown in table 1.

From table 1 it follows that the receipt of hard alloys based on tungsten carbide by the proposed method gives a noticeable increase in the indicators of physical and mechanical properties (strength, hardness and coercive force).

An increase in the cooling rate of more than 3.5 ° C / min has practically no effect on improving the properties of the hard alloy as compared to conventional sintering.

When the cooling rate decreases below 1 ° C / min, the effect of increasing the properties is retained, but the duration of sintering increases, which is not economically feasible.

The figure 2 presents a photo of the microstructure of a sample of hard alloy VK15 obtained by the method specified in example 1.

Figure 3 is a diagram of the size distribution of tungsten carbide grains in a sample of VK15 hard alloy obtained by the method described in Example 1. On the abscissa axis, grain sizes in micrometers are indicated, on the ordinate axis, the percentage of grains having a given size.

The figure 5 presents a photo of the microstructure of a sample of hard alloy VK15, sintered according to the method specified in example 2 (the proposed method).

FIG. 6 is a graph of grain size distribution in a sample of VK15 hard alloy obtained by the method specified in Example 2. On the abscissa axis, grain sizes in micrometers are indicated, on the ordinate axis, the percentage of grains having a given size.

Based on the grain size distribution diagram in the VK15 hard alloy sample, it follows that the tungsten carbide-based hard alloys obtained by the proposed method have a finer and more uniform structure compared to the method described in example 2.

In addition, on the samples of hard alloys VK8, VK10, VK20 obtained in accordance with the proposed method, a similar pattern was observed with a finer-grained alloy structure compared to the method of example 1.

Thus, the claimed method allows to increase the physical and mechanical properties of the hard alloy without additional heat treatment using traditional equipment.

Claims (1)

A method of producing a tungsten carbide-based hard alloy product, comprising sintering a powder in a furnace to obtain a hard alloy product and cooling the resulting product, characterized in that the powder sintering in the furnace is carried out at a temperature in the range from 1360 to 1550 ° C, while cooling the products are carried out together with the furnace to 950 ° C, then the product is cooled to 800 ° C at a speed of 1.0 ° C / minute to 3.5 ° C / minute, after which the product is cooled together with the furnace to room temperature.

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