RU2788382C1 - Method for producing carbon graphite composite material - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: invention relates to the field of metallurgy. The method for producing a carbon-graphite composite material includes vacuum degassing of a porous preform in a supersaturated aqueous solution of nickel sulfate hexahydrate with a concentration of 600 g/l at a salt solution temperature of 80°C. After vacuum degassing, the workpiece is dried at 150°C to a constant weight of the workpiece. The pores of carbon graphite are sealed by dipping a billet preheated to 400-450°C into A97 aluminum alloy, followed by cooling the billet in air. The workpiece is impregnated with a melt of a matrix aluminum alloy of the same composition under the influence of excess pressure due to thermal expansion of the aluminum alloy melt when heated by 300°C above the recrystallization temperature of the aluminum alloy. The workpiece is sealed with a lead alloy in a mold at a temperature of 600°C.

EFFECT: improving the quality of the composite material.

1 cl, 1 tbl, 1 ex

Description

The invention relates to the field of metallurgy, and in particular to the creation of composite materials by impregnation of a porous frame, having high electrical conductivity, anti-friction properties, resistance in aggressive environments .

A method for manufacturing composite materials is known, which includes immersing a porous workpiece into a melt of a matrix aluminum alloy located in an impregnation chamber, vacuum degassing in the melt, heating the aluminum alloy by 100°C above the liquidus temperature simultaneously with the lead melt located in the pressure chamber, and exposure to excessive pressure on the workpiece due to thermal expansion of the melt in the closed volume of the impregnation vessel (RF patent No. 2539528, IPC B22F3 / 26, C22C1 / 04, publ. 01/20/2015).

The disadvantages of this method are the large time spent on heating the tooling and cooling it to degas the impregnation chamber, the difficulty of ensuring the tightness of the two chambers for pressurizing the lead alloy and the impregnation chamber.

The closest is a method for obtaining a carbon-graphite composite material, including vacuum degassing of a porous workpiece in a nickel electrolyte solution, electroplating nickel coating, subsequent sealing of carbon graphite pores in an aluminum melt at a temperature of 750 ° C for 15-20 minutes, and impregnation of the workpiece with a melt of a matrix aluminum alloy under the influence of excess pressure due to thermal expansion of the aluminum alloy melt when heated by 300°C above the recrystallization temperature of the aluminum alloy (patent RU2725522, IPC C22C47/08, C22C47/12, 02.07.2020).

The disadvantage of this method is the need for impregnation at high temperatures and pressures to ensure the dissolution of the electroplated nickel coating and the complete filling of the pores with the matrix alloy, the large time and energy resources (electricity) when applying electroplated coatings, the need to clean water from polluting electrolyte components.

The task is to develop a method for maximum filling of pores in a carbon-graphite billet when it is impregnated with a matrix alloy.

The technical result of the invention is to simplify the method while maintaining and improving the quality of the composite material (CM).

The technical result is achieved in a method for producing a carbon-graphite composite material, including vacuum degassing of a porous workpiece in an aqueous solution of sulfate salt, its drying, subsequent sealing of carbon graphite pores in an aluminum alloy and impregnation of the workpiece with a melt of a matrix aluminum alloy of the same composition under excessive pressure due to thermal expansion of the melt aluminum alloy when heated by 300 °C above the recrystallization temperature of the aluminum alloy, while a supersaturated solution of nickel sulfate hexahydrate with a concentration of 600 g/l is used as a sulfate salt solution, vacuum degassing is carried out at a salt solution temperature of 80 °C, drying of the workpiece after vacuum degassing is carried out at 150 °C to a constant mass of the workpiece, and the sealing of carbon graphite pores is performed in A97 aluminum alloy by dipping a workpiece preheated to 400-450 °C into an aluminum alloy, followed by cooling the workpiece in air, moreover, After impregnating the workpiece with an aluminum alloy, the workpiece is additionally subjected to compaction with a lead alloy in a mold at a temperature of 600 °C.

The essence of the method consists in vacuum degassing of a porous billet (carbon graphite frame) in a heated supersaturated aqueous solution of nickel sulfate hexahydrate, complete drying of the billet, which ensures the solution dries in the pores of the billet and crystallization of nickel sulfate in them, followed by sealing the pores of carbon graphite, which makes it possible to delay further processing of the billet for an indefinite period. period with the preservation of the properties acquired by it as a result of preparatory work, impregnation of the workpiece with a melt of a matrix aluminum alloy using gas-free technology, and subsequent compaction (deeper pushing into the pores) of the aluminum alloy due to the effect of excess pressure of the lead alloy on the impregnated workpiece in the mold.

The claimed method is simple, does not require electrolysis equipment, it allows to increase the productivity of the process by reducing the time for its implementation, and also helps to increase the wetting of the carbon-graphite frame with an aluminum alloy, which leads to an increase in the filling of pores with metal.

Salt crystals dissolve in the aluminum alloy melt and provide concentrated alloying at the interface between carbon graphite and aluminum alloy, which in turn makes it possible to better fill the pores with aluminum alloy.

The compaction of the impregnated blank in the mold increases the density of the metal in the pores, and also pushes it deeper into the pores and, accordingly, improves the quality of composite materials (CM).

The method is carried out as follows.

Vacuum degassing of the carbon-graphite framework is carried out in a supersaturated aqueous solution of nickel sulfate hexahydrate (concentration 600 g/l). The temperature of the solution is 80 °C. In the process of vacuum degassing, a supersaturated solution penetrates into the pores of carbon graphite.

During the subsequent drying of the workpiece at 150 °C, water evaporates both from the surface of the workpiece and from its pores. In this case, the crystallization of nickel sulfate remaining in the pores occurs. Achieving the condition of constant mass of the workpiece ensures complete evaporation of water.

Next, the workpiece is heated in a furnace to a temperature of 400-450 °C, after which the surface is covered with an aluminum alloy by dipping into an aluminum alloy melt at a temperature of 680 °C, followed by cooling the workpiece in air for 5-10 minutes. Preliminary heating of the workpiece allows the aluminum alloy to evenly cover the surface of the carbon-graphite workpiece.

Sealing the pores of the carbon-graphite frame closes access to gases (oxygen, nitrogen, etc.) and dust, and allows the preparation of carbon graphite in the form of a “semi-finished product”, while maintaining the properties acquired by it as a result of preparatory work: it is easy to store, store and, if necessary, impregnate a given amount blanks without wasting time on preparatory work. With the planned impregnation, the aluminum surface of the workpiece is dissolved in the main melt of the aluminum alloy, and allows it to fill the pores more efficiently.

Aluminum alloy A97 (GOST 11069-2001) is used as an aluminum alloy for sealing pores and for impregnation.

The resulting workpiece is impregnated according to the classical gas-static technology with a melt of a matrix aluminum alloy under the influence of excess pressure due to thermal expansion of the aluminum alloy melt when heated by 300 °C above the recrystallization temperature of the aluminum alloy.

After impregnation is completed and the impregnated workpiece is removed from the impregnation device, the matrix alloy crystallizes in the pores due to air cooling. Then, the matrix alloy is compacted in the pores of carbon graphite, pushing aluminum deeper into the pores with the help of lead melt in the mold by creating an excess pressure of 10 MPa inside the mold at a temperature of 600 °C.

Example

According to the proposed method, a CM was obtained on the basis of a porous billet made of carbon graphite grade AG-1500 with an open porosity of 15%. The carbon graphite sample was made in the form of a cube with a side of 30 mm. Thus, the volume of the carbon-graphite frame was 900 mm ³ , the volume of pores in the frame was 135 mm ³ .

The chamber for evacuating the carbon-graphite frame was filled with an aqueous solution of nickel sulfate hexahydrate heated to 80°C with a concentration of 600 g/l. The porous preform was immersed in the solution, closed, and vacuum degassing was performed for 10 minutes. Next, the carbon-graphite billet was dried at a temperature of 150 °C to a constant weight. After drying, the carbon-graphite billet is preliminarily heated in a separate furnace to 400 °C and a metal coating of an aluminum alloy is applied to the surface in a crucible at a temperature of 680 °C, for which the billet is immersed in a crucible with an aluminum alloy and held under the surface of the alloy for 5- 10 seconds, after which the workpiece is removed and left to cool in air.

Next, the workpiece is placed in the device for impregnation and filled with aluminum alloy and closed with a lid. The impregnation device is heated to 700 °C with an isothermal hold of 20 min. At the end of the impregnation, the CM is removed and it is cooled with the crystallization of the aluminum alloy in the pores.

After impregnation with an aluminum alloy, the carbon-graphite billet is placed in a mold heated to 600 °C. After that, a lead alloy is poured into the mold, the temperature of which is 620 °C. Next, the mold is installed on the press and after the formation of a metal crust on the surface of the filling hole, excess pressure is created through the plunger inside the mold and maintained for 50 seconds. After exposure, the resulting CM is removed from the mold.

The resulting CM was tested for compressive strength, the degree of filling of open pores (impregnation density) was estimated from the specific gravity of the CM before and after impregnation.

The results of tests of KM are given in the table.

Table

KM carbon graphite - aluminum alloy Pouring temperature (beginning of impregnation), °C Temperature at the end of impregnation, °C Impregnation pressure, MPa Pressure holding time, min. Degree of filling of open pores, % Compressive strength of KM, MPa Results of metallographic studies According to the proposed method 680 700 2 20 96 191 Some microscopic pores are not filled Prototype method 600 750 3 20 92 181 The filling of microscopic pores is not complete, there are small unfilled areas

Thus, a method for producing a carbon-graphite composite material, including vacuum degassing of a porous workpiece in a supersaturated aqueous solution of nickel sulfate hexahydrate with a concentration of 600 g/l, at a salt solution temperature of 80 °C, drying of the workpiece after vacuum degassing is carried out at 150 °C to a constant weight of the workpiece, subsequent sealing of the pores of carbon graphite by dipping a billet preheated to 400-450 °C in aluminum alloy A97, followed by cooling the billet in air, impregnation of the billet with a melt of a matrix aluminum alloy of the same composition under the influence of excess pressure due to thermal expansion of the aluminum alloy melt during heating by 300 °C is higher than the recrystallization temperature of the aluminum alloy, and sealing the workpiece with lead alloy in a mold at a temperature of 600 °C is simple and ensures the preservation and improvement of the quality of the composite material (CM).

Claims (1)

A method for producing a carbon-graphite composite material, including vacuum degassing of a porous workpiece in an aqueous solution of sulfate salt, its drying, subsequent sealing of carbon graphite pores in an aluminum alloy and impregnation of the workpiece with a melt of a matrix aluminum alloy of the same composition under the influence of excess pressure due to thermal expansion of the aluminum alloy melt during heating 300 °C higher than the recrystallization temperature of the aluminum alloy, characterized in that a supersaturated solution of nickel sulfate hexahydrate with a concentration of 600 g/l is used as a sulfate salt solution, vacuum degassing is carried out at a salt solution temperature of 80 °C, drying of the workpiece after vacuum degassing is carried out at 150 °C to a constant weight of the workpiece, and sealing the pores of carbon graphite is performed in aluminum alloy A97 by dipping a workpiece preheated to 400-450 °C into an aluminum alloy, followed by cooling the workpiece in air, and after impregnation of the workpiece With aluminum, the workpiece is additionally subjected to compaction with a lead alloy in a mold at a temperature of 600 °C.