RU2793674C1 - Composite material - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: composite material based on aluminium alloy with reinforcing fibres includes an aluminium alloy matrix and a hardener. The hardener is made in the form of reinforcing fibres. The matrix is made of aluminium alloy AK7. The reinforcing fibres are made of copper wire with a cross section of 0.5 mm and a length limited by the size of the composite material. The reinforcing fibres are laid along the composite material at equal distances from each other. Hollow nickel spheres 4 mm in diameter are strung close to each other on the reinforcing fibres. The distance between the reinforcing fibres corresponds to 1-2 diameters of hollow nickel spheres.

EFFECT: obtaining a lightweight composite material with improved strength characteristics.

1 cl, 1 tbl

Description

The invention relates to metallurgy, namely to the production of a casting composite material based on aluminum and its alloys, reinforced with reinforcing metal fibers, and can be used in mechanical engineering, when creating structures and equipment as structural materials with improved technological and operational properties.

Known composite material comprising a matrix of aluminum, magnesium or their alloys and a hardener made in the form of reinforcing aluminum oxide nanofibers coated with a film of amorphous carbon (patent RU 2374355, IPC C22C 49/14, publ.27.11.2009).

The disadvantage of the known composite material is the difficulty in obtaining it, since in order to improve the mechanical properties of the composite material, the nanofibers must be additionally covered with a film of amorphous carbon, which entails an increase in the cost of the final product.

A composite material based on aluminum or an aluminum alloy is known, containing an aluminum alloy matrix and a hardener made in the form of a conglomerate of discrete aluminum oxide fibers (patent RU 2755353, IPC C22C 49/06, publ. 15.09.2021).

The disadvantage of the known composite material is the used hardener, made in the form of a conglomerate of discrete fibers of aluminum oxide, transported copper powders in a matrix of aluminum or aluminum alloy, creating a composition of hardening of various shapes and sizes. This affects the technological and operational properties of the product.

The closest in technical essence is a composite material based on an aluminum alloy with reinforcing fibers, including a matrix of aluminum alloy Al-Mg-Si and a reinforcing agent in the form of reinforcing fibers 2-5 mm long in an amount of up to 25% vol. the same composition as the matrix, or from a titanium alloy and obtained by the method of high-speed solidification of the melt (patent RU 2538245, IPC S22S49 / 06, publ. 10.01.2015).

The disadvantage of the composite material is the uneven arrangement of reinforcing fibers of small length, which contributes to the uneven manifestation of the strength properties of the composite material. This does not ensure the identity of the properties of all parts made from different parts of this material.

The objective of this invention is to develop a lightweight composite material with high strength properties throughout the volume.

The technical result is a lightweight composite material with increased strength characteristics.

The technical result is achieved by the fact that in a composite material based on an aluminum alloy with reinforcing fibers, including an aluminum alloy matrix and a reinforcing agent made in the form of reinforcing fibers, the matrix is made of AK7 aluminum alloy, and the reinforcing fibers are made of copper wire with a cross section of 0.5 mm and a long one limited by the size of the composite material, laid along the material at equal distances from each other, while hollow nickel spheres with a diameter of 4 mm are strung on the fibers close to each other, and the distance between the reinforcing fibers corresponds to 1-2 diameters of hollow nickel spheres.

Reinforcing fibers are designed to strengthen the material and form an additional metal frame in the body of the casting, which can significantly increase its strength characteristics and lighten the composite material (CM). Hollow nickel spheres mounted on copper fibers provide a reduction in the mass of the product due to the formation of cavities in the body of the casting, while the production of copper fibers and nickel spheres prevents their melting upon contact with AK7 aluminum melt during mold casting with metal in the production of KM. In addition, good wettability and adhesion of the nickel surface allows the AK7 alloy to fill the voids between the granules and fibers to the maximum, which in turn reduces (or completely eliminates) additional (uncontrolled) porosity in the composite material and reduces the possibility of “chipping” of hollow nickel spheres during operation. products.

To obtain a composite material, hollow nickel spheres of the same diameter of 4 mm were used, closely strung on a copper reinforcing fiber (for example, wire) with a cross section of 0.5 mm.

Reinforcing fibers with threaded hollow nickel spheres of a given length, corresponding to the length of the composite material, are placed and fixed on the forming plates installed in the lower half of the sand-clay casting mold at a given distance. The location of the fibers with metal hollow spheres is carried out along the composite material. Then the upper half is mounted on the lower half-mould. The mold assembly is filled with a melt of aluminum grade AK7 at an alloy temperature of 780 ° C, followed by knocking out the resulting casting from the mold, after the metal has solidified and the desired product has been obtained from the resulting composite material.

The resulting composite material was tested for strength in tension and bending, the density of the composite material was determined by the hydrostatic method. The test results are shown in the table. For comparison, under the same experimental conditions, a casting of AK7 aluminum (without the use of reinforcing fibers) and KM with the use of reinforcing fibers without hollow nickel spheres was tested.

Table

composite material Distance between reinforcing fibers, mm Density, kg / m ³ KM tensile strength, MPa KM strength in bending, MPa According to the invention: using reinforcing fibers strung with hollow nickel spheres 4 2031 212 227 8 1955 202 211 With reinforcing fibers without hollow nickel spheres - 2946 256 324 Without the use of reinforcing fibers - 2652 147 205

According to the test results, it was found that the composite material obtained using reinforcing fibers with closely strung hollow metal spheres showed the lowest density with an average increase in strength characteristics.

The use of reinforcing fibers provides the highest strength characteristics, but at the same time there is a significant weighting of the composite material.

Thus, a composite material based on an aluminum alloy with reinforcing fibers, including a matrix of aluminum alloy AK7 and a hardener made in the form of reinforcing fibers, made of copper wire with a cross section of 0.5 mm and a length limited by the size of the composite material, laid along the material at equal distances from each other. from each other, in which hollow nickel spheres with a diameter of 4 mm are strung on the fibers close to each other, and the distance between the reinforcing fibers corresponds to 1-2 diameters of hollow nickel spheres, is a lightweight composite material with increased strength characteristics.

Claims (1)

Composite material based on aluminum alloy with reinforcing fibers, including a matrix of aluminum alloy and a hardener made in the form of reinforcing fibers, characterized in that the matrix is made of aluminum alloy AK7, and the reinforcing fibers are made of copper wire with a cross section of 0.5 mm and a length limited by the size of the composite material, laid along the material at equal distances from each other, while hollow nickel spheres with a diameter of 4 mm are strung on the fibers close to each other, and the distance between the reinforcing fibers corresponds to 1-2 diameters of hollow nickel spheres.