RU2762446C1 - Method for treatment of silumin ak5m2 surface layer - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: invention relates to metallurgy, in particular to hardening processing of metals and alloys using concentrated energy flows. The method for treating the surface layer of AK5M2 silumin includes irradiating the surface layer with an intense pulsed electron beam in an argon atmosphere at a residual pressure of 2⋅10^-2 Pa with a number of pulses n=3, a pulse repetition rate of 0.3 s^-1. Irradiation is carried out with an intense electron beam with an electron energy of 17 keV, an electron beam pulse duration τ=200 mcs, and an electron beam energy density E_S=30-50 J/cm².

EFFECT: formed hardened surface layer of AK5M2 silumin has an improved structure, high microhardness and wear resistance.

1 cl, 3 dwg, 2 ex

Description

The invention relates to the strengthening processing of metals and alloys using concentrated energy flows.

A known method of producing hardened alloys based on aluminum, including the introduction into the melt of the aluminum base alloy in the form of rods from a mixture of aluminum powders containing modifying additives diboride or titanium carbide, which are compacted by shock wave action, while the content of powder of diboride or titanium carbide with a size particles (1 ÷ 5) μm in the ligature is 5 wt. %, and the resulting rods are introduced into an aluminum melt heated to 720 ° C while simultaneously exposing the melt to an ultrasonic field (patent RU No. 2542044, IPC C22C 1/03, C22C 1/06, publ. 20.02.2015).

However, this method is very difficult in technical implementation, since it involves a multistage process, which is associated with the complexity of control over it. In addition, this method does not provide a uniform distribution of particles in the matrix, and, therefore, obtain stable material properties.

The closest technical solution to the claimed invention is the method adopted as a prototype for modifying silumin by irradiating a sample of AK12 silumin with an intense pulsed electron beam with an electron energy of 18 keV, a pulse repetition rate ƒ = 0.3 Hz, an electron beam pulse duration τ = 50-150 μs , the energy density of the electron beam E _S = 10-25 J / cm ² and the number of exposure pulses n = 1-5, while the irradiation is carried out on the front surface of the sample, located above the notch imitating a crack, in an argon atmosphere at a residual pressure of 0.02 Pa (patent RU No. 2666817, IPC C22F 1/043, C22C 21/02, C22F 3/00, publ. 10.04.2018).

The disadvantage of this method is that irradiation of the surface of the AK12 silumin with a high-intensity pulsed electron beam in the mode of fusion of silicon inclusions is accompanied by the formation of micropores and microcracks in the surface layer, which weaken the material.

The technical problem solved by the present invention consists in the formation of a modified surface layer of silumin by processing with a high-intensity pulsed electron beam, which has an improved structure, as well as high microhardness and wear resistance.

The problem is solved by a method including irradiation of the surface layer of AK5M2 silumin with an intense pulsed electron beam in an argon atmosphere at a residual pressure of 2-10 ^-2 Pa with a number of pulses n = 3, a pulse repetition rate of 0.3 s ^-1 , according to the invention, irradiation carried out an intense electron beam with an electron energy of 17 keV, the electron beam pulse length of τ = 200 microseconds, the energy density of the electron beam E _S = 30-50 J / ^cm2.

The technical result obtained when using the proposed method consists in the formation of a hardened surface layer of silumin grade AK5M2, subjected to treatment with an intense electron beam with an electron energy of 17 keV, an electron beam energy density E _S = 30-50 J / cm ² , an electron beam pulse duration τ = 200 μs, which has an improved structure, high microhardness and wear resistance in comparison with the untreated silumin alloy in the cast state.

The proposed method is illustrated by the presented images:

fig. 1 - The structure of the AK5M2 alloy in the cast (before processing with an electron beam) state, in (b) the arrows indicate the inclusions of intermetallic compounds.

fig. 2 - Surface structure of silumin AK5M2 subjected to electron-beam processing: a - with energy density E _S = 30 J / cm; b - with energy density E _S = 50 J / cm.

fig. 3 - Dependence of microhardness HV on the energy density of the electron beam (30, 40, 50 J / cm ² ). The dashed line indicates the HV value of the untreated silumin alloy as cast (520 MPa).

In the initial state, the AK5M2 alloy is a polycrystalline aggregate, consisting mainly of grains of a solid solution based on aluminum (Fig. 1, a). Along the boundaries and at the joints of the A1 grain boundaries, grains of the A1-Si eutectic are located (Fig. 1, b), and there are also intermetallic inclusions (Figs. 1, 6, indicated by arrows).

Irradiation of silumin AK5M2 with an electron beam, regardless of the processing parameters, is accompanied by a significant transformation of the surface layer, namely, the melting and dissolution of particles of the second phase. Irradiation of the alloy with an electron beam energy density of 30 J / cm ² leads to the dissolution of the primary inclusions of intermetallic compounds, which is incomplete (Fig. 2, a). In some cases, islands are found on the irradiated surface, containing rounded particles with sizes in the range of 2-3 microns. With an increase in the energy density of the electron beam to 50 J / cm ² , complete dissolution of intermetallic particles in the surface layer is observed (Fig. 2, b). In this case, in a layer with a thickness of up to 50-70 μm, the formation of a structure of high-speed cellular crystallization is observed, the dimensions of which vary from 500 to 800 nm. The crystallization cells are formed by a solid solution based on aluminum, and the interlayers separating the cells are enriched with silicon, copper and iron atoms.

Analyzing the results of changes in the microhardness HV (Fig. 3), it can be noted that the value of HV of the surface layer of silumin depends on the energy density E _{S of the} electron beam. The microhardness of the surface layer has a maximum value of 860 MPa for E _S = 30 J / cm ² , exceeding the microhardness of the alloy in the cast (untreated) state (HV = 520 MPa) by 65%. The tribological properties of the modified silumin were characterized by the wear coefficient (the value inverse to the wear resistance), which decreases with an increase in the energy density of the electron beam (as a result, the wear resistance increases). The maximum increase in wear resistance (k = 0.37⋅10 ^-3 mm ³ / N⋅m) is observed at the energy density of the electron beam E _S = 50 J / cm ² and is 197% (in the initial state k = 1.1⋅10 ^{- 3} mm ³ / N⋅m).

It can be stated that such a significant increase in the microhardness and wear resistance of AK5M2 silumin is caused by the detected changes in the structure of the surface layer after electron-beam treatment, namely, the melting and dissolution of second-phase particles and the formation of a structure of high-speed cellular crystallization. Examples of specific use of the method.

Example 1.

The surface of AK5M2 silumin was subjected to electron beam processing. Silumin samples were 15 × 15 × 5 mm ³ . The processing was carried out on a surface with dimensions of 15 × 15 mm ² . The surface is modified according to the regime with an accelerated electron energy of 17 keV; the number of pulses N = 3; pulse duration τ = 200 μs; energy density E _S = 30 J / cm ² ; the pulse repetition rate is 0.3 s ^-1 , the pressure of the residual gas (argon) in the working chamber of the installation is 2⋅10 ^-2 Pa.

The surface wear parameter is k = 0.43⋅10 ^-3 mm ³ / N⋅m, which is 2.6 times less than in the initial state (k = 1.1⋅10 ^-3 mm ³ / N⋅m). The microhardness of the surface layer has a maximum value of 860 MPa, exceeding the microhardness of the alloy in the cast state by 65% (520 MPa).

Example 2.

The surface of AK5M2 silumin was subjected to electron beam processing. Silumin samples were 15 × 15 × 5 mm ³ . The processing was carried out on a surface with dimensions of 15 × 15 mm ² . The surface is modified according to the regime with an accelerated electron energy of 17 keV; the number of pulses N = 3; pulse duration τ = 200 μs; energy density E _S = 50 J / cm ² ; pulse repetition rate - 0.3 s ^-1 ; pressure of residual gas (argon) in the working chamber of the installation - 2⋅10 ^-2 Pa.

The surface wear parameter is k = 0.4⋅10 ^-3 mm ³ / N⋅m, which is 2.75 times less than in the initial state (k = 1.1⋅10 ^-3 mm ³ / N⋅m). The microhardness of the surface has a maximum value of 780 MPa, exceeding the microhardness of the alloy in the cast state by 50% (520 MPa).

Claims (1)

A method for treating the surface layer of AK5M2 silumin, including irradiation of the surface layer with an intense pulsed electron beam in an argon atmosphere at a residual pressure of 2⋅10 ^-2 Pa with a number of pulses n = 3, a pulse repetition rate of 0.3 s ^-1 , characterized in that the irradiation carried out an intense electron beam with an electron energy of 17 keV, the electron beam pulse length of τ = 200 microseconds, the energy density of the electron beam E _S = 30-50 J / ^cm2.

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