RU2791023C1 - Method for induction surfacing of iron-based magnetic alloys and induction-channel furnace for induction surfacing of iron-based magnetic alloys - Google Patents

Abstract

FIELD: agriculture machinery.

SUBSTANCE: invention relates to the field of metallurgy and can be used to strengthen the wear surfaces of the working bodies of agricultural machines with wear-resistant alloys. A method for induction surfacing of iron-based magnetic alloys includes applying a charge of a magnetic alloy in the form of a powder onto a strengthened surface of a workpiece and its subsequent melting by a high-frequency field of an inductor. The induction channel furnace for surfacing contains a cylindrical inductor (2) with two heating zones. The first heating zone (1) has a diameter of a cylindrical inductor greater than the diameter of the second zone (6) inductor. There is a hollow graphite core (5) inside the inductor of the first zone. The billet with the applied mixture is placed in a graphite core in the first zone (1) and heated to a temperature of 770-790°C with the absorption of a high-frequency magnetic field by a graphite core, which ensures the demagnetization of the magnetic alloy charge. Then the billet with the charge is moved to the second zone (6) of the furnace, where the charge is melted.

EFFECT: use of powders from iron-based magnetic alloys for induction surfacing due to the exclusion of their dropping from the strengthened surface of the workpiece.

2 cl, 1 dwg, 2 ex

Description

The invention can be used in the production of various working bodies of agricultural machines by hardening wear-resistant alloys of wear surfaces subjected to intense abrasive wear.

It is known that powdered high-alloy chromium cast irons are used as hardening, which should have a minimum magnetic permeability. This is due to the fact that the surfacing mixture is partially “thrown off” from the hardened surface of the part by the electromagnetic field of the inductor placed in it. (Bogodukhov, S.I. Hardening of the surface of low-carbon steel with self-fluxing hard alloys / Mashinostroenie. - 2014. No. 3. - P. 19-26).

Therefore, GOST 21448-75, paragraph 2.5, recommends that alloy powders for iron-based induction surfacing should not be magnetic.

In order to reduce the effect of magnetic permeability on the metal part of the surfacing charge, to keep it on the surface of the hardened part during the surfacing process, pastes are used that are sintered on the surface of the part at a temperature of 540-560 ° C for 12 minutes (Tkachev V.N. Wear and increase in durability details of agricultural machines / Mashinostroyeniye, 1971, p. 164). In addition, when applying the charge in the form of a paste, rather than powders, the scattering of the main alloying components responsible for the strength, toughness and wear resistance of the deposited layer is excluded (RU 2595180, 08/20/2016).

In the same way, alloys are created that have a microstructure with reduced magnetic permeability, for example, due to the presence of austenite in the deposited high-alloy chromium cast iron, it is subjected to hardening from a temperature of 1140-1200 ° C (V.N. Tkachev wear and increase the durability of parts of agricultural machines / Mashinostroenie, 1971, p. 164).

The use of powder non-magnetic materials to harden the wear surfaces of parts significantly reduces the complexity of the process of induction surfacing of parts operating under conditions of intense abrasive wear, but significantly narrows the possibility of using powder alloys with high magnetic permeability.

A known method (similar to patent RU No. 2090326, C1 20.09.1997), where the cylindrical workpiece is preheated to a temperature of 300-400°C. The charge, which includes boron-containing fluxes and magnetic components (grains, iron-based powder material compound), is poured onto the surface of the workpiece and formed with a specially profiled clot scraper. The mixture is baked to the surface of the part due to the flux part.

The disadvantage of the known technical solution is the significant complexity in the organization of the process of induction surfacing, including because of the magnetic powder materials consisting in the need to form a surfacing mixture, at a certain temperature, on the hardened surface of the part.

For the prototype, the method of induction surfacing, described in the work of the inductor for one-sided continuous-sequential surfacing by an external field), is chosen, which consists in the fact that the welded workpiece moving under the inductor is preheated with a passive coil, and the main heating until the charge is melted in another part of the inductor (patent RU 2026610, 01/09/1995).

The disadvantage of this method of surfacing is that its technology provides for preheating of the deposited charge on the hardened workpiece due to the influence of the electromagnetic field of the inductor. However, in this case, a partial dropping of the metal part of the charge from the hardened surface occurs, which significantly limits the possibility of using magnetic powder materials.

Known induction channel furnace for surfacing magnetic alloys based on iron, containing a housing, a heating zone, a crucible, a magnetic circuit (SU 1722121, 30.11.94). The disadvantage of this device is that the surfacing charge is partially "discarded" from the hardened surface of the workpiece by the electromagnetic field of the inductor.

Closest to the proposed device is an induction furnace for surfacing magnetic alloys based on iron, containing a housing, a cylindrical inductor, a crucible, a magnetic circuit and two induction coils in series (RU 2083938, 31.05.94).

The disadvantage of this device is that it is impossible to simultaneously demagnetize and qualitatively weld the iron-based magnetic alloy.

The problem solved by the proposed group of inventions is the possibility of using powders of iron-based magnetic alloys for induction surfacing and reducing the complexity of the process.

The technical result is achieved by demagnetizing the iron-based magnetic powder before melting by placing it in a hollow graphite core.

The problem is solved in the following way. In the method of induction surfacing of iron-based magnetic alloys, with deposition on the hardened surface of the workpiece in the form of a charge, which is a powder and subsequent melting by the high-frequency field of the inductor, the initially hardened workpiece with the charge of the hardened material deposited on its hardened surface is placed in a hollow graphite core installed in the first zone of the induction channel furnace, and the workpiece to be hardened is heated to a temperature of 770-790° while ensuring the absorption of the high-frequency magnetic field by a hollow graphite core, and then the workpiece to be hardened with the charge is moved to the second zone of the induction channel furnace and a melt of the strengthening material is produced.

In the device in the induction channel furnace for induction surfacing of iron-based magnetic alloys containing a cylindrical inductor with two heating zones, the first heating zone has a diameter of the cylindrical inductor larger than the inductor of the second heating zone, while inside the inductor of the first heating zone there is a hollow graphite core, made with the possibility placement of the hardened workpiece in it.

In FIG. 1 - Scheme of an induction channel furnace consisting of two heating zones.

The two-channel induction furnace consists of the first heating zone 1, a cylindrical inductor 2, covered by a magnetic circuit 3, insulated with asbestos insulation 4, from a hollow graphite core 5, made with the possibility of placing a hardened workpiece in it.

The second zone 6 of the induction channel furnace is located behind the first one and is made with a magnetic circuit 7 of a smaller diameter. Inside the hollow graphite core 5 is placed with the ability to move the workpiece to be welded 8 with the surfacing charge 9.

The implementation of the method is carried out as follows. A cylindrical inductor consisting of two zones 1 and 6 is connected to an ELSIT 70/40 inverter (not shown in the figure). In zone 1 of the two-zone inductor 2 there is a magnetic core 3 and a hollow graphite core 5 isolated from it with asbestos insulation 4, heated to a temperature of 770°C. The heating temperature of the surface of the welded workpiece 8 was determined by a chromel-alumelium thermocouple (not shown in Fig.) with a welding charge 9 poured on it. Placed in a hollow graphite core 5 made with the possibility of placing a hardened workpiece in it, and the charge and the workpiece were heated for 60 seconds . After installing the workpiece with the charge in the hollow graphite core, the power source is turned on and heats it with an alternating magnetic field. The workpiece installed in it is exposed to an electromagnetic field and heated to a temperature of 740-790°C due to the heat created by the graphite core. Then the sample with the surfacing charge is moved to the second zone 6 of the cylindrical inductor with the magnetic circuit 7 and the hardened alloy is melted.

The invention is illustrated by the following examples.

Example 1. Samples for induction surfacing in a cylindrical inductor 2 consisting of two zones 1 and 6 were prepared as follows: from rolled steel 65G 8 mm thick, blanks 20 * 60 mm were cut in the amount of 10 pcs; the composition of the surfacing mixture consisted of a powder of 85% high-alloy chromium cast iron grade PG-US25, GOST 244878 and 15% flux grade P-066;%; The surfacing charge was mixed for 15 minutes in a bicone mixer before being poured onto the surface of the part: the prepared surfacing charge was applied with a special dispenser onto a hardened surface 3 mm high, 20 mm wide and 25 mm long.

The prepared workpiece for surfacing was placed in a cylindrical inductor connected to an ELSIT-70/40 inverter.

The cylindrical inductor consists of two zones. In the first zone of the inductor 1 there is a rectangular hollow graphite core 5 (internal dimensions: 40 * 40 * 60) with a wall thickness of 6 mm in which the sample is heated to a temperature of 770-790°C. The specified temperature range of heating in the first zone of the inductor with an induction graphite heater eliminates the magnetic properties of the workpiece to be hardened and the surfacing charge.

When the workpiece and the charge are heated, for example, to a temperature of 760°C, and not up to 770°C, the surfacing charge is partially thrown off. Heating the surfacing charge and the sample to a temperature of 800°C, and not to 790°C, increases the heating time by 4-5%.

It has been experimentally established that for high-chromium white cast irons, the magnetic properties disappear at a temperature of 750°C, and for iron-carbon alloys at 768°C. The second zone of the inductor is made in the form of an oval, into which the workpiece moves after heating in a graphite core. The temperature measurement was carried out as follows. After preliminary calibration, a chrome-alumel thermocouple (0.2 mm in diameter) was welded to the workpiece (capacitor welding, not shown in Fig.), and it was connected to the K57PV1A ADC and reading was performed. Digitization and transfer to a personal computer (with the installation of data recording software - ASD.com, and data reading and calibration of ADS.med devices operating in the Matkhcad system) of its readings at a speed of 36 sec ^-1 made it possible to fix the fast process of heating the surface of the workpiece.

In the same way, the second composition of the charge was prepared, consisting of iron powder PZhV1.450.26. GOST 9849-86 - 85% and P-066 flux 15%, which, like the first composition of the surfacing charge, was heated to the same temperatures in an inductor consisting of two zones as the first one.

Throwing off the surfacing mixture did not contain both high-alloy chromium cast iron and iron powder.

Example 2. Surfacing charge consisting of two compositions of alloy PG-US25 and iron powder grade PZhV1.450.26. GOST 9849-86 (the same flux), as in the first example, was poured onto prepared workpieces. Heating and melting were carried out in an inductor connected to an ELSIT-70/40 inverter, in the same modes.

When the charge contains high-alloy powder iron PG-US25, after turning on the inverter, an alternating magnetic field arises inside the cylindrical inductor. The deposited charge with a workpiece to be hardened, located between the inductor branches, is “shaken” after the power source is turned on, and the charge wakes up (5-7%), regardless of the degree of magnetization of the materials.

In the case of iron powder, the charge is discarded up to 50% from the metal billet.

Thus, the proposed method with preheating of the workpiece and the surfacing charge in two zones of the inductor, one of which has a graphite hollow core, makes it possible to expand the range of powder materials for induction surfacing. Simplifies the organization of the technological process of induction surfacing.

Claims (2)

1. A method for induction surfacing of iron-based magnetic alloys, which includes applying them to the hardened surface of the workpiece in the form of a charge, which is a powder, and subsequent melting by a high-frequency field of the inductor, characterized in that the initially hardened workpiece with the charge of the hardened material deposited on its hardened surface is placed in a hollow graphite core installed in the first zone of the induction channel furnace, and the workpiece to be hardened is heated to a temperature of 770-790°C while ensuring the absorption of the high-frequency magnetic field by the hollow graphite core, and then the workpiece to be strengthened with the charge is moved to the second zone of the induction channel furnace and a melt is produced reinforcing material. 2. Induction channel furnace for induction surfacing of magnetic alloys based on iron, containing a cylindrical inductor with two heating zones, characterized in that the first heating zone has a diameter of a cylindrical inductor greater than the diameter of the inductor of the second heating zone, while inside the inductor of the first heating zone there is a hollow graphite a core made with the possibility of placing a hardened workpiece in it.

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