SU528997A1 - Method of making bimetallic products - Google Patents

Description

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pe.ucjis-HiUiiM (temperature gradient, and the leMTicpaiypa alloy in the last bath is 5 () 200 ° C lower. The temperature of the alloy in the first bath. Steel or cast iron is immersed for a certain time in the melting baths according to the degree of temperature decrease in them, then cooled.

This method also has a drawback - the complexity of the deposition process, due to the following factors; to obtain a layer of the desired thickness is possible only after repeated immersion of the workpiece in the molten liquid alloy; A large number of liquid-melted baths are required to carry out the process; In addition, for the implementation of the method, it is necessary to use complex auxiliary equipment that moves the workpieces in time and space with high accuracy according to a program selected by experienced chickpeas.

The purpose of the invention is to simplify the process of surfacing.

This is achieved by bringing the alloy to be welded to a solid-liquid state, and the billet with the alloyed layer is cooled to a temperature equal to 0.8-0.9 solidus temperature of the alloyed alloy.

In the melting bath, in a protective gaseous medium, the melt of the alloyed alloy is maintained at a constant working temperature. The working temperature of the melt is below the liquidus temperature ifa 0.01 - 0, .S JOT is the magnitude of the crystallization interval, and its surface is covered with a layer of active coating flux. The cold billet is immersed in the melt through a layer of liquid flux for a certain time. In the process of immersion, the liquid flux wets the surface of the workpiece and immediately solidifies as a solid flux cake. The deposited alloy crystallizes on the surface of the flux crust due to heat removal from the molten alloy into the body of the workpiece through the flux crust. By the time of flux melting, the entire billet is in a shell of a solid crystalline layer of the alloyed alloy. After melting the flux, the latter treats the surface of the workpiece, preparing it for wetting by the alloy. When the footage of the workpiece reaches its temperature,

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melting the alloy, the hard shell after / neck melts, the flux floats, and the alloy wets the fluxed surface of the workpiece. After removing the preform from the melt, its surface is coated with a thin layer of alloy. In a protective environment, the workpiece is kept for a certain period of time sufficient to cool the workpiece to a temperature of 0.8 - 0.9 solidus alloy temperature. The cooled, coated with a thin layer of alloy re-immersed in the same bath for a short period of time (2-6 sec.). After extraction from the melt, the billet is cooled. In the case of surfacing a self-flux alloy, it is not necessary to coat the alloy surface with flux.

In the proposed method, it is possible to weld the alloys using only a single melting bath with a solid-liquid alloy. As a result, the costs of purchasing, installing and

operation of the main equipment, simplified axial and auxiliary equipment, increases the productivity of surfacing by increasing the thickness of the resulting layer by 5–50 times per load into the melt.

Forms in Ji and inventions

A method of manufacturing bimetallic products, including maintaining the temperature of the alloyed alloy constant in a protective gaseous medium, immersing the billet in {melted alloy and cooling the billet coated with an alloy layer before re-diving it, characterized in that, in order to simplify the process of surfacing, the alloyed alloy is brought to the solid state, and the billet with the deposited alloy layer is cooled to a temperature equal to 0.8-0.9 the solidus temperature of the alloyed alloy.

Sources of information taken into account in the examination

. Maksimovich B.I. and others. Surfacing with a molten filler alloy 37-42.

2. Japanese patent N 16962, class 12 A 22, 1972