SU1152095A1 - Submerged-resistor induction furnace - Google Patents

Abstract

INDUCTION CHANNEL OVEN, containing a bath and an induction unit located under it, the channels of which are made of two branches located at an acute angle to one another and at the intersection of those combined into a common channel, characterized in that, in order to increase the furnace productivity by increasing the intensity transit flow through the channels, the channels are made with a uniform cross-section along the entire length, the height of the common channel is 1.0-4.0 of the height of the branches. and the specified acute angle is 10-45.

Description

This invention relates to electrical engineering, in particular to induction duct furnaces. A necessary condition for further improvement of the technical parameters of furnaces of this type (power, productivity) is the creation of intensive through metal movement through the channel, which allows minimizing overheating of the metal in the channel. A known induction channel furnace containing a bath and a single induction unit with two channels l. The disadvantage of this furnace is the absence of through movement through the channel, as a result of which the effective transfer of thermal energy from the channel to the bath is not ensured. Closest to the invention is an induction channel furnace containing a bath and located under it. an induction unit whose channels are made of two branches spaced at an acute angle to one another and at the intersection combined into a common channel 2. However, since the channels in the known furnace are irregular in cross section, vortices are formed at the intersection of the branches transit metal flow. The aim of the invention is to increase the productivity of the furnace by increasing the intensity of transit flow through the channels. The goal is achieved by the fact that in an induction channel furnace containing a bath and an induction unit located under it, the channels of which are made of two branches located at an acute angle to one another and at the intersection of the common channel, the channels are made with a uniform cross-section The height of the common channel is 1.0–4.0 of the heights of the branches, and this angle is 10–45 °. When channels with a ratio of heights lower than 2 are made, their nepe section is stepped. FIG. 1 and 2 show the structure of an induction channel furnace; FIG. 3 - lower channels distribution of electromagnetic forces acting on the metal of the lower channels, and the trajectory of the hydrodynamic flows of the metal at the junction of channels 952 The furnace contains a bath 1 and a single induction unit 2 connected to it, containing inductor 3 located on the magnetic core 4, two lower channels 5, located one from another at an angle cL, the combined channel 6 with height p and two vertical channels 7 with height b. Making the U-shaped channels allows easy cleaning of the vertical channels during their overgrowing with non-metallic inclusions during the smelting of aluminum alloys and using reusable templates for forming the channels in the lining of an induction unit. The furnace works as follows. When connecting the furnace to the network, the induced electric current flows through the channels. Electromagnetic forces F act on the metal in the lower channels, which are located relative to each other at an angle, and in the transition zone of the lower channels into the combined vertical metal. As a result, hydrodynamic vortices A and B appear in the transition zone, creating tractive force T. The metal is driven by the pull force in the V direction from the joint channel to the lower, side and into the furnace bath. The table shows the transit flow rates obtained on the furnace model with equal power output for different values determining flow intensity, design parameters.

Table continuation

The obtained results show that there is a stable transit flow in the claimed area, and it is very weakly expressed beyond the boundary of this area (experiments 1, 6, 10). Thus, the claimed design parameters region is optimal.

 The use of the invention will make it possible to increase the power of an induction furnace more than twice with an increase in its service life.

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Claims (1)

INDUCTION CHANNEL FURNACE containing a bathtub and an induction unit located below it, the channels of which are made of two branches located at an acute angle to one another and at the intersection point united into a common channel, with the following: in order to increase the productivity of the furnace by increasing the intensity of the transit flow through the channels, the channels are made with a uniform cross section along the entire length, the height of the common channel is 1.0-4.0 the height of the branches, and the specified acute angle is 10-45.