SU608047A1 - Channel-type induction furnace - Google Patents

Description

(54) INDUCTION DUCT FURNACE

one

The invention relates to the field of metallurgy, in particular, to an induction channel furnace device with remote kiln transformers for melting metal galls with a current penetration depth of less than the channel transverse size, for example, for aluminum smelting in its alloys. .

A well-known induction channel furnace is used for the smelting of predominantly light-colored ferrous metals, containing a crucible and the main magnetic core with exciting winding and additional IJ magnetic cores.

In the BtoSt furnace design, the main magnet line wraps only one main channel and induces up to 60% of all the induced power in it, and the rest of the power is released in the second main and transverse channels and in the furnace bath, i.e. it is distributed unevenly, which limits the power of the furnace transformer and necessitates cleaning the main and transverse channels from oxides, and to reduce overheating of the metal in the channels and increase the power of the furnace floor: the formatter is equipped with additional

ground leads with exciting windings that are not connected with the main magnetic circuit of the furnace transformer.

As a result, the size and weight of furnace transformers increase, the furnace volumetric power and its capacity decrease, the uneven distribution of the induced power in the channels is retained, and it becomes necessary to install additional magnetic cores with excited windings.

C-LY invention is to increase the productivity and operational reliability of the furnace.

This is achieved by the fact that in an induction channel furnace for smelting non-ferrous metals containing a crucible, the main magnetic circuit with the exciting winding and additional magnetic cores, the main magnetic circuit of the furnace transformer is made in the form of an I-beam and equipped with additional L-shaped magnetic cores attached by elongated ends to the shelves I-beam, and their short conc) are directed towards the induction

of the channel, the blendings of the main and additional magnetic pipes are mutually perpendicular.

This makes it possible to evenly distribute the induced Power between the main channels, increase it in the furnace bath and reduce in the transverse channel db magnitude. heat losses to them into the environment

At the same time, the size and weight of the furnace transformer are reduced, the volume power of the penta and its capacity are increased, there is no need to clean the transverse channel from metal oxides.

FIG. 1 shows the proposed furnace, a general view; in fig. 2 Give section A-A in FIG. one; in fig. 3 - view along arrow B.

The induction channel furnace is made of a lined crucible 1 mounted on a turning mechanism 2.

Furnace detachable transformers 3 are tightly fixed to the bottom of crucible 1. The furnace transformer consists of a main magneto line 4, made in the form of an I-beam, on the core 5 of which is located a booster winding 6, with two additional L-shaped magnetic cores 7 attached at the ends to the shelves 8 I-beams, and their short ends are directed towards the induction channel furnace.

The core 4 and additional 7 magnetic cores are arranged mutually perpendicular.

The main 4 and additional 7 magnet wires are mounted on a bracket 9 fixed to the crucible 1 cortus.

In the housing 10 of the furnace transformer 3 with a ramified mass of 11, the main channels 12, which are included in the furnace bath 14, and the next 5 :) common channel 13 are decorated.

The magnetic flux of the furnace transformer penetrates the molten metal of the main channels 12 and the furnace bath 14 through

L-shaped additional magnet wires, while shielding the transverse channel 13, the cross section of which is many times larger than the cross section of the main channels.

As a consequence, almost all inductively. The power is evenly distributed in all the main channels 12 and in the furnace bath 14 and a small part in the transverse channel is not the largest heat loss from the transverse channel.

Due to this reduction in the specific volumetric power in OCHOBHBIX channels 12 and the absence of overheating of the melt in the transverse channel 13, cleaning of the main channels 12 is made easier and cleaning of the transverse channel 13 is eliminated, which ensures the reliability of the furnace.

Reducing the size of the furnace transformer. Due to the size of the magnetic core, it can increase the furnace capacity and performance by 2 2.5 times and reduce the specific power consumption by 20%.

Claims (1)

1. The patent of England No. 1281377, CL.P4B 1972. 45