SU1749673A1 - Monolithic roof of arc furnace - Google Patents

Abstract

The essence of the invention: arch 1 is made of monolithic concrete and has 5 radial and concentric 6 stiffeners, which allows to reduce the wall thickness of the roof and increase the resistance of the roof to cutting changes in temperature gradient over the cross section of the roof. To protect the roof 1 from the heat effect of the furnace temperature, the roof is protected by a screen 7 made of printed plastic clay, which is attached to the roof 1 by means of anchors. In the places of attachment of the screen and the roof there are gaps equal to the maximum thermal expansion of the refractory material of the roof 1 and screen 7 at the maximum temperature of the furnace. 2 h. apt. 4 il.

Description

The invention relates to ore recovery furnaces and can be applied in heating furnaces.

The aim of the invention is to increase the durability and service life of a monolithic arch of an arc furnace.

To do this, in the monolithic arch of the arc furnace, which contains a central part with holes for electrodes, a peripheral part and protrusions on its surface, the arch is equipped with a suspended ramming screen, anchors for attaching the screen to the arch, metal cups and concrete plugs, and the protrusions are made in the form of radial and concentric stiffeners with sockets in which glasses with concrete plugs are installed for fastening the anchors, with the central part protruding protruding above the peripheral part.

Suspended. The screen has cylindrical projections at the locations of the anchors.

Nests, metal cups and concrete plugs are made in the form of a truncated cone.

FIG. 1 shows the proposed arch, top view; in fig. 2 shows section A-A in FIG. one; in fig. 3 - node I in FIG. 2; FMG 4 - section BB in FIG. 3

Monolithic roof 1 comprises a central part 2 with openings for electrodes 3, peripheral part 4 and protrusions 5 and 6 on its surface.

The center portion 2 extends above the peripheral portion 4.

The arch 1 is provided with a pendant screen printed 7, anchors 8 for fastening the screen 7 to the arch 1, metal cups 9 and concrete plugs 10

The projections 5 and 6 are made in the form of radial 5 and concentric 6 stiffeners with slots 11, in which glasses 9 are installed with concrete plugs 10 for fastening the anchors 8.

Nests 11, metal cups 9 and concrete plugs 10 are made in the form of a truncated cone.

The suspended screen 7 has cylindrical protrusions 12 at the locations of the anchors 8.

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Monolithic vault works as follows.

During the smelting process, an electric arc is formed between the electrodes 3 and the ore, the temperature of which instantly affects the suspended screen 7.

Screen 7 perceives the heat load, protecting the roof 1 from the effects of the arc.

As a result of the smelting of charge materials, furnace gas is formed. Due to the movement of the furnace gases, the screen 7 is heated on both sides, which aligns the temperature gradient over the cross section of the screen 7.

Thus, the inner surface of the roof 1 is protected from the influence of the temperature of the arc and the molten material by the screen 7 and the circulating kiln gases, which also shield the thermal effect of the furnace on the roof 1.

In the initial period of melting, the temperature of the furnace gases is low and this contributes to the gradual heating of the roof 1. Further heating of the roof 1 by the furnace gases contributes to a uniform distribution of the isotherms of the temperature field over the cross section of roof 1, which significantly reduces the stresses.

The resulting thermal stresses over the cross section of the screen 7 are reduced due to the free movement of the screen 7 on the anchors 8 attached to the roof 1 with metal cups 9 and concrete plugs 10 in the slots 11.

The design of the roof 1 and the suspension screen 7 during the operation of the furnace is less subject to thermal stress, prevents the formation of cracks and increases the service life of the roof.

The use of a ramming suspended screen 7 makes it possible to reduce the temperature of the roof 1, which makes it possible to produce roof 1 monolithic of refractory concrete and, moreover, to the damaged areas of the hot screen 7 during the period between melts

can be applied gunning, which increases the service life of the screen 7 and increases the efficiency of the furnace.

The use of radial 5 and concentric 6 ribs allows reducing the thickness of the peripheral part 4 and the mass of the roof 1 while maintaining the strength of the latter. The number of stiffeners 5 and 6 is determined by calculation from the condition

strength of the vault 1 and screen 7 with specific Measures of a particular furnace.

The use of cylindrical protrusions 12 allows you to protect the anchors 8 from the effects of furnace gases and temperature

corrosion and increase their service life, in addition to using the cylindrical protrusions 12, a guaranteed gap is established between the inner surface of the roof 1 and the screen 7, which increases the screen effect.

Claims (3)

1. The monolithic arch of the arc furnace, containing the central part with holes for the electrodes, the peripheral part and protrusions on its surface, characterized in that, in order to increase durability and service life, it is provided with a pendant ramming screen, anchors for fastening the screen to the roof, with metal cups and concrete plugs, and the protrusions are made in the form of radial and concentric stiffeners with sockets, which are equipped with glasses with concrete plugs for fastening anchors, moreover, the central part is made protruding above the peripheral part. 2. An assembly according to claim 1, characterized in that the suspension screen has cylindrical projections at the locations of the anchors, 3. Code according to claim 1, characterized in that the sockets, metal cups and concrete plugs are made in the form of a truncated cone. ;;  5 6  | H / H l g T I ysN. jl "iWLJ.IJJiJ -1 Ml" J I Wyily. Vx.1 w / w %% t AND . "2f v v5 Fi.Z FIG A