DE2003039B2 - WINDER HEATER FOR BIG STOVE - Google Patents

Description

45

The invention relates to a wind heater for blast furnaces, containing a shaft made of refractory Masonry which is surrounded by a metal jacket and in which between the refractory masonry and the metal jacket an additional layer through a partition into a combustion chamber and a heating chamber, which contains a latticework of fire-resistant fabric, is divided, and the one on the outside with Metail has a protected dome made of fireproof masonry, under which the two chambers are connected to each other Stone connection.

In the German patent application V 2321 24c, 5/01, published on October 15, 1953, a Wind heater with a brick layer of insulation between the outer shell and the inner one Refractory masonry described, in which the insulation of the dome and the mantle in the thermotechnical Meaning is formed continuously and independently of the refractory masonry.

The entire content of this prior publication, including the figure shown there, shows that next to the metal dome, which is lined with an insulating layer, a separate dome made of fireproof Masonry is in place. This refractory masonry dome rests on top of the refractory masonry of the shaft so that the solid masonry of the shaft is loaded with the weight of the dome, as a result of the inevitably occurring temperature fluctuations (heating of the heater, cooling of the masonry when the air is heated) the masonry loses its mechanical strength.

In the case of the well-known wind heater, the insulating lining of the metal dome rests - not the fireproof one Masonry of the dome - on the insulating lining of the metal shell. In a special design can between the insulating layer of the metal dome and the subsequent insulating layer of the sheet metal jacket a support ring for the Insulating layer of the dome may be provided. This is supposed to be a particularly good way to get around the to ensure a self-supporting arrangement of the insulation of the dome.

Other well known blast furnace blast heaters also contain a cylindrical shaft, the walls of which are made of refractory bricks. From the outside the shaft has a metallic one A coat. A dome rests on the shaft walls, which are lined with refractory bricks and with a metallic coat is covered. The shaft is full height to the base of the dome a brick partition of a cylindrical shape divided into two chambers. One of the chambers lies outside the cylinder formed by the partition, the other inside this cylinder. the the latter is equipped with a burner / to burn gaseous fuel and stands with the former (under the dome) and in connection with the furnace. The former contains a latticework refractory material supported on a substructure, which is equipped with air fans and with the Communicates smoke vent. The work of the stove is characterized by two stages. The first The stage is the heating of the latticework by burning the fuel in the combustion chamber and Passing the combustion products through the latticework. After that, the combustion products get into the smoke vent. The second stage is the forcing of air through the latticework and the combustion chamber, whereby the air is heated. The heated air then enters the blast furnace. It is understandable that the Air temperature should be as high as possible. However, physical properties of the stones represent, with which shaft, partition and dome are bricked, a limitation in the fulfillment of these Condition. As the masonry is exposed to periodic heating and cooling, enlarge and the dimensions of the shaft walls decrease periodically.

The dome resting on the shaft introduces a shift synchronously with the shaft walls by and the same size, damaging their masonry. The hot gases heat up by them penetrate through cracks in the dome and gaps between the stones, the metallic dome jacket a temperature that will damage the dome.

To avoid the difficulties mentioned, the masonry of the heater is ^{made of firebricks from the base up to 2} Λ of its height and higher from high-alumina refractory material.

However, the Luftttemperatur should not exceed, otherwise the high-alumina refractory material loses its mechanical strength 1,200 ⁰ C and in this embodiment of the masonry.

The use of Dmasstein, which can ^{withstand a temperature of 1400 0} C and more, is impossible because the Dinas brick loses its mechanical strength under the action of the dome weight at 67O ⁰ C, which occurs when the heater is cooled by cold air while it is being heated.

The purpose of the invention is to eliminate the difficulties mentioned.

The invention is based on the object of creating a blast furnace and its construction Creates conditions for the use of Dinasstein or any other fire-resistant material that is under Load does not tolerate cooling down to relatively low temperatures.

In order to achieve this object, the air heater of the type specified at the outset is characterized in accordance with the invention characterized in that the dome rests on the masonry forming the additional wall.

The additional wall is exposed to lower temperatures than the shaft walls and is thus not exposed to the relatively large deformations. In addition, the additional wall isolates the High temperature zone of the shaft from the relative cool atmospheric air that surrounds the heater.

In the preferred variant of the heater, the additional wall serves as a support Cantilever pieces that are arranged in a belt shape and attached to the metallic jacket, the jacket in Height of the cantilever belt is girdled with bandages. The bandages increase the strength of the support the additional wall.

The distance from the cantilever pieces to the base of the heater is expediently about ^{2 of} its height. With this arrangement of the cantilever pieces, the height of the additional wall is sufficient. that this wall can fulfill its functions mentioned above.

To eliminate the friction of the additional wall on the shaft masonry and the metallic The jacket and for better insulation are useful between the additional wall, the shaft masonry and the metallic jacket gaps are provided.

These gaps can be filled with shredded refractory material.

A uniform temperature distribution at the fastening point of the cantilever pieces can be achieved Achieve heat dissipation at the cantilever pieces proportional to the inflowing heat. To do this, be expedient Channels are provided in the cantilever pieces that communicate with a liquid or air cooling system.

The main advantage of the present invention is that it succeeds, in addition to considerable Increase the life of the heater (not less than by 5 years) the air to one temperature to be heated from 1300-1700 ° C.

Below is a detailed description of a preferred embodiment of the blast furnace according to the invention with reference to drawings; in the drawings shows

F i g. 1 is a schematic representation of the inventive concept Heater in vertical section,

45 Fig. 2 the upper part of the heater in vertical section (enlarged),
Fi g. 3 shows a section according to IH-III from FIG. 1.
The heater contains a cylindrical shaft

1 (Fig. 1,2 and 3) projecting from the base surface up to its height Vj of firebricks and in the upper part is made of Dinassteinen. A jacket 2, which consists of sheet steel, is attached to the outside of the shaft. At a height that is ² / j of its length, the jacket 2 expands. In the wide jacket part, metallic cantilever pieces 3 are arranged on the inside, which are fastened to the jacket 2 by means of screws (not shown in the drawing). The cantilever pieces 3 adjoin one another, so that a belt is created from these Kragstükken. The distance between the axis of the cantilever pieces and the base of the heater is approximately equal to ² Ii of its height. The coat is at the height of the cantilever pieces

2 surrounded by steel bandages 4. An additional wall 5, which is made of firebricks, is supported on the belt from the cantilever pieces 3 . The thickness of the additional wall 5 exceeds the masonry thickness of the shaft 1 by 20-30%. Between the additional wall 5, the metallic jacket 2 and the masonry of the shaft 1, gaps are provided to avoid friction in the course of temperature deformations.

These columns are divided equally in height with the aid of shelves 6 made of porous Dina stone divided. The shelves represent protruding parts of the masonry of the shaft 1 and the additional Wall 5 represents. Crushed kaolin is poured between the shelves 6. The kaolin improves that Insulation of the heater.

On the additional wall 5 is a dome 7, which is made of dinosaur stones. Between the Masonry of the dome 7 and the metallic jacket 2, which acts as a common jacket for the dome and shaft a gap is provided to improve the dome insulation.

The arrangement of the additional wall 5 on the outside of the masonry of the shaft 1 prevents an intensive Heat flows to this wall from the high temperature zone of the heater and reduces heat dissipation from the heater to the atmosphere. The working conditions of the heater become essential lent improved, which enables the use of Dinasstein.

Because the additional wall is exposed to lower temperatures than the shaft masonry exposed, it is slightly deformed, which is why the dome placed on the additional wall rests on, does not experience any destructive deformations.

The shaft 1 contains a cylindrical partition 8, which consists of firebricks up to a height which is ² Zj of the entire height, and of silicate bricks in the remaining part. The partition wall encloses a combustion chamber 9, on the base of which a burner 10 is arranged. Under the dome 9 is the combustion chamber with the air heating chamber 11 in connection which is filled with a lattice-work 11 a, that is up to _^2/3 of the height of fireclay and in the upper part made of Dinassteinen. The latticework is based on a substructure 12 of known construction. The gas-air mixture is fed to the burner 10 from a corresponding system (not shown in the drawing) with the aid of a connector 13.

The combustion chamber 9 communicates with the blast furnace (not shown in the drawings) with the aid

a nozzle 14. The substructure 12 stands with the help of a Connection 15 with the air blower and with the help of a connection 16 with the smoke outlet (from the drawings not visible) in connection.

For uniform temperature distribution in the cantilever pieces 3, channels 17 are present in these with a system (not shown in the drawings) for cooling the cantilever pieces by liquid or gaseous medium are connected. The liquid cooling system of the blast furnace can serve as this system.

The heater works as follows: the connection pieces 14 and 15 are closed and the connection pieces 13 and 16 are open (shut-off devices are not shown). The gas-air mixture is fed through the nozzle 13 to the burner, where the gas is burned. The combustion products rise in the combustion chamber 9, are deflected under the dome 7 and go down on the latticework 11a, where they heat this. The combustion products migrate from the latticework into the substructure 12 and further via the nozzle 16 into the smoke outlet. When the temperature of the latticework ^{has increased to 1500 °} C., the nozzles 1 and 16 are closed with the aid of shut-off devices. Cold air is supplied via the nozzle 15, which in turn the substructure 12, the latticework 11a and the

ίο combustion chamber 9 passes through, where it is heated in order to reach the blast furnace via the nozzle 14. The air temperature rises up to 1300-1400 ⁰ C on. After the temperature of Dinassteine has lowered to 750-800 ⁰ C, sockets 14 and 15 are closed and the open stub 13 and the sixteenth The work cycle of the heater is repeated.

For this purpose 3 sheets of drawings

Claims (6)

Patent address: 1. Wind heater for blast furnaces, containing a shaft made of refractory masonry, the front. one s Metal jacket is surrounded and where between the refractory masonry and the metal jacket an additional layer of insulating material is arranged, in which further the shaft by a Partition in a combustion chamber and a: o heating chamber, which is a lattice work of refractory Contains fabric, is divided, and the one outwardly protected with metal dome made of fireproof Has masonry, under which the two chambers are in communication with each other, thereby characterized in that the dome (7) on the the additional wall (5) forming masonry rests. 2. Wind heater according to claim t, characterized in that as a support for the additional Wall (5) cantilever pieces (3) are used, which are arranged in the shape of a belt and attached to the metallic jacket (2) are, the metallic jacket (2) at the level of the belt consisting of the cantilever pieces (3) through Bandages (4) is held together. 3. Wind heater according to claim 2, characterized in that the distance from the Kragstükken (3) to the base of the wind heater is about ² Zj of its height. 4. Wind heater according to claim 1 to 3, characterized in that between the additional Wall (5), the masonry of the shaft (1) and the metallic jacket (2) column are provided. 5. Wind heater according to claim 4, characterized in that gaps between the additional Wall (5), the masonry of the shaft (1) and the metallic jacket (2) with crushed refractory material are filled. 6. Wind heater according to claim 2 to 5, characterized in that in the cantilever pieces (3) channels (17) are present that have a cooling system communicate.