EP1532281A1

EP1532281A1 - Cooling plate for metallurgic furnaces

Info

Publication number: EP1532281A1
Application number: EP03792197A
Authority: EP
Inventors: Wilhelm Stastny; Herbert Scharinger; Walter Rainer Kastner
Original assignee: Voest Alpine Industrienlagenbau GmbH; Siemens VAI Metals Technologies GmbH and Co
Current assignee: Primetals Technologies Austria GmbH
Priority date: 2002-08-20
Filing date: 2003-07-14
Publication date: 2005-05-25
Anticipated expiration: 2023-07-14
Also published as: PL374577A1; ZA200501130B; WO2004018713A1; AT6277U1; JP4358109B2; MXPA05001866A; KR20050050092A; DE50311974D1; AU2003250046A1; UA77849C2; RU2309351C2; RU2005107719A; US20050218569A1; EP1532281B1; DE20213759U1; TWI265197B; US7537724B2; ATE444378T1; EP1391521A1; AU2003250046B2

Abstract

The invention relates to a cooling plate (1,16) made of copper or a low-alloy copper alloy for metallurgic furnaces provided with high-strength sheet steel (2) on the outside of the furnace . Said cooling plate has at least one, preferably at least two, coolant channels which extend inside the cooling plate (1,16), whereby coolant tube pieces used for feeding the coolant and discharging said coolant extend through the high-strength sheet steel (2) of the furnace and are guided in an outer direction. Retaining tubes are arranged on the cooling plate (1,16) and are provided with retaining disks which are arranged outside the high-strength sheet steel (2) of the furnace and which fix the cooling plate (1,16) in the direction of the inside of the furnace. The retaining tubes and retaining disks are preferably made of steel.

Description

Cooling plate for metallurgical furnaces

The invention relates to a cooling plate, consisting of copper or low-alloy copper alloy, for metallurgical furnaces provided with an outer furnace armor plate, with at least one, preferably at least two, coolant channels running inside the cooling plate, with coolant pipe pieces for the coolant inlet and outlet through the furnace armor plate are led outside.

Such cooling plates are arranged between the jacket and the lining and connected to a cooling system. On the side facing the inside of the furnace, the cooling plates are partially provided with refractory material.

A cooling plate is known from DE 39 25 280, in which the cooling channels are formed by pipes cast in cast iron. The support nose is also connected to the cooling system. These plates have a low heat dissipation due to the low thermal conductivity of the cast iron and because of the resistance between the cooling tubes and the plate body, caused by an oxide layer or an air gap.

If the blast furnace masonry is lost after a certain period of operation, the inner surface of the cooling plates is directly exposed to the furnace temperature. Since the furnace temperature is far above the melting temperature of the cast iron and the internal thermal resistance of the cooling plates leads to insufficient cooling of the hot plate side, accelerated wear of the cast iron plates is inevitable and the service life is limited accordingly.

DE 199 43 287 A1 discloses a copper cooling plate which is fixedly connected to the furnace shell near the upper coolant pipe sections by means of a fixed point fastening element. In addition, the upper coolant pipe sections are also permanently connected to the furnace shell. Other fasteners are designed as Lospunkt fasteners that allow mobility in both the horizontal (x) and vertical (y) direction. The lower coolant pipe sections are only gas-tightly connected to the furnace shell by means of conventional compensators. In this area, the cooling plate is therefore not fixed in any of the three spatial directions.

Due to the fact that the side of the cooling plate facing the inside of the furnace reaches temperatures of more than 300 ° C and that facing the furnace Side remains on coolant temperature, i.e. about ambient temperature, the cooling plate is exposed to very large thermally induced stress forces. In the cooling plate of DE 199 43 287 A1, this leads to the fact that the plate, which is completely fixed in several places, plastically deforms under the influence of temperature and bulges into the interior of the furnace when cooling. This results in cracks in the coolant pipe sections and coolant outlet.

Compared to the prior art, the object of the invention is to provide a cooling plate in which such a bowl-like deformation is no longer possible and in which therefore no stress-related cracks occur in the coolant tube pieces.

This object is now achieved according to the invention in that the cooling plate is provided with holding tubes which are guided through the furnace armor sheet to the outside and which are provided with fastening elements, in particular holding plates or holding disks after being carried out through the furnace armor plate, and wherein the holding tubes and the fastening elements are made of are made of a material which has an increased strength compared to copper or low-alloy copper alloy.

The cooling plate according to the invention can be moved at the positions of the holding tubes both in the vertical (y) and in the horizontal (x) direction, while a movement in the z direction, that is to say "encryption" in the direction of the interior of the furnace, of the fastening elements attached to the holding tubes, which are supported against the outside of the furnace shell.

Any tensions in the z direction that occur nevertheless are not carried - as in the prior art - by the unsuitable copper coolant pipe pieces, but by the holding tubes and fastening elements made of a much more suitable material.

The material specifically preferred for the holding tubes and fastening elements is steel, possibly also stainless steel. In principle, however, any material is suitable, provided that it fulfills the requirement of a strength that is significantly higher than that of copper or low-alloy copper alloy, as is the case with steel. Also preferred is a material that is at least weldable to itself and preferably can also be welded with copper or low-alloy copper alloy, which is also the case with the particularly preferred material steel.

According to an advantageous embodiment, the cooling plate according to the invention is connected in a central area to the furnace shell by a fixed point fastening element.

Such a fixed point fastening element can, for example, be a fastening bolt and fixes the plate at this point in each of the three spatial directions.

As a result, the cooling plate according to the invention is fixed in its position and cannot be moved from this position as a whole by thermally induced stressing forces. Thermal expansion of the plate, however, is still possible from this central fixed point without restriction.

According to a further advantageous embodiment, the cooling plate - in particular with a height / width ratio of the cooling plate of 3 3 - is provided with at least one loose point fastening element which is arranged above and / or below the fixed point fastening element and which only allows mobility in the vertical direction.

As an alternative to this, the cooling plate - in particular with a height / width ratio of the cooling plate of <3, preferably <2 - with at least one loose point fastening element arranged to the left and / or right of the fixed point fastening element, which only allows mobility in the horizontal direction, Mistake.

Such a loose-point fastening element can, for example, be a fastening bolt with a washer, the washer being welded to the furnace armor plate and being able to slide in one direction in a guide, and, depending on the orientation of the fastening element, fixes the plate either in x- or in y- Direction, but in any case in the z direction.

In addition to the fixation achieved by the central fixed point, both of the variants mentioned ensure that the cooling plate is not only merely fixed in its overall position, but that the cooling plate is also secured against twisting caused by thermally induced stressing forces. Furthermore, one Thermal expansion of the plate freely possible in the directions permitted by the loose point fastening elements.

A particularly preferred embodiment of the cooling plate according to the invention consists in that it has webs and grooves on the side facing the interior of the furnace, the webs being segmented in their longitudinal direction.

The webs are the part of the cooling plate which is least exposed to the cooling effect of the coolant. The webs therefore reach the maximum temperature of the entire cooling plate (the above-mentioned about 300 ° C). By dividing the webs into individual sections, the tensile forces caused by the thermal expansion of the webs are reduced to the minimum possible. The subdivision of the webs would also be taken on its own in cooling plates known from the prior art as a suitable means of reducing the "encryption" of the cooling plates and significantly increasing the service life of the cooling plates, in particular of the coolant tube pieces.

In order not to impair the mechanical strength of the entire cooling plate, it is preferred that the segmentation of the webs is carried out as cuts arranged essentially at right angles to the webs.

These cuts are preferably also carried out in such a way that they are not arranged above but between the coolant channels. If there are any cracks, the risk of tearing into the coolant channels can be reduced.

In order not to impair the load-bearing capacity of the webs, which usually run horizontally, it is preferred that the segmentation of the webs be carried out in such a way that the individual segments are offset from one another in the horizontal direction.

Various other embodiments relate to the detailed design of the holding tube, fastening element and coolant tube piece. These special embodiments are the subject of claims 6 to 12.

In principle, it is preferred that a holding tube surrounds a coolant tube piece, that is to say that a holding tube is guided outwards through the furnace shell and a coolant tube piece is in each case guided inside the holding tube through the furnace shell. The type of connection between the holding tube and the cooling plate or between the coolant tube piece and the cooling plate or even between the holding tube and the coolant tube piece can be different.

According to a first and preferred variant, a disk-shaped connecting piece is welded to the holding tube surrounding the coolant tube piece and this connecting piece is screwed onto the cooling plate. The coolant pipe section is welded to the cooling plate.

According to a second variant, the holding tube surrounding the coolant pipe section is welded directly to the cooling plate, and the coolant pipe section is also welded to the cooling plate.

According to a further variant, a disk-shaped or ring-shaped connecting piece is inserted between the coolant pipe piece and the holding pipe. The coolant pipe section and the holding pipe rest on this connecting piece. The connection between the connecting piece and the cooling plate, on the one hand, and between the connecting piece and the coolant pipe piece or holding tube is preferably made by welding.

According to a further variant, the coolant tube piece is made in one piece and provided with a flange, which flange is attached to the cooling plate. The holding tube surrounds the coolant pipe piece, is placed on this flange and is attached to it by welding.

According to a further variant, a holding tube is also designed as a coolant tube piece, with both functionalities, i.e. the coolant supply and discharge and the holding function are carried by this one piece of pipe.

With the exception of the last-mentioned variant, in all of the embodiments the coolant tube pieces can either be made from the same base material as the cooling plate or another, preferably the material of the holding tube.

This option does not exist for the latter variant, here the coolant tube is at the same time also a holding tube and is therefore in any case made from the material of the holding tube.

The invention is explained in more detail below in the drawings in FIGS. 1 to 9. Fig. 1: Two-channel cooling plate

Fig. 2: Four-channel cooling plate

Fig. 3: arrangement of several cooling plates

Fig. 4: Segmentation of a four-channel cooling plate

Fig. 5-9: Different holding tube designs

Fig. 1: shows a two-channel cooling plate 1, which is attached to a furnace sheet 2. The cooling plate consists of copper and has webs 3 on the side facing the furnace interior. The space between the cooling plate 1 and furnace sheet 2 is backfilled with refractory material. Further cooling plates 1 'are arranged above and below and - not shown - to the side of the cooling plate 1. The cooling plate 1 is provided with vertical cooling channels 5, which are designed as blind bores of the cast or rolled plate body. At the upper and lower ends of each cooling channel 5, coolant pipe pieces 6 for the supply and discharge of coolant (usually water) are guided through the furnace shell 2. For each coolant pipe section 6 - surrounding this - a holding tube 7 is also guided outwards through the furnace shell. The holding tube 7 is welded to a disk-shaped connecting piece 8, which in turn is fastened to the cooling plate 1 by a screw connection 9. Outside the furnace shell 2, the holding tube 7 is provided with a welded-on holding disc 10, which limits the mobility of the cooling plate 1 in the direction of the furnace interior. The holding tube 7 and the coolant pipe section 6 are connected to the furnace armor plate 2 in a gas-tight manner by means of a conventional compensator 11. In the middle of the cooling plate 1, this is fixedly connected to the furnace armor plate 2 by means of a fixed point fastening 12 designed as a fastening bolt. The fixed point fastening 12 is welded gas-tight to the furnace armor plate 2. Loose point fastenings 13 are arranged above and below the fixed point fastener 12. The loose point fastenings 13 are also designed as fastening bolts, but these are not welded to the furnace shell 2 in a gas-tight manner, but can slide up and down in a guide 14. To seal against the interior of the furnace, sealing hoods 15 are attached above the loose point fastenings 13.

FIG. 2 shows a four-channel cooling plate 16 which, with the exception of twice the number of cooling channels 5, is largely identical to the cooling plate 1 shown in FIG. 1. However, due to the different height / width ratio, the loose point fastenings 13 are not above and below the fixed point fastener 12 attached, but to the side of it. The guides 14 of the loose point fastenings 13 are arranged in such a way that sliding in the horizontal direction is possible.

3 schematically shows the arrangement of two-channel cooling plates 1 and four-channel cooling plates 16 in an oven. Also shown is the coordinate system, which illustrates the x, y and z directions to which the text has repeatedly referred.

4 shows the webs 3 of the cooling plate 16 which are segmented in the horizontal direction. The individual segments are each approximately the same size and offset in the horizontal direction by approximately half their length.

5 shows an enlarged representation of the preferred variant of the embodiment according to the invention of holding tube 7, coolant tube piece 6 and the attachment of connecting piece 8 by means of screw connection 9 on cooling plate 1.

The embodiment shown in FIG. 6 differs from that shown in FIG. 5 in that the connection between the holding tube 7 and the cooling plate 1 is produced by welding.

FIG. 7 shows an embodiment in which both the holding tube 7 and the coolant tube piece 6 are fastened on the connecting piece 8.

8 illustrates a one-piece coolant pipe section 6 provided with a flange, the holding tube 6 also being fastened to this flange.

Fig. 9 shows a special form. On a welded with the cooling plate 1 annular connector 8 is a welded with this pipe section 17, the raw piece 17 is made of the material of the holding tubes, for example steel, and due to the - compared to copper - higher strength at the same time as a coolant tube piece and as Holding tube is used.

In all of the drawings FIGS. 5 to 9, holding disks 10, which are attached directly outside the furnace shell 2 and welded to the holding tubes 7, 17, fix the respective cooling plate 1 in the z-direction to the interior of the furnace.

Claims

claims

1. cooling plate (1, 16), consisting of copper or low-alloy copper alloy, for metallurgical furnaces provided with an outer furnace armor plate (2), with at least one, preferably at least two, coolant channels (5) running inside the cooling plate (1, 16) , wherein coolant pipe sections (6) for the coolant inlet and outlet are led through the furnace armor plate (2) to the outside, characterized in that the cooling plate (1, 16) is provided with holding tubes (7) which are passed through the furnace armor plate (2 ) are guided to the outside and which are provided with fastening elements (10), in particular holding plates or holding disks, after being carried out through the furnace shell (2), and the holding tubes (7) and the fastening elements (10) are made of a material which is a has increased strength compared to copper or low-alloy copper alloy.

2. Cooling plate (1, 16) according to claim 1, characterized in that it is connected in a central area by a fixed point fastening element (12) to the furnace shell (2).

3. cooling plate (1, 16) according to claim 2, characterized in that - in particular with a height / width ratio of the cooling plate (1, 16) of ≥ 3 - with at least one above and / or below the fixed point fastening element ( 12) arranged loose point fastening element (13), which only allows mobility in the vertical direction, is provided.

4. Cooling plate (1, 16) according to claim 1, characterized in that it - in particular with a height / width ratio of the cooling plate (1, 16) of <3, preferably <2 - with at least one to the left and / or right next to it the fixed point fastening element (12) arranged loose point fastening element (13), which only allows mobility in the horizontal direction, is provided.

5. Cooling plate (1, 16) according to one of claims 1 to 4, characterized in that it has webs (3) and grooves on the side facing the interior of the furnace, the webs (3) being segmented in their longitudinal direction.

6. Cooling plate (1, 16) according to one of claims 1 to 5, characterized in that a holding tube (7) - each surrounding a coolant tube piece (6) - on the cooling plate (1,16) attached, for example screwed or welded ,

7. cooling plate (1,16) according to any one of claims 1 to 6, characterized in that a preferably annular or disc-shaped connecting piece (8) between the holding tube (7) or coolant tube piece (6) is provided.

8. Cooling plate (1, 16) according to one of claims 1 to 5, characterized in that a coolant tube piece (6) is made in one piece and is provided with a flange, which flange is attached to the cooling plate (1,16).

9. cooling plate (1, 16) according to claim 8, characterized in that a

Holding tube (7) - surrounding the coolant pipe section (6) - is attached to the flange.

10. Cooling plate (1, 16) according to claim 1 to 9, characterized in that the pipe pieces (6) for the coolant inlet and outlet are made of the same material as the cooling plate (1, 16).

11. Cooling plate (1, 16) according to claim 1 to 5, characterized in that a pipe section (17) is designed as a holding tube (7) as well as a coolant pipe section (6).

12. Cooling plate (1, 16), according to one of claims 1 to 9, characterized in that the tube pieces (7, 17) for the coolant inlet and outlet are made of the same material as the holding tubes (7).