NL9001555A - COATING STONE OF FIRE-RESISTANT CERAMIC MATERIAL. - Google Patents

Description

COATING STONE OF FIRE-RESISTANT CERAMIC MATERIAL.

The invention relates to a cladding stone of refractory ceramic material, for a wall of a combustion chamber, which is preferably provided with a cooling housing, wherein the stone is provided with a bearing surface, with which the stone rests on a supporting element arranged on the wall and the cooling housing, respectively, in a support direction that is parallel to the chamber-side surface of the stone.

Such a cladding stone is described in EP-0-228 918. The supporting element skew extends upwards on this stone. The bearing surface is formed in the same manner. Due to the skewed support elements, stone must be secured in both vertical and horizontal directions. This securing is problematic since the double function of the support elements can only be achieved if their intended position on the wall or on the pipe is exactly maintained in practice. If the support elements do not run exactly at the intended angle, the support will be worse or the support elements will not fit on the stone.

Applicant's DE-GM 88 09 174 also discloses a cladding stone of the type mentioned in the preamble, in this stone the upper and lower, end faces of the stone are skewed on the surface and the bearing surface is perpendicular to the surface. This ensures that the facing stones can be exchanged individually if the wall bandage is properly secured. Stones are not secured horizontally to the wall or to the cold stores. They are secured only by counter-sliding of the supporting element downwardly adjacent stone.

The object of the invention is to provide the cladding stone of the type mentioned in the preamble which takes place during the supporting, in particular vertical supporting, on the one hand and securing it to the wall or to the cold store on the other hand with different surfaces of the stone.

This object is achieved according to the invention in that at least one profile groove is arranged in the brick of the type mentioned in the preamble, which extends parallel to the direction of support and which is slidable via a wall element or cold store attached to the cold store, which without stops in the direction of support, keep the stone in the direction perpendicular to its chamber-side surface to the wall or to the cold store.

The stone rests in vertical direction with its supporting surface on the support element. In the perpendicular, horizontal direction, the stone is secured to the wall or the cold store by the locking element, which engages in the profile groove. The horizontal lock does not have to take the weight of the stone, since the weight is absorbed by the support element. However, there is no danger of the profile groove breaking open. The bearing surface can simply be shaped in such a way that it supports the weight of the stone without being damaged. Since the functions of the support and securing have thus been taken over by different surfaces, namely the bearing surface and the profile groove, it is easy to adapt the bearing surface or the profile groove to the current conditions independently of each other.

The length of the profile groove ensures that the locking element is free in the vertical direction. It is not necessary to pay vertical attention to the exact position of the securing element on the wall or cold store.

The locking element keeps the stone tight against the cooler. This is favorable for the heat transfer from the stone to the cold store.

The end faces of the stone may be perpendicular to the room-side surface or skewed thereon. Since the support and securing is independent of the profile of the end faces, their profile can be chosen so that dust or aggressive components of the gas flowing through the combustion chamber get as little as possible between the stones. According to an embodiment of the invention, the profile groove and the bearing surface are each arranged on a partial cylindrical surface for close contact with the cold store.

According to another embodiment of the invention, the stone comprises two parallel profile grooves and the bearing surface lies between the two profile grooves. This also ensures good locking in the horizontal direction with a relatively large slab-shaped stone. Even if one of the locking elements is ineffective, the stone is still held securely.

other advantageous embodiments of the invention are apparent from the subclaims and from the following description of an exemplary embodiment. In the drawings: figure 1 shows a view of the cladding stone, figure 2 shows a top view of the cladding stone according to line II-II of figure 1 to a cold store of a combustion chamber wall, and figure 3 shows a view of the stone in the direction of arrow III in figure 1 to the cold store of a combustion chamber wall.

Cold stores 2 run along a combustion chamber wall 1. These are shielded from a combustion chamber 4 by bricks 3, one of which is shown in the figures. The cooling housings 2 are thereby shielded from heat from the combustion chamber 4 and from chemical influences from the gases from the combustion chamber 4.

The bricks 3 consist of a refractory ceramic material, for example based on alumina-silica, silicon carbide or a silicon-bonded silicon carbide. The bricks 3 are cooled by the cold stores 2.

The brick 3 comprises a flat, chamber surface 5. On the opposite surface, the brick 3 is provided with cylindrical cylindrical surfaces 6, 7, 8. Their radius of curvature corresponds to the radius of curvature of the cold store 2 such that the stone 3 with the surfaces 6, 7, 8 closely against the relevant cooling pipe 2 (see figure 2). In the exemplary embodiment, the brick 3 extends over three cold stores 2. In a corresponding manner, three-part cylindrical surfaces 6, 7, 8 are arranged.

The upper end faces 9 and the lower end faces 10 are skewed on the chamber-side surface 5 (see figure 3).

In the region of the middle surface 7, the stone 3 has a recess 11. It is open backwards with respect to the surface 7 and downwards with respect to the end face 10. It forms a support surface 12 which extends perpendicularly to the chamber-side surface 5. In the area of the surfaces 6, 8, the stone 3 is provided with profile grooves 13 and 14. The profile groove 13, 14 is open at a slot 15 to the surfaces 6 and 8, respectively. the stone 3 is the profile groove 13, 14 wider than the slot 15. As a result, the locking surfaces 16 are formed. The profile grooves 13, 14 run parallel to each other and perpendicular to the plane in which the bearing surfaces 12 lie. The profile grooves 13, 14 are open at the upper end faces 9. At the bottom they end in a recess 17 and 18, respectively, which is also designed as the recess 11. Between the recesses 17, 11, 18 there are strips 19 which bound the recesses 17, 11, 18 laterally.

A plate-shaped support element 20, which is approximately the size of the supporting surface 12, is attached to the middle cooling housing 2. With the support surface 12, the stone stands inverted V on the support element 20 O-.

T-shaped securing elements 21 are attached to the two outer cold stores 2 (see figure 2). These engage via the slot 15 in the profile grooves 13, 14. They lie against the locking surfaces 16 and lock the stone 3 in horizontal direction H with its partial surfaces 6, 7, 8 closely against the cooling houses 2.

The locking elements 21 are considerably shorter in vertical direction than the profile grooves 13, 14.

The brick 3 can be easily attached to the cold stores 2. For this purpose it is placed with its recesses 17, 18 on the locking elements 21 of the respective cold stores 2 and then moved downwards. Deburring elements 21 then engage in the profile grooves 13, 14.

The stone is then moved further downwards until its supporting surfaces 12 are supported on the support element 20. The stone is thereby supported in the vertical direction V by the support element 20 and is held in the horizontal direction H by the locking elements 20 closely against the cold stores 2.

The stone is suitable for installation on cooling houses that run horizontally or with respect to the vertical direction V. The end faces 9, 10 can be designed in such a way that gases or dust can penetrate as little as possible between the end faces of adjacent stones. Adjoining bricks 3 can also be fixed to the cold stores 2 with respect to one another.

Claims (9)

1. Cladding stone of refractory ceramic material, for a wall of a combustion chamber, which is preferably provided with a cold store, wherein the stone is provided with a bearing surface, with which the stone rests on a support element arranged on the wall, respectively, on the cooling tube, in a support direction which is parallel is on the chamber-side surface of the stone, characterized in that at least one profile groove (13, 14) is provided in the stone (3), which extends parallel to the direction of support V and which extends through a wall or cooling pipe (2) The retaining element (21) is slidable, which holds the stone (3) in the direction (H) perpendicular to its chamber-side surface (H) to the wall or to the cooling pipe without stops in the supporting direction (V). Cladding stone according to claim 1, characterized in that the stone (3) has two parallel-extending profile grooves (13, 14) and the bearing surface (12) lies between the two profile grooves (13, 14). Cladding stone according to claim 1 or 2, characterized in that the profile groove (13, 14) and the support surface (12) each have partial cylindrical surfaces (6, 7 and 8) for a close support on the cooling pipe (2). Cladding stone according to one of the preceding claims, characterized in that the profile groove (13, 14) on the stone (3) is open at both ends. Cladding stone according to one of the preceding claims, characterized in that the profile groove (13, 14) widens in the stone (3) and forms a locking surface (16). Cladding stone according to one of the preceding claims, characterized in that the bearing surface (12) extends perpendicular to the chamber-side surface (5) of the stone (3). Cladding stone according to one of the preceding claims, characterized in that the bearing surface (12) is formed in a recess (11) of the stone (3), which is also open downwards. Cladding stone according to one of the preceding claims, characterized in that the bearing surface (12) is bounded laterally by strips (19). Cladding stone according to one of the preceding claims, characterized in that the profile groove (13, 14) opens at the bottom into a recess (17) or (18) of the stone (3).