KR20000023442A - A grate block for a plant for the thermal treatment of waste - Google Patents

Abstract

PURPOSE: A grated block of a thermal treatment facility is provided to reduce the number of grated blocks by arranging pipes to be symmetrical to the plane symmetrical lengthwise of a grated block. CONSTITUTION: A grated block(1) is composed of: an upper wall(23) while forming a left side wall(29a), a right side wall(29b), a front wall(24) and a rear wall(21); a hook(22) formed on the rear wall; a symmetric face(S) extended in the same direction as lengthwise direction and formed to be orthogonal to the horizontal face; a pipe(16) connected to a water supply connection part(30) to be symmetrical with each other against the symmetric face; a carved part(16a) of the pipe extended lengthwise to the first front wall; a curved carved part(16b) connected to the carved part; and another lengthwise carved parts(16c,16d,16e) connected sequentially. Herein, the pipe(16) is placed to separates from the rear wall to easily approach to the water supply pipes(30,43).

Description

A grate block for a plant for the thermal treatment of waste}

The present invention relates to a lattice block of the waste heat treatment facility according to claim 1.

The publication EP 0 844 438 A2 describes the grid of an incineration plant with a number of grid blocks with cooling furnaces. The grating block having a longitudinal direction is provided with a cooling path, which is connected perpendicularly to the longitudinal direction of the grating, and the cooling path is a sinuous shape and cooling of different strength with respect to the longitudinal direction is possible. .

The problem of the grating block is that it requires a grating having a plurality of grating blocks arranged side by side. Moreover, the sidewalls of the lattice are difficult to cool, and the shape of the sinuous cooling furnace is relatively complicated, and excessive manufacturing costs are required.

Accordingly, the present invention has been invented to solve the above problems, and an object thereof is to provide a lattice block formed to improve efficiency.

Another object of the present invention is to provide a lattice block having the features shown in claims 1, 2 and 8.

It is further an object of the present invention to provide a lattice block having a rectangular body acting in the longitudinal direction and a casting pipe of an undulating shape. Pieces of the pipe are arranged on the side of the grating block for flowing in the longitudinal direction. A preferred coolant used is water, which is passed through a pipe to cool the lattice block. The arrangement of the pipes passing through the side cross-section of the lattice block in the longitudinal direction has the effect of dissipating a large amount of heat to the outer surface. The effect of the present invention is that the side wall or interface side of the grating block according to the invention is cooled in a simple manner. In addition, the longitudinal arrangement of the pipes prevents differential cooling in the longitudinal direction of the grating block. As a result, a large temperature difference does not appear in the longitudinal direction of the grating block. Since there is only one pipe in the lattice block, fluid flows through it, which can cause one side of the laterally extending pipe to have a higher temperature than the other opposite piece perpendicular to the length of the pipe. have. This allows the temperature difference to be perpendicular to the longitudinal direction in the grating block. The grating block according to the present invention is compensated by the two grating blocks in which the above phenomenon is arranged side by side on both sides, the one side has a high temperature and the other side has a low temperature, the temperature difference is adjacent to the side It is reduced by the heat exchange passing through it.

A particularly significant effect is that the pipes are arranged to be symmetrical with respect to the longitudinally symmetrical plane of the grating block, so that only one kind of grating block is needed to complete a complete grating.

The effect of the grating block according to the invention is that it requires less bending to achieve the required cooling capacity and therefore costs less. The pipes are assembled into semi-finished products, and the pipes prepared for molding are put into a casting block for the lattice block unit, and the lattice blocks are cast in a known manner.

1A is a longitudinal sectional view of a grating block according to the present invention;

1b is a perspective view of another grating block according to the present invention;

Figure 2a is a bottom view of another grating block in accordance with the present invention,

FIG. 2B is a sectional view taken along the line A-A of FIG. 2A;

3a is a perspective view of another grating block according to the present invention;

3b is a perspective view of a pipe disposed in the lattice block according to FIG. 3a;

4 is a perspective view of a grating according to the present invention.

Explanation of symbols on the main parts of the drawings

1 --- lattice block, 21 --- back wall,

22 --- hook, 23 --- upper wall,

24 --- front wall, 25 --- corners,

26 --- pedestal, 30, 43 --- water supply connection.

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

1A shows a longitudinal section of the grating block 1.

As shown, the grating block 1 is produced by a casting method with a casting pipe 16. The grating block 1 has an upper wall 23 that forms an effective surface 33. The rear wall 21 and the hook 22 extend on the left side of the upper wall 23, and the corner 25 and the front wall 24 extend on the right side of the upper wall 23, the bottom of the front wall 24. The pedestal 26 which has the support surface 26a is formed in the. The side wall 29 is located between the upper wall 23 and the rear wall 21 and the front wall 24. The pipe 16 has a water supply connection 30, extending to the corner between the upper wall 23 and the side wall 29, with the engraving 16a of the pipe 16 along the longitudinal direction L. It extends to the corner part 25. As shown in FIG. This pipe 16 extends to the height of the pedestal 26 and extends perpendicular to the horizontal plane of the pedestal 26. In addition, the pipe 16 extends to the corner through the length L2 along the longitudinal direction L, and extends to the length L5 along the side wall 29. The size of the grid block 1 is the length L4, and the size of the pedestal 26 is the length L3. In addition, the air outlet 47 is formed in the front wall 24.

FIG. 1B is another embodiment of the grating block 1, which is fabricated in a similar manner to the grating block of FIG. 1A. The pipe 16 associated with the water supply connection 30 extends vertically with respect to the longitudinal direction L and is bent at 90 degrees, and the engraving 16a has a length at the corner between the upper wall 23 and the side wall 29. It extends in the direction L but extends longer than the length L2. The length L2 should be at least about 1/5 of the total length L4 of the grating block 1. In addition, the engraving 16a extends approximately 2/3 or more with respect to the length L4 of FIG. 1A and extends approximately 4/5 or more with respect to the length L4 of FIG. 1B.

2A is a bottom view of another embodiment of a grating block. This grating block 1 is naturally rectangular and has an upper wall 23, as already shown in FIG. 1A, with a left sidewall 29a and a right sidewall 29b, a front front wall 24 and a rear back wall ( 21). The hook 22 is disposed on the rear wall 21. In addition, the lattice block 1 has a symmetry plane (S) extending in the same direction as the longitudinal direction (L), which is perpendicular to the horizontal plane. Meanwhile, the pipe 16 to which the water supply connection part 30 is connected and the pipe 16 to which the water supply pipe 16 is connected are disposed on the grid block 1 so as to be symmetrical with respect to the symmetry plane S. The water supply pipes 30 and 43 are spaced apart from the rear wall 21 to facilitate access. The engraving 16a of the pipe 16 extends in the longitudinal direction L to the first front wall 24, followed by the bent engraving 16b followed by the engraving 16a, again in the longitudinal direction L. Phosphorus engraving 16c is linked, and the bent engraving 16d is extended again, followed by the engraving 16e.

In FIG. 2B showing the cross section along the line A-A in FIG. 2A, the engraving 16e extends at the corner between the upper wall 23 and the right side wall 29b. The engraving portion 16e is connected to the engraving portion 16f again, and then the engraving portion 16g transverse to the longitudinal direction L extends in the pedestal 26.

The pipe 16 has a somewhat serpentine shape and occupies many lengths in the longitudinal direction L. As shown in FIG. The pipe 16 has a relatively small bending point, thereby making it possible to produce the pipe at low cost. The side walls 29a and 29b are effectively cooled by the engraving 16e extending in the longitudinal direction. For example, if the coolant is supplied through the water supply connection 30, the right side wall 29b is more concentrated than the left side wall 29a. This is because the water reaching the engraving 16e of the left side wall 29a is warm. The minute temperature difference between the left side wall 29a and the right side wall 29b is partially compensated by the thermal conductivity of the casting. Another grating block 1 is properly disposed to the left and right of the grating block 1, and the side wall 29a and the other side wall 29b are brought into contact with each other to compensate for the minute temperature difference. The distribution is uniform.

The lattice 3 as shown in FIG. 4 is part of a waste heat treatment plant lattice, such as for example waste. A plurality of lattice blocks 1 are formed and arranged one after the other in the transverse direction of the lattice.

In the present embodiment, the lattice 3 has nine rows 4, 5 in the longitudinal direction L, with one row 4 positioned behind the other row 5. In this case, the flow of heat 5 is arranged after the fixed heat 4. Here, the fixed grid block 1 is mounted at the end of the block holding tube 7, and the block holding tube 7 is fixed to the bracket 8, while the block holding tube of the flow grid block 1 is attached. 7) is fixed to the bracket (9) to make a linear movement in the longitudinal direction (L). This flow bracket 9 is fixed to the lattice carriage, which reciprocates in the longitudinal direction L, but is mounted through a roller on the lattice flow 3. This reciprocating motion in the longitudinal direction L necessarily causes the flow of heat 5 of the grid block 1 to be operated in the movement direction L1. In this case, all the grating blocks each perform a slight pivoting movement with respect to the block retaining tube 7. The conveying track formed by the grating block 1 is limited in scope by the side film 15 or the side wall 15.

The engravings 16a and 16e disposed on the grating block 1 of the present invention can be cooled in a simple manner through the side walls 29a and 29b on both sides.

The effect of the grating block 1 according to the invention is that it can satisfactorily satisfy the requirements for cooling the grating block 1 and for cooling the side wall 15. In addition, the water supply connection (30, 43) is always in the same position is enough to supply the cooling water.

FIG. 3A shows a bottom of the grating block 1 as another embodiment according to the invention, wherein reference numerals coincide with reference numerals of FIGS. 2A and 2B. This grating block 1 is formed symmetrically with respect to the plane of symmetry S shown in Fig. 3B. 3b shows only the pipe 16 shape in the grating block 1 according to FIG. 3a. The cooling water is supplied through the water supply connecting portion 30, and the engraving portion 16e extending in the longitudinal direction L along the side wall 29b through the engraving portions 16a, 16b, 16i, 16d, 16k, and 16h. Flows through the engraving portion 16f and then through the engraving portion 16g perpendicular to the longitudinal direction L, and returns to the water supply connection portion 43 along a shape symmetrically extended to the pipe 16. Come.

The pipe 16 can also be entirely cast symmetrically with respect to the plane of symmetry S by removing the engraving 16e extending in the longitudinal direction L from the side walls 29a and 29b. As a result, the cooling capacity of the side walls 29a and 29b is reduced, but the effect on the arrangement according to the present invention is effective.

Preferably, on the one hand the grating block should be as warm as possible to extract less heat from the debris on the surface, but on the other hand the grating block made of cast iron should be sufficiently cooled to avoid excessive wear caused by high temperatures. .

The casting pipe 16 is made of a metal or alloy such as casting. The pipe 16 may be designed integrally or may consist of a number of connections forming a fluid passage. Multiple pipes 16, i.e. two pipes 16, may be cast into the grating block 1, in which case both pipes will each have two connections 30,43, such as water. The fluid splits and is supplied. These two pipes 16 are arranged in the grid block 1 in a manner symmetrical with respect to the plane of symmetry S.

The effect of the present invention as described above is that the pipes are arranged to be symmetrical with respect to the plane symmetrically in the longitudinal direction of the grating block, so that only one type of grating block is necessary to complete a complete grating.

The effect of the grating block according to the invention is that it requires less bending to achieve the required cooling capacity and therefore costs less.

Claims (9)

It consists of a rectangular body acting in the longitudinal direction (L) and has a serpentine shape and an overall cast pipe (16), with the engravings (16a, 16e) of the pipe (16) being in the longitudinal direction (L). The lattice block of the waste heat treatment equipment, characterized in that arranged on the side of the lattice block (1) to extend. 2. The grating block (1) according to claim 1, wherein the grating block (1) has a total length (L4) in the longitudinal direction (L), and the engravings (16a, 16e) extend at least 1/5 of the total length (L4). Lattice block of the waste heat treatment equipment, characterized in that. The plane (S) according to claim 1 or 2, wherein the grating block (1) has an effective surface (33), wherein the pipe (16) is in a plane (S) perpendicular to the effective surface (33) and in the longitudinal direction (L). Lattice block of the waste heat treatment equipment, characterized in that arranged symmetrically. 8. The grating block (1) according to any one of the preceding claims, wherein the grating block (1) is provided with an upper wall (23), the upper wall (23) forming an effective surface (33), extending in the longitudinal direction (L), and the effective surface (33). A grid block of waste heat treatment equipment, characterized in that it is connected to one of two side walls (29a, 29b) perpendicular to each other. 5. The lattice block of the waste heat treatment apparatus according to claim 4, wherein the engravings 16a and 16e extend at corners formed on the upper walls 23 forming the side walls 29a and 29b and the effective surface 33. . The method according to any one of the preceding claims, wherein the grating block (1) has a front wall (24) perpendicular to the longitudinal direction (L), wherein the engraving (16g) of the pipe (16) is perpendicular to the longitudinal direction (L). Lattice block of the waste heat treatment equipment, characterized in that disposed on the front wall (24). The pipe block (1) according to any one of the preceding claims, wherein the grating block (1) has a rear wall (21) perpendicular to the longitudinal direction (L), and the pipe (16) connects the fluid supply connection portion (30) and the fluid supply connection portion (43). The grid block of the waste heat treatment facility, characterized in that the fluid supply connector (30) and the fluid supply connector (43) are disposed in the area of the rear wall (21). The waste heat treatment according to any one of the preceding claims, characterized in that the grid block (1) is provided with an air outlet (47) in the front wall (24), the air outlet (47) extending in the longitudinal direction (L). Grid block of equipment. The waste incineration plant according to claim 1, wherein the grid block (1) is included.