EP0921354A1 - Liquid cooled grate plate - Google Patents

Abstract

A grate body (21) has a locating surface (22) for the material to be burnt and which is thermally connected with a coolant channel (31), which has at least one first coolant connection (32). This first coolant connection is arranged centrally between the grate body flanks. The grate body is provided with a connecting device for a grate plate carrier. The grate plate is a cast part. The coolant channel is a pipe conduit cast into the grate body, or can be a hollow space. The grate body is of one-piece or multiple structure.

Description

The invention relates to a grate plate with the Features of the preamble of claim 1.

For burning solids are especially in Waste incineration plants with so-called feed grates in use, which take up the material to be burned and give it a feed motion. The feed grates are formed by grate bars or plates, of some of which are stationary and others in groups back and forth in a feed direction or be moved against this.

The entire rust is usually covered by many grate bars arranged side by side and one behind the other or Plates formed. Through in the grate bars or plates - provided slotted nozzles flows in combustion air the combustion material lying on the grate.

The grate plates or rods heat up during the Operating due to the burning on the grate plates Solids considerably. The through the slots flowing combustion air can, especially since it is mostly preheated is or for combustion reasons is subject to a quantity limitation, only a small one Effect cooling effect. The temperature of uncooled grate plates or rods is therefore relatively high, resulting in a severe chemical corrosion and mechanical Wear of the grate plates. This is understandable undesirable.

A strong warming of the grate plates results in that they expand during operation. To do this To enable a certain game must be provided. This in turn can lead to the fact that between the Rust plates arise through the air in the Combustion chamber flows in. This happens uncontrolled and is therefore to be rejected. The combustion process continues negatively influenced by excess air. In addition, particles can cause so-called rust diarrhea fall under the grate, which is also undesirable.

For both reasons it is necessary to have grate plates to cool during operation or in a constant Keep temperature range. For example, from DE 196 13 507 C1 known a grate plate, which covers the stretches the entire width of the grate. The grate plate has many extending in parallel in the longitudinal direction Cooling channels on the ends to collect channels to lead.

Effective cooling can be achieved with this grate plate be effected without the between individual grate plates Expansion joints would have to be provided due to the undesirable Air flows. However, the grate plate extends over the entire width of the grate, which makes it relatively large.

EP 0621449 B1 is a grate plate with a meandering shape Cooling channel known. This leads across to the Grate plate and thus across to the feed direction the grate plate. Individual sections of the meandering Coolant channels are each in the longitudinal direction oriented.

Due to the supply of cooling water on one side the grate plate and the discharge of the heated cooling water on the other side of the grate plate results a heat gradient on the grate plate. The heat gradient can to different extents on both sides of the Guide the grate plate. Such differential expansions can Warp the grate plate. This allows you to Form gaps that are significantly larger than the thermal expansion itself. To keep this as low as possible a relatively large coolant throughput is required. In addition, only with slight coolant heating be worked to the default and / or faults the grate plate due to different thermal expansions to avoid. Otherwise could be between neighboring Rust plates form column through which unchecked Air flows into the combustion chamber and rust diarrhea occurs.

Based on this, it is an object of the invention to To create rust plate that has a low tendency to warp Has.

This task is with a grate plate according to claim 1 with one on the thermal load of the Cooling plate oriented cooling system solved.

In the grate plate according to the invention there is a coolant channel provided a central coolant connection has, while the connections at the state of Technology are usually arranged on the side. By the central Arrangement of the coolant connection becomes the coolant the grate plate and the coolant channel centrally or dissipated. The coolant channel leads from here to peripheral grate plate areas where the coolant from or is supplied.

By heating the coolant along the Coolant channel creates a heat gradient along the Coolant channel. The grate plate is in operation from above heated up, there is a heat gradient of the central connection to the peripheral peripheral areas the grate plate, or vice versa. In any case, it is Heat distribution more or less symmetrical. Depending on The grate plate can flow in the center of the coolant flow or be cooled more at the edge. In any case but is the temperature distribution with respect to a longitudinal median plane essentially symmetrical. So that will be Expansion behavior and thus also the thermal stress distribution the grate plate by cooling the center of gravity improved. There can be faults and thus the Formation of free cross sections between neighboring ones Grate bars or plates or jamming of moving Rust plates are avoided. This can cause rust diarrhea, i.e. falling solids between individuals Rust plates or bars can be reduced. Furthermore can reduce the amount of cooling water required and the overall temperature differences are increased what a higher heating of the cooling water and thus a repeated reduction of the required amount conditionally.

With central coolant supply or discharge, it can succeed in keeping large areas of the grate plate cool, whereby, even if the edge areas are heated, overall achieved a relatively low thermal expansion becomes. Differential strains can also be eliminated Thermal expansion of the grate plate with a minimized amount of cooling medium equalized and thermal stresses in the cast material be reduced.

The grate plate is especially for feed grates intended. To do this, it has a lanyard at one end provided with which they with a grate plate carrier is connectable. This is, for example, a round bar or any other carrier. On their opposite At the end, the grate plate then has a storage means, for example in Form a foot on which it can be used on a suitable Abutment is slidably supported. The abutment can, for example, a grate plate adjacent in the feed direction be.

As far as the coolant connection in the middle between is arranged on both sides of the grate plate, it can if necessary, closer to the storage means or closer to that Lanyards may be arranged. In both cases becomes a more or less uniform heat gradient reached on both sides. It is therefore not essential required that the coolant connection be in the middle is arranged between the two ends of the grate plate. It is crucial that it is provided in one place, on an imaginary, in the middle between the flanks, lying and connecting the ends of the grate plate together Line lies. The coolant connection is preferably something towards the front end of the grate plate offset so that the distance ratio to the ends is one in two. By such a central feed or The outflow of the coolant is thermal symmetry Maintained with sufficient accuracy and somewhat increased cooling in the front area.

A second coolant connection can be made to any one be arranged elsewhere on the grate plate. It can that from the central connector to the one spaced therefrom second coolant connection leading coolant channel designed as a single channel or on several subchannels be divided.

The coolant channel routing can vary be. E.g. the channel can be formed by a cavity be that of several coolant connections on the periphery of the plate for removing coolant. Coolant is through the central coolant connection fed. It is also possible to use the coolant channel spiral (round) or square spiral. If necessary, the coolant channel can also be star-shaped be trained. Subchannels then extend radially away from the central coolant connection. This can be on the edge of the grate plate individually or in groups be led to further coolant connections.

In all cases, the heat flow on the surface the grate plate by a suitable design of the Cross sections of the coolant channel can be achieved. E.g. it can occur with a radial arrangement of the subchannels be expedient to the subchannels in the central area narrow the flow rate of the coolant increase here. This creates a large central area the grate plate kept relatively cool, causing thermal expansion minimized. If the coolant channel is spiral-shaped there is a similar heat distribution. A a large part of the total length of the coolant channel is omitted on the edge area of the grate plate, whereas one correspondingly large area of the coolant channel divides several inner turns, the total one occupy a large area.

The grate plate according to the invention can in addition to the coolant duct connected to the central connection be provided with a further coolant channel, the example and preferably near the as a foot trained storage means is arranged. This one more Coolant channel can serve, especially occurring here reduce large thermal loads. This is particularly advantageous if in this area Air gaps designed to supply combustion air are. Due to the incoming combustion air high thermal loads here. By the inflowing Fresh air and the associated combustion there is a corrosive attack on the metal of the hot Rust plate that is tempered by cooling.

The grate plate can consist of one or more parts be trained. The execution of the grate plate as one-piece cast body allows a particularly inexpensive Manufacturing. It turned out to be special expediently exposed the coolant channel through Einund Pouring around corresponding pipes during manufacture the grate plate in the casting process. In order to can be relatively complex cooling channel geometries inexpensive can be produced without mold cores.

Fig. 1 einen aus mehreren Rostplatten zusammengesetzten Vorschubrost, der in dem Innenraum eines Ofens angeordnet ist, in vereinfachter schematisierter und perspektivischer Darstellung,

Fig. 2 eine Rostplatte des Vorschubrosts nach Figur 1, in perspektivischer, schematisierter Darstellung,

Fig. 3 die Rostplatte nach Figur 2, mit besonderer Veranschaulichung von in der Rostplatte ausgebildeten Kühlmittelkanälen, in perspektivischer Darstellung,

Fig. 4 die Rostplatte nach den Figuren 2 und 3, in einer schematisierten Draufsicht,

Fig. 5 die Rostplatte nach Figur 4, geschnitten entlang der Linie V-V,

Fig. 6 eine abgewandelte Ausführungsform der erfindungsgemäßen Rostplatte, in schematisierter perspektivischer Darstellung, und

Fig. 7 eine weitere abgewandelte Ausführungsform der erfindungsgemäßen Rostplatte, in schematisierter und perspektivischer Darstellung,

Fig. 8 den Vorschubrost nach Fig. 1 mit schematischer Veranschaulichung der Kühlmittelkanälle der Rostplatten, in einer schematisierten Draufsicht,

Fig. 9 eine aus dem Vorschubrost nach Fig. 1 und 8 herausgegriffene Rostplattengruppe mit Einzelversorgung aller Kühlmittelkanäle, in schematisierter Darstellung,

Fig. 10a eine aus dem Vorschubrost nach Fig. 1 und 8 herausgegriffene Rostplattengruppe mit rostplattenweise hintereinandergeschalteten Kühlmittelkanälen und Kühlmittelzufuhr an der Rostplattenmitte, in schematisierter Darstellung,

Fig. 10b eine aus dem Vorschubrost nach Fig. 1 und 8 herausgegriffene Rostplattengruppe mit rostplattenweise hintereinandergeschalteten Kühlmittelkanälen und Kühlmittelzufuhr zu einem stirnseitigen Kühlmittelkanal, in schematisierter Darstellung,

Fig. 11 eine aus dem Vorschubrost nach Fig. 1 und 8 herausgegriffene Rostplattengruppe mit gruppenweise hintereinandergeschalteten Front- und Rücken-Kühlmittelkanälen, in schematisierter Darstellung, und

Fig. 12 eine aus dem Vorschubrost nach Fig. 1 und 8 herausgegriffene Rostplattengruppe mit plattenweise hintereinandergeschalteten Kühlmittelkanälen und Hintereinanderschaltung der Kühlmittelkanäle ausgewählter Rostplatten, in schematisierter Darstellung.

Advantageous details of embodiments of the invention are the subject of dependent claims and result from the drawing and the associated description. Exemplary embodiments of the invention are illustrated in the drawing. Show it:

1 a feed grate composed of a plurality of grate plates, which is arranged in the interior of a furnace, in a simplified schematic and perspective illustration,

2 shows a grate plate of the feed grate according to FIG. 1, in a perspective, schematic representation,

3 shows the grate plate according to FIG. 2, with a special illustration of coolant channels formed in the grate plate, in a perspective view,

4 the grate plate according to FIGS. 2 and 3, in a schematic plan view,

5 shows the grate plate according to FIG. 4, cut along the line VV,

Fig. 6 shows a modified embodiment of the grate plate according to the invention, in a schematic perspective view, and

7 shows a further modified embodiment of the grate plate according to the invention, in a schematic and perspective representation,

8 shows the feed grate according to FIG. 1 with a schematic illustration of the coolant channels of the grate plates, in a schematic plan view,

9 a grate plate group picked out from the feed grate according to FIGS. 1 and 8 with individual supply of all coolant channels, in a schematic representation,

10a is a schematic representation of a grate plate group picked out from the feed grate according to FIGS. 1 and 8, with coolant channels connected one after the other in the form of grate plates and coolant supply at the middle of the grate plate,

10b shows a grate plate group picked out from the feed grate according to FIGS. 1 and 8, with coolant channels connected one after the other in the manner of a plate and coolant supply to an end-side coolant channel, in a schematic illustration,

11 shows a grate plate group picked out from the feed grate according to FIGS. 1 and 8 with group-connected front and back coolant channels, in a schematic representation, and

12 is a schematic representation of a grate plate group picked out from the feed grate according to FIGS. 1 and 8 with coolant channels connected in series plate-wise and connecting the coolant channels in series.

Description:

In Figure 1, a feed grate 1 is in the cutout illustrated, the one in a combustion chamber 2 only schematically illustrated waste incinerator is arranged. The feed grate 1 is by many individual grate plates 3 are formed, of which several each transversely to a furnace longitudinal direction 4 arranged side by side are. These grate plates 3 form a grate plate group 4, the feed grate 3 by several such grate plate groups 5 arranged one behind the other, 6, 7 and others not shown in FIG. 1 Grate plate groups is formed.

The grate plates 3, the grate plate group 5 are on their, based on the furnace longitudinal direction 4, upstream End 8 with a transverse recess open at the bottom 9 provided, for example, from FIG. 5 and on 3 mouth-like contact surfaces on both sides of the grate plate having. With the mouths of the transverse recess 9 is the Grate plate 3 formed on a round rod 11, for example Grate plate support element, which extends over the extends over the entire width of the feed grate 1. On hers opposite end 12 is the grate plate 3 with a Riot foot 14 provided a storage means for the Grate plate 3 forms. With the foot 14 is the Grate plate 3, as shown in Figure 1, on the next one Grate plate 3a of grate plate group 6. Die Grate plate 3a thus forms an abutment for the grate plate 3. The grate plate 3a, which like all grate plates with the grate plate 3 described as representative corresponds, is with its transverse recess 9 on a rod 15 stored, which is parallel to the rod 11 across the entire width of the feed grate 1 extends.

Additional rods 16 are along the entire length of the Feed grate 1 distributed, arranged transversely. Every second The rod is fixed in place. Arranged in between Rods are connected to a drive device, that of the rod in question reciprocates oscillating movement in the direction of the furnace longitudinal direction 4 To give. This movement is in Figure 1 for the grate plate group 3 illustrated by arrows 17, 18. This results in an overall stair-shaped moving grate 1, the grate plate groups 5, 6, 7 in the manner of a Stairs are arranged one above the other, each second grate plate group (6) swings back and forth to the combustion material a feed movement in the longitudinal direction of the furnace 4 to issue. Fig. 8 illustrates the feed grate 1 in top view.

The structure of a single grate plate 3 results in particular from Figures 2 to 5. The grate plate 3 is as Cast body formed. The cast body defines one Grate body 21, the top 22 of which essentially flat rectangular contact surface for the burned Has good. At its rear end 8 and at its the front end 12 of the grate body 21 is somewhat rounded. Between the rounded area at the end 12 and the Upright foot 14 is formed a transverse groove 24 in which Louvers 25 for access to combustion air flow out. These louvers 25 are in particular from FIG 5 can be seen. The air slots 25 connect the combustion chamber 2 with the trained under the feed grate 1 Area that is exposed to preheated combustion air is. The air slots 25 form the only one Connection between the area below the grate and the combustion chamber 2. Close adjacent grate plates 3 essentially close together.

The grate plates 3 are subject to operation strong thermal stress. To prevent that the grate plates 3 during operation by the on Burning combustible material stored in rust plates too strong are heated, each grate plate 3 with a coolant channel 31 provided. This coolant channel 31 is used the cooling of the top of the grate plate 3 and is in the thermal contact with this. The coolant channel 31 is, as can be seen in particular from FIG. 4, with a provided first central coolant port 32, the on the bottom of the grate body 21 is formed. To the Coolant port 32 is one that is not further illustrated Line connected, the coolant or leads away. The management is flexible or with appropriate Provide joints if the grate plate 3 is a moving plate.

The coolant connection 32 is, as from FIG. 4 emerges, midway between the two flanks 33, 34 of the Grate body 21 arranged. The coolant port 32 is doing so on an imaginary line 33 in one position arranged closer to the end 12 than to the end 8 lies.

Starting from the coolant connection 32, the Coolant channel 31 in several turns to a second, coolant connection 36 located at flank 33. The coolant channel 31 surrounds the coolant connection 32 with the same sense of direction. He is thus independent of the actual length-width ratio of the grate body 21 as a spiral, in particular designed as a rectangular spiral. Their turns lie on a common level and are therefore equally wide removed from the top 22.

To even out the temperature of the grate body 21 on its top 22, the turns can also in arranged at different distances from the top 22 be. E.g. it is possible to use the inlet Coolant connection 32 or 36 or on these subsequent turns a little further from the top 22 to be installed away. Then the turns are not on a common level, for example on the coat of a flat cone.

As particularly illustrated in FIG. 4, the individual sections 31 'of the coolant channel 31 corrugated be trained to improve the heat transfer. Both individual sections can be used 31 'and the entire coolant channel 31 are corrugated.

The coolant channel 31 can be through a mold core formed in the casting of the grate body 21 in this become. A particularly inexpensive and safe manufacture results, however, when the coolant channel 31 is initially designed as a pipeline in the Form of the grate body 21 to be cast and subsequently from the liquid material of the grate body 21 is cast around. The grate body 21 is preferred designed as a cast steel part. For the pipeline can conventional piping material (steel or other Metals) can be used. It results in an intimate and good heat-conductive connection between the pipeline and the grate body 21 with good heat transfer.

At the end 12 of the grate body 21 occur relatively high temperatures. This is particularly true in the area the transverse groove 24 is the case. To avoid overheating, a further coolant channel 41 is arranged transversely, which has two separate coolant connections 42, 43. Of the Coolant channel 41 is used exclusively for the focus Cooling the end region of the grate body 21 and can be used separately and specifically with cooling water be supplied.

If the grate plate 3 as a whole at a higher temperature operated, the cooling water is initially through the coolant channel 41 passed. If the grate plate 3 work at a lower temperature, the Flows through channel 31 with incoming cooling water. The Cooling water supply is preferably the coolant connection 32. There are many possibilities the interconnection of the coolant channels 31, 41 each grate plate 3 and between the grate plates 3.

The individual grate plates 3 of the feed grate 1 can be connected separately to coolant supply sources as illustrated in Fig. 9, for example. A flow line 44 is via corresponding connecting lines to the connections serving as inputs 32, 42 of the coolant channels 31, 41 connected. Of the Connections 36, 43 is heated cooling water rust plate by plate discharged to a return line 45. This will achieved a very effective cooling of the grate plates 3. This concept of cooling can be very Find hot areas of the moving grate 1 application.

If unequal plate temperatures are tolerated, the grate plates can also be made according to different concepts the same coolant flows through one after the other will be connected in series. This is for example in Figure 11 illustrates. This solution is particularly suitable for rust areas with less thermal stress.

Correspondingly, the coolant channels 31, 41 can also to be connected in series in rows. Illustrate this 10a and 10b. The coolant supply can first of all from the supply line at the connection 32 take place (Fig. 10a) when the top 22 is focused to be cooled. Should the forehead area are mainly cooled, the coolant is supplied to terminal 42 (Fig. 10b). If necessary the coolant supply can also be connected to the connection 36 respectively. This is not further illustrated in the figures, but corresponds to Fig. 10b with interchanged Flow and return line.

12 is a connection variant of the coolant channels 31, 41 illustrates the coolant channels 31, 41 for each grate plate 3 in each Series are connected. There are also several each Grate plates connected in series. The order of Flow through the grate plates 3 is based on the Grid center set to the sides. First of all the more heavily loaded middle grate plates and afterwards flowed through the marginal grate plates 3.

Through the appropriate choice and / or combination The cooling variants are a good adaptation to different ones Items in different applications or possible in different rust areas. All cooling variants illustrated in FIGS. 9 to 12 can also be exchanged for flow pipe 44 and return line 45 are used if it is the thermal load accordingly required.

The feed grate 1 described so far works as follows:

Solid to be burned is in operation, e.g. Rubbish on the feed grate 1. Every second grate plate group 6 performs a back and forth movement (arrows 17, 18). Combustion air flows through the air slots 25 into the combustion chamber 2. The coolant channels 31, 41 are flowed through by cooling water. It is with the Cooling water channel 41 a cross-flow based on the Oven longitudinal direction 4 available. The coolant channel 31 realizes a circulating flow, whereby the Cooling water starting from the coolant connection 32 transported several turns radially outwards until it arrives at the coolant connection 36 and is dissipated. While the flow rate in Circumferential direction is relatively high, is the radial component the flow movement less. Due to the relatively large Peripheral speed on the approximately spiral of the path defined in the coolant channel 31 results in a good temperature uniformity. Independent of Radial directions are at equal distances from that Coolant connection 32 reached almost the same temperature. The temperatures on both flanks 33 are thus 34 the same size. There is no heat gradient from the one side of the grate body 21 to the other.

6 and 7 are alternative embodiments the grate plate 3 illustrates. With the grate plate 3 according to FIG. 6, the coolant channel 31 starts out from the central coolant connection 32 into subchannels 31a, 31b ... 31n divided. These extend starting from the coolant connection 32 initially star-shaped away from this. The subchannels 31a to 31g pivot then to a transverse collecting duct 51, the arranged at the end 12 of the grate plate 3 and with a Coolant connection 36a is provided. The sub-channels 31h to 31n lead in the arch to a collecting channel 52 which leads to a coolant connection 36b.

Otherwise, the grate plate 3 coincides with FIG. 6 the grate plate 3 described above, so that their description applies accordingly.

A central coolant supply or discharge points likewise the grate plate 3 illustrated in FIG. 4 on. Starting from the first coolant connection 32, The coolant channel 31 branches out into a plurality of rays striving away from the coolant connection 32 Subchannels 31a to 31n. These are on their marginal side End with an encircling collecting channel 53 connected to one or more coolant connections 36 having. The subchannels 31a to 31n can be in one single level or on the mantle of a flat cone be arranged. They can also cross sections along vary in length.

A water-cooled grate plate 3, which in particular used for incinerators, at least points a coolant channel 31. This serves the Cooling the top 22 of the grate plate 3. The coolant channel 31 has a coolant connection 32 which arranged in a central region of the grate plate 3 is. It is essential that the coolant connection 32 approximately midway between the two flanks 33, 34 of the grate plate 3 is arranged, at one end 8, 12 of the Grate plate 3 can be arranged offset.

Claims (26)

Grate plate (3) with cooling device, in particular for feed grates (1), in which a plurality of grate plates are arranged side by side and one behind the other, preferably partially overlapping one another with a grate body (21) which has on its upper side a support surface (22) for solids to be burned, which is thermally connected to a coolant channel (31) which has at least one first coolant connection (32),
characterized, that the first coolant connection (32) of the grate body (21) is arranged centrally between its flanks (33, 34). Grate plate according to claim 1, characterized in that the grate body (21) with a connecting means (9) is provided for a grate plate support (11). Grate plate according to claim 2, characterized in that the connecting means (9) is a recess, which the grate body (21) has on its underside and set up to accommodate the grate plate carrier (11) is preferably at one end (8) of the grate plate (3) is arranged and between the flanks (33, 34) of the grate body (21) extends. Grate plate according to claim 3, characterized in that it is attached to the connecting means (9) remote end (12) has a bearing means (14) with which the grate plate (3) can be supported on an abutment is. Grate plate according to claim 4, characterized in that the one arranged centrally between the flanks (33, 34) first connection (32) of the coolant channel (31) arranged at an unequal distance from the ends (8, 12) is. Grate plate according to claim 1, characterized in that the coolant channel (31) starting from the first arranged centrally between the flanks (33, 34) Coolant connection (32) to a second coolant connection (36) is guided by the first coolant connection (32) is spaced. Grate plate according to claim 6, characterized in that the second coolant port (36) is nearby a flank (33, 34) is arranged. Grate plate according to claim 6, characterized in that the second coolant connection (36) at a End (8) of the grate body is arranged. Grate plate according to claim 1, characterized in that the coolant channel (31) in the grate body (21) arranged essentially in a single plane is. Grate plate according to claim 1, characterized in that the coolant channel (31) from its first Connection (32) starting in at least one turn is arranged all around. Grate plate according to claim 10, characterized in that the coolant channel (31) has multiple turns with the same sense of rotation. Grate plate according to claim 10, characterized in that the turn is at least one straight or has corrugated section. Grate plate according to claim 12, characterized in that the turn is essentially rectangular is trained. Grate plate according to claim 1, characterized in that the coolant channel (31) has at least two subchannels connected to one another at the start and end (31a, 31b). Grate plate according to claim 14, characterized in that the subchannels (31a, 31b) starting from the first coolant connection (32) arranged radially are. Grate plate according to claim 1, characterized in that the coolant channel (31) over its length has a constant cross-section. Grate plate according to claim 6, characterized in that the coolant channel (31) has a cross section has, which is between the coolant connections changed. Grate plate according to claim 1, characterized in that the cross section is close to the coolant supply to be used first or second coolant connection (32, 36) is wider than the other Coolant connection (36, 32). Grate plate according to claim 1, characterized in that it has a further coolant channel (41). Grate plate according to claim 4, characterized in that the further coolant channel (41) is nearby of the bearing means (14) is arranged and preferably extends between the flanks (33, 34). Grate plate according to claim 20, characterized in that the further coolant channel (41) and the Coolant channel (31) in series or parallel connection are connected, the coolant channels (31, 41) of adjacent grate plates preferably with each other are connected. Grate plate according to claim 1, characterized in that it is designed as a casting. Grate plate according to claim 22, characterized in that the coolant channel (31) through a in the Grate body (21) cast pipe is formed. Grate plate according to claim 1, characterized in that the coolant channel (31) through a in the Grate plate (21) is molded into the cavity. Grate plate according to claim 1, characterized in that the grate body (21) is formed in one piece. Grate plate according to claim 1, characterized in that the grate body (21) is constructed in several parts.

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