KR20080024112A - Cooling system for a combustion grate in an incineration plant - Google Patents

Abstract

In a cooling fluid circulation system for an incineration or combustion grate in an incineration or combustion plant, the grate comprises a number of grate beams, at least some of which are movable for providing a movement of the fuel on top of said grate, primary air being blown through the grate from a primary air chamber below the grate Connections for circulating cooling fluid through said grate beams are positioned at the bottom side of said grate beams, inside said primary air chamber, and connected to rigid tubing, possible headers and flexible tubing, preferably in the form of bellow tubes, for providing a connection between moving tubing and stationary tubing in the cooling fluid circulation system. The flexible tubing is positioned outside the primary air chamber and the iead-in for the moving, rigid tubing through the wall of said primary air chamber is provided with a flexible bellow in order to avoid leakage of primary air along the tube. Hereby the flexible tubing is not subjected to the grate screenings falling down from the grate and the high temperatures thereof. ® KIPO & WIPO 2008

Description

Cooling system for combustion grate in incineration plant {COOLING SYSTEM FOR A COMBUSTION GRATE IN AN INCINERATION PLANT}

The present invention relates to a cooling fluid circulation system of the kind described in the preamble of claim 1.

In this type of cooling fluid circulation system, it is known to have a grate beam arranged to be movable to provide movement of fuel at the top of the grate and to blow main air through the grate from the main air chamber below the grate. It is. The connection for circulating the cooling fluid through the grate beam is normally positioned on the bottom side of the grate beam so as not to affect the movement of fuel at the top of the grate. To allow the movement of the movable grate beam, a flexible tubing was normally provided under the grate inside the main air chamber before the rigid tubing exited from this main air chamber, whereby a fixed connection between the tubing and the side wall of the main air chamber Was formed. Cooling fluid circulation systems of this type that do not specifically mention flexible tubing are known, for example, from EP 0 804 706.

It is an object of the present invention to provide a cooling fluid circulation system of the kind described above which makes it possible to avoid positioning flexible tubing underneath the grate, which object in accordance with the invention also provides the features described in the characterizing part of claim 1. A cooling fluid circulation system of the above kind is achieved. Due to this configuration, the flexible tubing is positioned outside the main air chamber, thus eliminating the need for its possible high temperature and grate screen falling from the grate, and for rigid tubing moving through the wall of the main air chamber. The lead-in is provided with a flexible bellow to prevent leakage of the main air along the tube from the inside of the main air chamber to the periphery. Preferred embodiments of the cooling fluid circulation system, which will be apparent to those skilled in the art after reading the following detailed description, are described in the dependent claims.

In the following detailed description of the invention, the invention will be described in more detail with reference to exemplary embodiments of a cooling fluid circulation system according to the invention shown in the drawings.

1 is a schematic partial side view in the longitudinal section of a combustion grate in which the invention may be practiced;

2 schematically shows a tubing connected to a mobile grate beam according to the invention.

Figure 3 schematically shows the inlet of a mobile rigid tube through the main air chamber wall and a flexible bellows positioned externally connecting the mobile rigid tubing to the wall of the main air chamber.

4 schematically shows a lyre-formed tube for providing a continuous connection between the inlet and outlet of the grate beams connected in series.

5 schematically shows a helical tube for providing a connection between the inlet and outlet of a continuously connected grate beam.

The waste incineration plant shown in FIG. 1 comprises a plurality of grate sections I-IV, each extending in the direction of movement of fuel at the top of the grate sections and alternating the mobile grate beams and the fixed grate beams in the cross direction. And a downward stepped grate beam 1 arranged. Thus, each grate section comprises a plurality of grate beams 1 positioned above the main air chamber P for introducing the main air through the main air openings in the grate.

As shown in Fig. 2, the movable grate beam 1 is provided with a moving mechanism 2 at one end and a support roller 3 at the other end, whereby the movable grate beam 1 is in its longitudinal direction. Can be moved to. The grate beam 1 is provided with a cooling fluid channel (not shown in detail) through which the cooling fluid is supplied through the rigid tube 4, and the cooling fluid exits the grate beam through the rigid tube 5. The tubing 4, 5 is connected to the inlet header 6 and the outlet header 7, respectively, which are positioned at a suitable distance below the grate beam 1. Although rigid, the tubing 4, 5 allows any minimum movement of the grate beam relative to the headers 6, 7 and thereby a small relative movement of the individual movable grate beam 1. Corresponding stationary grate beams positioned between movable grate beams are correspondingly provided with similar inlet and outlet tubing and inlet and outlet headers, or conventional tubing and headers, which are not part of the present invention and are described in detail below. It won't be. However, the stationary grate beam is also connected to the inlet and outlet headers, which are connected to the outside through the walls of the main air chamber in a typical manner.

Each distance between the grate beam and the inlet header 6 and the outlet header 7 can be reduced by using a liar, helical or coiled tubing 4, 5.

The headers 6, 7 are oriented to the box 8 positioned on the side of the main air chamber P, and the inlet for the headers 6, 7 is an opening in the box 8 as shown in FIG. 3. Extending outwards through 11, 12, the openings 11, 12 are provided with studs for connecting the bellows 9, 10 to the box 8 in an airtight manner. Opposite ends of the bellows 9, 10 are hermetically connected to tubing 6, 7 for the inlet and outlet of the cooling fluid, the hermetic connection being schematically indicated by clamps 13 to 16.

When the movable grate beam 1 moves, the headers 6, 7 move mainly in the longitudinal direction of the bellows 9, 10 without obstructing the openings 11, 12, in this way the rigid tubing 4, 5, 6, 7 are connected to the air outside the main air chamber P in a movable manner without the risk of leakage of the main air to the outside of the main air chamber.

In the position behind the clamps 15, 16, flexible tubing is provided to connect the inlet and outlet for the cooling fluid to the fixture of the cooling fluid circulation system.

In situations where it is convenient for the cooling fluid to circulate continuously in at least some of the grate beams, the continuous connection between the inlet and outlet of the continuously connected grate beams provides any degree of freedom of relative movement between the continuously connected grate beams. It may be provided in a layered, helical or coiled tube for this purpose.

Although the present invention has been described in connection with specific embodiments as indicated in the figures, those skilled in the art can appreciate many variations without departing from the scope of the following claims. Such modifications include the use of fluid cooling circulation systems associated with other types of mobile incineration grate beams, such as individual mobile grate beams, which require separate inlet systems for separate headers and separate mobile grate beams.

Claims (11)

A cooling fluid circulation system for incineration or combustion grate in an incineration or combustion plant, The grate comprises a plurality of grate beams at least partially movable to provide for the movement of fuel on top of the grate, Main air is blown through the grate from the main air chamber below the grate, A connection for circulating cooling fluid through the grate beam is located on the lower side of the grate beam inside the main air chamber and preferably provides a connection between the mobile tubing and the stationary tubing in the cooling fluid circulation system. A cooling fluid circulation system connected to a rigid tubing, possibly a header and a flexible tubing in the form of a bellows tube, The flexible tubing is positioned outside the main air chamber, An inlet for rigid tubing moving through the wall of the main air chamber is provided with a flexible bellows to prevent leakage of main air along the tube. 2. The cooling fluid circulation system of claim 1 wherein the direction of the rigid tube at the inlet is primarily in the direction of movement at this point. The cooling fluid of claim 1, wherein the cooling fluid is circulated in parallel in the grate beam, The inlet and outlet for cooling fluid circulation through the stationary beam are at least one set of headers in which the vertical rigid tube is positioned at this distance below the grate beams allowing any degree of freedom of relative movement between the stationary grate beams. Is linked to The inlet and outlet for the cooling fluid to the movable grate beam are connected by at least one other set of headers, the headers being below the grate beam allowing the vertical rigid tube to allow any degree of freedom of relative movement between the movable grate beams. Cooling fluid circulation system, characterized in that positioned at this distance. The cooling fluid of claim 1, wherein the cooling fluid is circulated in parallel in the grate beam, Inlets and outlets for cooling fluid circulation through the stationary beams are connected to at least one set of headers positioned below the grate beams and are liar, spiral shaped to allow any degree of freedom of relative movement between the stationary grate beams. Or is connected to the inlet and outlet of the grate beam through a coiled tube, The inlet and outlet for the cooling fluid to the movable grate beam are connected by at least one other set of headers, and the connection between the headers and the inlet and outlet of the grate beam is any degree of freedom of relative movement between the movable grate beams. Cooling fluid circulation system, characterized in that it is provided in the form of a layered, helical or coiled tube to allow. The cooling fluid of claim 1, wherein the cooling fluid circulates continuously in at least some of the grate beams, and the continuous connection between the inlet and the outlet of the continuously connected grate beams is provided in the form of a liar, helical or coiled tube. To provide any degree of freedom of relative movement between successive connected grate beams. 6. The cooling fluid circulation system according to any one of claims 1 to 5, wherein the movable grate beam is movable primarily and linearly in the direction of transport of fuel at the top of the grate. 7. The cooling fluid circulation system of claim 6 wherein the grate beams of the grate are positioned side by side alternately mobile and stationary. 8. The cooling fluid circulation system of claim 6 or 7, wherein the grate beam extends longitudinally in the direction of transport of fuel at the top of the grate. The cooling fluid circulation system according to any one of claims 6 to 8, wherein the grate is subdivided in continuous grate sections in the conveying direction. 10. The cooling fluid circulation system according to any one of claims 6 to 9, wherein the grate beam has a stepped grate top downward in the conveying direction. 11. The cooling fluid circulation system of claim 1, wherein the cooling fluid is water.

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