KR101246174B1 - Water cooling type input chute for incinerators - Google Patents

Abstract

PURPOSE: A water cooling type input chute for an incinerator is provided to improving cooling efficiency by uniformalizing the upward flow and the lateral flow of the cooling water supplied from the lower part of the input chute. CONSTITUTION: A water cooling type input chute for an incinerator includes an inner box(110), an outer box(120), a cooling water supply unit(130), and a cooling water discharging unit(140). The inner box has a passage through which the object for incineration input by an input hopper passes by falling. The outer box comprises an exterior wall(122) formed with a fixed space from an inner wall(112) of the inner box. The cooling water supply unit is connected to an injection port(126) mounted on the external surface of the lower part end of the outer box to supply cooling water to the space in between the inner wall and the outer wall. The cooling water discharge unit is connected to a vent(128) equipped on the external surface of the upper end of the outer box to discharge the cooling water with heat exchanged in the space in between the inner wall and the outer wall to the outside.

Description

Water Cooling Type Input Chute For Incinerators

The present invention relates to a cooling device provided in the inlet for injecting fuel in an incinerator, and more particularly, to equip the upstream and lateral flow of the cooling water supplied from the lower part to be heated by the combustion heat and the radiant heat of the combustion chamber. It relates to a water-cooled input chute for incinerators that can increase the cooling efficiency.

In general, as the human society is civilized and industrialized, the destruction of the natural environment caused by wastes discharged from households or industrial sites is becoming more serious, and a method of incineration of non-recyclable wastes through incinerators has been proposed.

In addition to the incineration of such wastes, in order to combust solid fuels (RDF, RPF, WOOD CHIP), a stoker type incinerator comprising a grate as the bottom of the combustion chamber is widely used.

1 illustrates a general grate type incinerator, and an incinerator 1 is configured to secondaryly burn a first combustion chamber 10 for drying and burning an incineration object, and exhaust gas discharged from the first combustion chamber 10. The second combustion chamber 20 is comprised.

In addition, an upper end of one side of the first combustion chamber 10 in which the grate 12 is disposed is provided with an input chute 32 for injecting an incineration object, and an incinerator ash outlet 116 for discharging an incineration ash is provided in the lower side of the first combustion chamber 10. .

In addition, the pusher 40 for supplying the incineration object dropped through the input hopper 30 provided at the upper end of the input chute 32 into the first combustion chamber 10 to the first combustion chamber 10. The incineration object dropped from the input hopper 30 to the pusher 40 is dried and incinerated through the drying end, the combustion end and the post combustion end of the grate 14 extending from the pusher 40 and then incinerated The incineration ash is discharged to the outside through the outlet 16.

However, in the conventional incinerator, the input chute 32 has a problem in that it is deformed or damaged by high temperature combustion heat generated during incineration because it is connected to the first combustion chamber 10 due to the installation structure.

In addition, the incineration object introduced through the input chute 32 is fixed by the combustion heat or the radiant heat of the combustion chamber, there is a problem that the incineration object such as waste is not smoothly made.

Accordingly, Korean Patent Laid-Open Publication No. 10-2009-0096907 discloses a hollow rectangular shape in which an inner wall and an outer wall are double sealed by a metal material, and a cooling water inlet is formed at one lower portion of the outer wall, and a cooling water outlet is formed at an upper portion of the other side. Disclosed is a water-cooled waste input chute characterized in that formed.

On the other hand, in the conventional cooling apparatus, the supply flow of the cooling water filled into the space between the inner wall and the outer wall is made uneven in the height direction and the lateral direction, thereby lowering the cooling efficiency of uniformly cooling the entire chute. There was a problem that can not completely prevent the deformation and damage of the input chute.

The present invention is to solve the problems as described above, the object is to provide a water-cooled input chute for incinerators that can increase the cooling efficiency by uniformizing the upward flow and the lateral flow of the cooling water supplied from the bottom.

As a specific means for achieving the above object, the present invention is provided between the input hopper and the combustion chamber in the incinerator chute for supplying the incineration object to the combustion chamber, the passage through which the incineration object injected through the input hopper falls through Inner box with; An outer box having an outer wall spaced apart from the inner wall of the inner box at a predetermined distance; connected to at least one injection hole provided on an outer surface of the lower end of the outer box to cool the water into a space between the inner wall and the outer wall Cooling water supply unit for supplying; A coolant discharge part connected to at least one outlet provided on an outer surface of the upper end of the outer box to discharge the coolant heat exchanged in the space between the inner wall and the outer wall to the outside; A first coolant flow is formed in the space to form a first coolant flow which induces the coolant filled in the space upwards from a lower portion to an upper portion by a first passage formed between an outer surface of the inner wall and an end fixed to the inner wall; A plurality of first partition walls provided along the multilayer; And first partition walls adjacent to each other to form a second coolant flow laterally guiding cooling water filled between the first partition walls adjacent to each other by a second passage formed between the outer wall and one side end facing the outer wall. A second partition wall provided with a plurality of spaced intervals in the lateral direction; It provides a water-cooled input chute for incinerator comprising a.

Preferably, the outer box may partially expose the first partition wall to the outer wall corresponding to the first partition wall, and weld the outer partition along a contact portion between the outer surface of the partially exposed first partition wall and the inner surface of the outer wall. It is provided with a plurality of exposed exposure holes formed so as to penetrate.

Preferably, the cooling water discharge unit includes a discharge box having an inner space in communication with the discharge port is filled with the cooling water, and a discharge pipe provided on the bottom surface of the discharge box to discharge the cooling water introduced into the discharge box to the outside do.

More preferably, the discharge box is provided with a steam discharge pipe to discharge the steam generated in the cooling water heated by heat exchange in the space on the upper surface to the outside.

More preferably, the discharge box is provided with a overflow plate having a certain height so as to control the level of the coolant filled in the space up to a height corresponding to the top of the outer wall.

Preferably, an opening is provided between the upper edge of the inner box and the upper edge of the outer box so that the space communicates with the outside.

Preferably, the first partition wall is a horizontal plate for forming a first passage at an end in contact with the outer surface of the inner wall, and a vertical plate that is bent at a right angle from the end of the horizontal plate and fixed to the inner surface of the outer wall It includes.

More preferably, the first passage is provided with at least one recess formed in an end of the horizontal plate corresponding to the inner wall.

Preferably, the first passage is provided with at least one rectifying hole formed through the first partition wall.

Preferably, the second partition wall has at least one recess to add a third passage that forms a coolant flow in parallel with the second coolant flow at the other end facing the outer surface of the inner wall.

Preferably, the second passage is provided with at least one recess formed in one end of the second partition wall fixed to the inner surface of the outer wall.

Preferably, the second passage is formed of at least one rectifying hole formed through the second partition wall.

The present invention as described above has the following effects.

(1) The first and second partitions are provided between the inner wall of the inner box and the outer wall of the outer box so as to form a space in which the coolant is filled downward, and by the first passage formed between the first partition and the inner wall. By forming a first coolant flow in the upflow, and forming a second coolant flow in the lateral flow between the second partition and the outer wall, the coolant filled in the lower rotor of the space is gradually induced upward, and the first partition wall adjacent to each other Since the coolant filled between the two sides can be uniformly induced and discharged in the lateral direction, the cooling efficiency of the inner box heated by the combustion heat and the radiant heat of the combustion chamber can be increased, thereby preventing damage to the facility and deformation, and extending the service life. .

(2) By increasing the cooling efficiency of the inner box in which the incineration object is drop-supplied, it is possible to prevent the waste that is dropped and supplied to the inner surface of the inner wall from being attached and stuck. It is possible to operate the incinerator plant stably without facility shutdown.

1 is a schematic view showing a general incinerator.
2A and 2B are perspective views illustrating a water-cooled cooling chute for an incinerator according to a preferred embodiment of the present invention.
3A and 3B are partial cross-sectional perspective views illustrating a water-cooled cooling chute for an incinerator according to a preferred embodiment of the present invention.
Figure 4 is an exploded perspective view showing a water-cooled cooling chute for incinerators according to a preferred embodiment of the present invention.
5 is a cross-sectional view showing the first and second cooling water flow in the water-cooled cooling chute for incinerators according to a preferred embodiment of the present invention.
6A and 6B are perspective views showing another embodiment of the first partition wall employed in the water-cooled cooling chute for an incinerator according to a preferred embodiment of the present invention.
7A to 7B are state diagrams showing another embodiment of the second partition wall employed in the water-cooled cooling chute for an incinerator according to a preferred embodiment of the present invention.

The objects, features and advantages of the present invention described above will become more apparent from the following detailed description. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Water-cooled input chute 100 for incinerators according to a preferred embodiment of the present invention, as shown in Figures 2a to 4, a wide inlet hopper to inject the incineration object containing waste, and drying for the incineration object And an inner box provided between the combustion chambers in which combustion is performed, in order to prevent the overheating caused by the heat of combustion of the combustion chamber in the process of guiding the incineration object falling through the input hopper 101 to the combustion chamber. 110, an outer box 120, a cooling water supply unit 130, a cooling water discharge unit 140, and first and second partition walls 150 and 160.

The inner box 110 is a box structure having an approximately vertical passage so that the incineration object introduced from the outside through the input hopper passes through.

The inner box 110 is shown and described as being formed of a rectangular parallelepiped with the inner wall 112 is continuously connected to the four outer surface to form a passage on the rectangular cross-section, the upper and lower portions are not limited thereto. It can be made of a hollow park body.

The inner box 110 is preferably provided with upper and lower flanges 116 and 118 so as to be connected to the upper and lower ends of the input hopper, which is the upper structure, and to be interchangeably connected to the combustion chamber, which is the lower structure.

The outer box 120 is spaced apart by a predetermined interval formed by the inner wall 112 and the first partition wall 150 of the inner box 110 to form a space filled with the cooling water (a plurality of outer walls ( It is provided with a box 122 to surround the outer edge of the inner box (110).

The outer box 120 is provided in the same cross-section with the inner box, the outer wall is continuously connected to the outer wall corresponding to the inner wall 112, and shown as being made of a rectangular parallelepiped upper and lower open. However, the present invention is not limited thereto, and may include a hollow park cylinder assembled to an outer side of the inner box formed of the hollow park cylinder.

The outer box 120 penetrates a plurality of exposed exposure holes 124 for partially exposing the first partition wall 150 to the outer wall body 122 corresponding to the first partition wall 150. An operator welds the outside of the outer box along the contact area between the outer surface of the first partition wall 150 exposing the exposure hole 124 and the inner surface of the outer wall 122 to externally open the first partition wall 150. The wall 122 can be fixed in close contact.

 The coolant supply unit 130 has a coolant supply pipe 132 connected to at least one inlet 126 provided on an outer surface of a lower end of the outer wall 122 constituting the outer box 120 and the inner box. Cooling water is supplied to a space formed between the inner wall 112 of the 110 and the outer wall 122 of the outer box 120, and the coolant in a height direction parallel to the direction in which the incineration object falls from the lower portion of the space. You can slowly fill.

Here, the inlet 126 is provided at the center of each lower end of the outer wall (122, 122) facing each other of the outer box 120 to evenly supply the cooling water supplied to the lower portion of the space to the lower left and right sides of the space. It is preferable.

In addition, the outer edges of the outer wall 122 corresponding to the left and right sides of the inlet 126 have the total amount of coolant filled in the space between the inner wall 112 and the outer wall 122 when the equipment is stopped or repaired or replaced. A drain outlet 126 is provided to discharge the drain to the outside, and the drain outlet 128 is preferably installed to be close to the bottom of the space.

Here, the cooling water supply pipe is to supply the cooling water to the space between the inner wall 112 and the outer wall 122 at a constant intensity pressure to be supplied in accordance with the discharge discharged to the outside while gradually filling from the lower portion to the upper portion of the space. It is preferable to be connected to the cooling water supply pump.

The cooling water discharge unit 140 is connected to at least one discharge port 128 provided on an outer surface of an upper end of a plurality of outer walls 122 constituting the outer box 120 and the inner wall 112. ) Is discharged to the outside of the cooling water to be heat-exchanged to cool the inner box 110 is heated to a high temperature by the combustion heat and radiant heat of the combustion chamber after filling in the space between the outer wall (122).

The cooling water discharge unit 140 discharges the discharge box 141 communicating with the discharge port 128 and the cooling water introduced into the discharge box to discharge the cooling water filled up to the top of the space to the outside. The discharge pipe 142 is provided on the bottom surface of the box 141.

Here, one side surface facing the discharge port 128 formed through the outer wall 122 is formed to be formed in the upper surface of the discharge box 141 in which the cooling water is filled in the inner space, which is generated from the cooling water heated and heat-exchanged in the space. It is preferable to have a steam discharge pipe 143 to discharge the steam to the outside.

The discharge box 141 is introduced into the inner space to constantly control the discharge flow of the cooling water discharged to the outside through the discharge pipe to the height corresponding to the top of the outer wall 122 to the level of the coolant filled in the space It is preferable to provide a laminar flow plate 144 having a certain height so as to be controlled, and to form a notch at the upper end of the laminar flow plate 144.

On the other hand, between the upper edge of the inner box 110 and the upper edge of the outer box 120 is formed between the inner wall and the outer wall so that the space filled with the cooling water is in communication with the outside to be affected by atmospheric pressure The outer wall 122 is provided with a size that is relatively lower than the height of the inner wall 112 so that an opening having a predetermined size between the upper flange 116 of the inner box 110 and the upper end of the outer wall 122. It is preferable to form 149.

Here, the opening 149 which communicates the space with the outside to prevent the internal pressure of the space from being increased is illustrated and described as being formed in the entire area of the upper outer edge of the outer box 120, but is not limited thereto. It may be partially formed on the upper outer edge of the outer box 120.

The first partition wall 150 is formed between the inner wall 112 and the outer wall 122 and is provided in multiple layers horizontally with a predetermined interval between the inner wall and the outer wall to form a space filled with the cooling water. The partition member is provided continuously in the horizontal direction along the entire outer surface of the inner box.

The first partition wall 150 incinerates the object from the bottom to the top of the cooling water filled in the space by the first passage (P1) formed between the outer surface of the inner wall 112 and the end fixed in contact with the It is to form a first coolant flow which is an upward flow proceeding from the bottom to the top in a direction parallel to the direction.

That is, as shown in FIGS. 4 and 5, the first partition 150 recesses at least one recess 156 at an end contacting the outer surface of the inner wall 112 to form a first passage. A horizontal plate 152 and a vertical plate 154 that is bent at approximately right angles from an end of the horizontal plate 152 and fixedly adhered to the inner surface of the outer wall 122.

The horizontal plate 152 should be formed as an inclined surface at the end so that the horizontal plate 152 can be welded at a substantially right angle to the horizontal plate 152 of another adjacent first partition wall.

Here, the first passage P1 is illustrated and described as being formed of a plurality of grooves 156 open to the inner wall 112 side with a predetermined interval on the horizontal plate 152, but is not limited thereto. As illustrated in FIG. 6A, the horizontal plate 152 may be provided with a straight recess 156a formed therein, or as shown in FIG. 6B, or may be provided with at least one rectifying hole 156b formed therethrough. Can be.

The second partition wall 160 is disposed in the space up and down between the first partition wall 150 adjacent to each other in a substantially rectangular plate shape having a predetermined interval in the lateral direction that crosses at right angles with the upward flow of the coolant at approximately right angles. Partition wall member.

The second partition wall 160 has a cooling water filled between the first partition walls adjacent to each other by a second passage P2 formed between the outer surface of the outer wall 122 and one end facing the outer wall 122. Inducing and forming a second coolant flow that crosses the first coolant flow at approximately a right angle.

The second partition wall 160 has one end corresponding to the inner surface of the outer wall 122 being spaced apart at a predetermined interval, while the other end corresponding to the outer surface of the inner wall 112 is closely fixed. Although it is illustrated and described as being disposed between the first partition wall 150 adjacent to each other in close contact with the horizontal plate 152 of the first partition wall 150, but is not limited thereto and may be provided in various forms. .

As shown in FIG. 7A, the second partition 160 has at least one third path to form a coolant flow in parallel with a second coolant flow between the outer surface of the inner wall and the other end facing the inner wall. A recess 162 may be provided.

In addition, as shown in FIG. 7B, the second passage P2 is at least one recess 164 recessed at one end of the second partition wall 160 fixed to the inner surface of the outer wall 122. 7B, the at least one rectifying hole 166 may be provided through the second partition wall.

Here, the vertical plate 154 of the first partition wall 150 is cut out without being caught in the upper one side edge portion of the second partition wall 160 in which the outer ends perpendicular to the inner and outer wall bodies 112 and 122 are tightly fixed. Although it is preferable to form the portion 161, when the first partition wall 150 is provided with only the horizontal plate 152 without the need for the vertical plate 154, there is no need to form the cutout 161.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and changes are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

110: inner box 112: inner wall
120: outer box 122: outer wall
124: exposure hole for welding 126: injection hole
128: outlet 130: cooling water supply unit
140: cooling water discharge unit 141: discharge box
142: discharge pipe 143: steam discharge pipe
144: overflow plate 150: first bulkhead
152: horizontal plate 154: vertical plate
156: groove 160: second bulkhead

Claims (12)

In the incineration chute for incinerators provided between the input hopper and the combustion chamber to supply the incineration object to the combustion chamber,
An inner box having a passage through which the incineration object introduced through the input hopper falls;
An outer box having an outer wall spaced apart from the inner wall of the inner box at a predetermined interval;
A cooling water supply unit connected to at least one injection hole provided on an outer surface of a lower end of the outer box to supply cooling water to a space between the inner wall and the outer wall;
A coolant discharge part connected to at least one outlet provided on an outer surface of the upper end of the outer box to discharge the coolant heat exchanged in the space between the inner wall and the outer wall to the outside; And
A first coolant flow is formed in the space to form a first coolant flow which induces the coolant filled in the space upwards from a lower portion to an upper portion by a first passage formed between an outer surface of the inner wall and an end fixed to the inner wall; A plurality of first partition wall is provided along the multilayer; And
First partition walls adjacent to each other to form a second coolant flow to guide the cooling water filled between the first partition walls adjacent to each other by a second passage formed between the outer wall and one side end facing the outer wall body A second partition wall having a plurality of spaced intervals in a lateral direction therebetween; Water-cooled input chute for incinerator comprising a. The method of claim 1,
The outer box partially penetrates the first partition wall to the outer wall corresponding to the first partition wall, and penetrates to weld along the contact portion between the outer surface of the partially exposed first partition wall and the inner surface of the outer wall wall. Water-cooled input chute for incinerators comprising a plurality of exposed exposure holes for welding. The method of claim 1,
The cooling water discharge unit includes a discharge box having an inner space in communication with the discharge port is filled with the cooling water, and a discharge pipe provided on the bottom surface of the discharge box to discharge the cooling water introduced into the discharge box to the outside. Water-cooled chute for incinerators. The method of claim 3,
The discharge box is a water-cooled input chute for an incinerator, characterized in that the upper surface has a steam discharge pipe to discharge the steam generated in the cooling water heated by heat exchange in the space to the outside. The method of claim 3,
The discharge box is a water-cooled input chute for incinerator, characterized in that it comprises a overflow plate having a certain height so as to control the level of the coolant filled in the space up to the height corresponding to the top of the outer wall. The method of claim 1,
An incineration water cooling chute for an incinerator, wherein an opening is provided between the upper edge of the inner box and the upper edge of the outer box so that the space communicates with the outside. The method of claim 1,
The first partition wall includes a horizontal plate forming a first passage at an end in contact with the outer surface of the inner wall, and a vertical plate bent at right angles from an end of the horizontal plate and fixed to the inner surface of the outer wall. Water-cooled input chute for incinerators, characterized in that. The method of claim 7, wherein
The first passage is water-cooled input chute for incinerators, characterized in that provided with at least one recess formed in the end of the horizontal plate corresponding to the inner wall. The method of claim 1,
The first passage is water-cooled input chute for incinerators, characterized in that provided with at least one rectifying hole formed through the first partition wall. The method of claim 1,
The second partition wall has at least one groove to add a third passage to form a coolant flow in parallel with the second coolant flow at the other end facing the outer surface of the inner wall water-cooled incinerator Input chute. The method of claim 1,
The second passage is water-cooled input chute for incinerator, characterized in that provided with at least one recess formed in one side end of the second partition wall fixed to the inner surface of the outer wall. The method of claim 1,
The second passage is water-cooled input chute for incinerator, characterized in that provided with at least one rectifying hole formed through the second partition wall.

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