KR102625230B1 - Fire grate block, stocker type fire grate apparatus, stocker type incinerator and system for incinerating waste - Google Patents

Abstract

According to one aspect of the present invention, a pair of side walls disposed opposite each other on one side, an upper wall coupled to cover an upper end of the pair of side walls, and extending from the upper wall to cover a front end of the pair of side walls. It includes a front wall that is coupled, and a coupling portion formed at a rear end of the pair of side walls and coupled to the grate support, and the lower portion is opened to the inside by the pair of side walls, the upper wall, the front wall, and the coupling portion. A linear grate block body dividing the flow space; a partition extending downward from the bottom of the upper wall into the flow space to divide the flow space in the longitudinal direction; A grate block is provided, which is formed on the front wall to correspond to each of the divided flow spaces and includes a plurality of spray nozzles having different formation heights.

Description

Fire grate block, stocker type fire grate apparatus, stocker type incinerator and system for incinerating waste}

The present invention relates to grate blocks, stoker-type grates, stoker-type incinerators and waste incineration systems. More specifically, it relates to a grate block, a stoker-type grate device, a stoker-type incinerator, and a waste incineration system that has high cooling efficiency by combustion air and can efficiently supply combustion air to waste.

The generation of waste has increased with the increase in population and industrial development, and technologies to manage and dispose of such waste in an environmentally or hygienic manner are needed.

Until recently, most waste was being disposed of through landfill. However, not only is it difficult to secure a landfill, but if it is not managed intensively for several decades, the landfill will continue to become a source of secondary pollution, causing environmental pollution. Recently, the number of incineration facilities that can dispose of waste hygienically and safely has been increasing.

Waste disposal methods through incineration can be classified into various types depending on the type of waste and calorific value. Among these, the stoker-type incinerator is easy to construct as it spreads the waste on a grate and incinerates it, and has a range from low calorific value to high calorific value. It has the advantage of being able to incinerate a wide range of solid waste, including waste.

The stoker-type incinerator installs a grate in the combustion chamber in which rows of fixed grates and rows of movable grates are arranged alternately in a staircase, and incinerates the waste placed on the grate as the movable grate row moves the waste back and forth. At this time, the incineration of waste is controlled by blowing combustion air while controlling the supply amount of combustion air at the bottom of the grate.

Combustion air supplied from the lower part of the grate cools the high-temperature grate and is supplied to waste at the top of the grate through slits formed by adjacent grate blocks, and also through combustion air injection nozzles formed on the front wall of the grate. Incineration is carried out by feeding the waste placed in front of the grate.

Therefore, it is necessary to increase the cooling efficiency by combustion air for the individual grate blocks that make up the grate where incineration is performed at high temperatures, and there is a need to develop technology to efficiently supply combustion air to waste.

Republic of Korea Patent Publication No. 10-2022-0138653 (published on October 13, 2022)

The present invention provides a grate block, a stoker-type grate device, a stoker-type incinerator, and a waste incineration system that has high cooling efficiency by combustion air and can efficiently supply combustion air to waste.

According to one aspect of the present invention, a pair of side walls disposed opposite to each other on one side, an upper wall coupled to cover an upper end of the pair of side walls, and extending from the upper wall to cover a front end of the pair of side walls. It includes a front wall coupled to the rear end of the pair of side walls and a coupling portion coupled to the grate support, and the pair of side walls, the upper wall, the front wall, and the coupling portion open the lower part to the inside. a linear grate block body in which the flow space is divided; a partition extending downward from the bottom of the upper wall into the flow space to divide the flow space in the longitudinal direction; A grate block is provided, which is formed on the front wall to correspond to each of the divided flow spaces and includes a plurality of spray nozzles having different formation heights.

Cooling fins may be formed to protrude from the opposing inner surfaces of the side walls and the partition wall of the flow space so that the grate block body is cooled according to the flow of air in the flow space, so as to be staggered.

The cooling fins may be formed to be inclined toward the front wall so that the air is guided to the inner surface of the front wall along the flow space.

The spray nozzle may be formed in a cone shape so that its cross-section is reduced in the direction from the inner surface to the outer surface of the front wall so that air introduced to the inner surface of the front wall passes with a flow rate.

The spray nozzle may be formed to be inclined downward.

A gap maintaining protrusion may be formed on at least one of the pair of side walls so that a long slit through which air passes is formed between the side walls of the grate block main body disposed adjacent to each other.

A chamfer may be formed in the longitudinal direction on the outer side of the lower end of the side wall so that the inlet of the slit is enlarged when the grate block is continuously disposed.

The lower end of the side wall may be alternately formed with recessed portions in a trapezoidal shape in the upper direction along the longitudinal direction and mountain-shaped portions in a trapezoidal shape in the lower direction.

Chamfers may be formed on the outer side of the upper end of the recessed portion and on the outer side of the lower end of the mountain-shaped portion in the longitudinal direction to enlarge the inlet of the slit when the grate blocks are sequentially disposed.

According to another aspect of the present invention, there is provided a fixed grate row in which the grate blocks are arranged continuously so that their side surfaces are adjacent to each other; A stoker-type grate device includes a movable grate row that reciprocates in a straight line at the top of the fixed grate row and the grate blocks are arranged continuously so that the sides are adjacent to each other, wherein the fixed grate row and the movable grate row form alternating steps. provided.

In addition, according to another aspect of the present invention, a combustion chamber in which a waste inlet is formed on one side, an incineration outlet is formed on the other side, and a combustion gas exhaust port is formed on the upper side; A fixed grate row located at the lower part of the combustion chamber, in which the grate blocks are continuously arranged so that the sides are adjacent to each other, and a movable grate row in which the grate blocks are continuously arranged so that the sides are adjacent to each other, and moves straight back and forth on the upper part of the fixed grate row. A stoker-type incinerator is provided that includes a stoker-type grate row, wherein the fixed grate row and the movable grate row form alternating steps.

Meanwhile, according to another aspect of the present invention, a combustion chamber in which a waste inlet is formed on one side, an incineration outlet is formed on the other side, and a combustion gas exhaust port is formed on the upper side; A fixed grate row located at the lower part of the combustion chamber, in which the grate blocks are continuously arranged so that the sides are adjacent to each other, and a movable grate row in which the grate blocks are continuously arranged so that the sides are adjacent to each other, and moves straight back and forth on the upper part of the fixed grate row. A stoker-type grate device including a grate row, wherein the fixed grate row and the movable grate row form alternating steps; a waste heat boiler that communicates with the combustion gas exhaust port and recovers waste heat from the combustion gas through heat exchange; a semi-dry reaction tower for removing acidic gas from the combustion gas that has passed through the waste heat boiler; a filtering dust collector that removes dust from the combustion gas that has passed through the semi-dry reaction tower; A waste incineration system is provided, including an induced blower that exhausts the combustion gas passing through the filter dust collector to the outside air.

The waste incineration system is disposed behind the filter dust collector and may further include a selective catalytic reaction tower that removes nitrogen oxides (NOx) from the combustion gas that has passed through the filter dust collector.

The grate block according to an embodiment of the present invention has high cooling efficiency by combustion air and can efficiently supply combustion air to waste.

1 is a diagram illustrating a waste incineration system including a stoker-type incinerator including a grate block according to an embodiment of the present invention.
Figure 2 is a diagram showing a stoker-type incinerator including a grate block according to an embodiment of the present invention.
Figure 3 is a view showing a portion of a stoker-type grate device including a grate block according to an embodiment of the present invention.
Figure 4 is a perspective view of a grate block according to an embodiment of the present invention.
Figure 5 is a side view of a grate block according to an embodiment of the present invention.
Figure 6 is a view of a grate block according to an embodiment of the present invention viewed from the back.
Figure 7 is a front view of a grate block according to an embodiment of the present invention.
Figure 8 is a cross-sectional view of the tip of a grate block according to an embodiment of the present invention.
Figure 9 is a diagram for explaining a method of supplying combustion air to a grate block according to an embodiment of the present invention.
Figure 10 is a side view of a grate block according to another embodiment of the present invention.
Figure 11 is a diagram for explaining a method of supplying combustion air to a grate block according to another embodiment of the present invention.

Since the present invention can be modified in various ways and can have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all transformations, equivalents, and substitutes included in the spirit and technical scope of the present invention. In describing the present invention, if it is determined that a detailed description of related known technologies may obscure the gist of the present invention, the detailed description will be omitted.

Hereinafter, the grate block, stoker-type grate device, stoker-type incinerator and waste incineration system according to the present invention will be described in detail with reference to the attached drawings. In the description with reference to the attached drawings, the same or corresponding components are shown. will be assigned the same drawing number and overlapping description will be omitted.

1 is a diagram illustrating a waste incineration system including a stoker-type incinerator including a grate block according to an embodiment of the present invention. And, Figure 2 is a diagram showing a stoker-type incinerator including a grate block according to an embodiment of the present invention, and Figure 3 is a diagram showing a part of a stoker-type incinerator including a grate block according to an embodiment of the present invention. This is a drawing.

1 to 3, a stoker-type incinerator 10, a stoker-type grate device 11, an inlet 12, a combustion gas outlet 13, a combustion chamber 14, an outlet 15, a grate block 16, Support rod (17), fixed grate row (18), movable grate row (20), waste heat boiler (46), semi-dry reaction tower (48), filter dust collector (50), selective catalytic reaction tower (52), induced blower (54) ), the chimney 56 is shown.

Before describing the grate block 16 according to the present embodiment, with reference to FIGS. 1 to 3, a stoker-type grate device 11, a stoker-type incinerator 10 and a waste incineration system in which the grate block 16 is used. Let's take a look at.

As shown in FIG. 2, the Stoker-type incinerator 10 has a combustion chamber 14 inside which is made of a refractory wall or a water pipe wall. An inlet 12 through which waste is input is formed on one side of the combustion chamber 14, an incinerated material outlet 15 is formed on the other side, and a combustion gas exhaust port 13 is formed on the upper side. And, a stoker-type grate device 11 including a grate block 16 according to this embodiment is installed at the lower part of the combustion chamber 14.

Combustion air is supplied from the lower part of the stoker-type grate device 11, and the combustion air is supplied through a slit 36 formed by adjacent grate blocks 16 and a spray nozzle formed on the front of the grate block 16 ( 28) is supplied to the waste.

Combustion air passing through the slit 36 is supplied from the lower part of the waste placed on top of the grate 11, and combustion air passing through the injection nozzle 28 is supplied to the waste placed in front of the grate block 16. In order to incinerate waste efficiently, combustion air must be efficiently supplied into the waste through the slit 36 and the injection nozzle 28.

The waste injected into the combustion chamber 14 through the inlet 12 is incinerated as it advances to the rear end by the grating device 11, and the incinerated material generated after incineration is in the form of ash through the discharge port 15 at the end. is discharged to the outside. The combustion gas generated during incineration is exhausted through the combustion gas exhaust port 13 at the top, undergoes environmental treatment during the exhaust process, and is finally discharged through the chimney 56.

1 shows a waste incineration system comprising a stoker-type incinerator 10 comprising a grate block 16 according to the present embodiment. Referring to FIG. 1, various treatment devices for environmentally treating combustion gas are disposed at the rear of the Stoker-type incinerator 10.

The waste incineration system according to this embodiment includes a combustion chamber 14 in which a waste inlet 12 is formed on one side, an incineration outlet 15 is formed on the other side, and a combustion gas exhaust port 13 is formed on the upper side, and the combustion chamber It includes a fixed grate row (18) located at the lower part of (14) and a movable grate row (20) that moves linearly in the upper part of the fixed grate row (18), and includes a fixed grate row (18) and a movable grate row (20). ) a stoker-type incinerator (10) including a stoker-type grating device (11) in alternating steps; a waste heat boiler (46) that communicates with the combustion gas exhaust port (13) of the combustion chamber (14) and recovers waste heat from the combustion gas through heat exchange; a semi-dry reaction tower (48) for removing acid gas from combustion gas that has passed through the waste heat boiler (46); A filtering dust collector (50) that removes dust from the combustion gas that has passed through the semi-dry reaction tower (48); It includes an induced blower 54 that discharges combustion gas passing through the filter dust collector 50 to the outside air.

The combustion gas exhausted from the combustion gas exhaust port 13 of the above-described stoker-type incinerator 10 may undergo secondary combustion at the top of the incinerator 10, and the secondary combustion gas flows into the waste heat boiler 46. . At this time, the temperature of the combustion gas flowing into the waste heat boiler 46 reaches approximately 850 to 1,100°C. Dioxin production can be suppressed by maintaining the temperature of the combustion gas flowing into the waste heat boiler 46 at 850°C or higher.

In the waste heat boiler 46, high-temperature waste heat of combustion gas is recovered through heat exchange. Water is heated with the waste heat of combustion gas to produce steam, and the produced steam is sent to a cogeneration facility to produce electricity or district heating. It is used. The temperature of the combustion gas passing through the waste heat boiler 46 is approximately 200 to 240° C., and in the process of recovering waste heat in the waste heat boiler 46, the combustion gas is cooled below the resynthesis temperature of dioxins, etc.

A semi dry reactor (SDR, 48) removes acidic gas from the cooled combustion gas as it passes through the waste heat boiler (46). In the reaction tower, an acidic gas neutralizer such as slaked lime slurry is sprayed onto the combustion gas to initially remove the acidic gas.

The filter dust collector 50 removes dust from the combustion gas that has passed through the semi-dry reaction tower 48. The filtration dust collector 50 includes a bag filter and removes dust such as powder slaked lime residue and activated carbon residue contained in combustion gas through the bag filter, as well as secondary removal of acid gas and removal of dioxins and heavy metals. can do.

The combustion gas that has undergone environmental treatment while passing through the filter dust collector 50 is finally exhausted through the chimney 56 by blowing from the manned blower 54.

Recently, as interest in the environment has increased, environmental regulations have been strengthened, and nitrogen oxides (NOx) in combustion gas can be removed again by placing a selective catalytic reaction tower 52 behind the filter dust collector 50.

In the Selective Catalytic Reduction (SCR, 52), nitrogen oxides can be removed through the catalyst layer by an ammonia reduction reaction.

The waste heat boiler (46), semi-dry reaction tower (48), filter dust collector (50), and selective catalytic reaction tower (52) that perform environmental treatment of the combustion gases that have passed through the incinerator can use products that are widely known on the market. there is.

Figure 3 shows a stoker-type grate device 11 including a grate block 16 according to the present embodiment. The stoker-type grate device (11) includes a fixed grate row (18) in which grate blocks (16) are continuously arranged so that the sides are adjacent to each other, and a grate block that moves in a straight line on the upper part of the fixed grate row (18) so that the sides are adjacent to each other. (16) includes rows of movable grates (20) arranged in series, and these fixed grate rows (18) and movable grate rows (20) are arranged alternately in steps.

Although FIG. 3 shows two fixed grate rows 18 and one movable grate row 20, the fixed grate row 18 and the movable grate row 20 may be arranged sequentially in the form of steps.

The grate blocks 16 forming the grate rows 18 and 20 are installed with the coupling grooves 32 across the support bars 17 of the grate support extending in the horizontal direction, and are movable by moving the support bars 17 in a straight line. The grate row 20 can be moved in a straight line.

As the movable grate row 20 moves in a straight line with respect to the fixed grate row 18, the waste placed on top of the fixed grate row 18 is moved forward by the front wall 26 of the movable grate row 20.

When the grate blocks 16 are placed continuously while the coupling groove 32 of the grate block 16 spans the support bar 17, the grate block 16 is formed by the gap maintaining protrusion 34 formed on the side of the grate block 16. A thin slit 36 (slit) is formed in between, and combustion air supplied from the lower part of the grating device 11 passes through the slit 36 and is supplied into the waste placed on top of the slit 36.

Meanwhile, the combustion air supplied from the bottom cools the grate block 16 while moving through the flow space 29 of the grate block 16, and the combustion air moving through the flow space 29 flows through the injection nozzle 28. It is supplied with waste placed in front of the grate block (16).

Hereinafter, the grate block 16 according to this embodiment will be examined in detail with reference to FIGS. 4 to 8.

Figure 4 is a perspective view of a grate block according to an embodiment of the present invention, Figure 5 is a side view of a grate block according to an embodiment of the present invention, and Figure 6 is a grate block according to an embodiment of the present invention. is a view viewed from the back, Figure 7 is a view of the grate block according to an embodiment of the present invention viewed from the front, and Figure 8 is a cross-sectional view of the tip of the grate block according to an embodiment of the present invention.

4 to 8, a stoker-type incinerator 10, a stoker-type grate device 11, an inlet 12, a combustion chamber 14, a grate block 16, a flow space 29, and a grate block main body 21. , side wall 22, upper wall 24, front wall 26, spray nozzle 28, coupling portion 30, coupling groove 32, gap maintaining protrusion 34, slit 36, partition wall ( 38), cooling fins 39, and chamfers 40 are shown.

The grate block 16 according to this embodiment includes a pair of side walls 22 with one side facing each other, an upper wall 24 coupled to cover the top of the pair of side walls 22, and an upper wall. It includes a front wall 26 extending from (24) and coupled to cover the front end of the pair of side walls 22, and a coupling portion 30 formed at the rear end of the pair of side walls 22 and coupled to the grate support. , a linear grate block body (21) in which a flow space (29) open at the bottom is defined by a pair of side walls (22), an upper wall (24), a front wall (26), and a coupling portion (30). and; a partition 38 extending downward from the bottom of the upper wall 24 into the flow space 29 and dividing the flow space 29 in the longitudinal direction; It is formed to correspond to each of the flow spaces 29 divided into the front wall 26 and includes a plurality of spray nozzles 28 having different formation heights.

4 to 6, a linear block with an open bottom inside the grate block body 21 is formed by a pair of side walls 22, an upper wall 24, a front wall 26, and a coupling portion 30. A long flow space 29 is formed. This flow space 29 is a flow passage for combustion air supplied from the lower part of the grate block 16, and cools the grate block 16 during the combustion air flow process, and the combustion air flowing forward is directed to the front wall 26. It is sprayed as waste through a spray nozzle 28 formed in .

Referring to FIGS. 4 to 6, the pair of side walls 22 are arranged so that one side faces each other, and the upper wall 24 is coupled to cover the top of the pair of side walls 22 arranged to face each other. , the front wall 26 extends from the upper wall 24 and is coupled to cover the front end of the pair of side walls 22. In addition, a coupling portion 30 coupled to the grate support is formed at the rear end of the pair of side walls 22, so that the pair of side walls 22, the upper wall 24, the front wall 26, and the coupling portion 30 A linear, long flow space 29 with an open bottom is formed inside the grate block body 21.

The flow space 29 of the grate block 16 is divided in the longitudinal direction by a partition wall 38, which extends downward from the bottom of the upper wall 24 to the flow space 29 to form the flow space 29. Divide in the longitudinal direction. In this embodiment, the flow space 29 is divided into two long spaces by one partition 38. Considering the width of the grate block 16, etc., one or more partition walls 38 are provided. It may be installed.

Combustion air supplied from the lower part of the grate block 16 is divided by the partition wall 38 and moves to the front wall 26 along each of the separated flow spaces 29. The reason for separating the flow spaces 29 by the partition wall 38 is to efficiently inject combustion air through the injection nozzle 28 corresponding to each flow space 29.

The injection nozzles 28 are formed to correspond to each of the flow spaces 29 divided into the front wall 26, and the formation heights of the injection nozzles 28 are different from each other.

In the present invention, the formation height of the spray nozzle 28 formed corresponding to each flow space 29 was varied. Referring to FIG. 7, the spray nozzle 28 formed on the front of the left flow space 29 of FIG. 7 is located above the spray nozzle 28 formed on the front of the right flow space 29.

This is to increase combustion efficiency by increasing the contact area of the waste by supplying the combustion air to the upper and lower parts instead of spraying it only in one direction when the combustion air is supplied to the waste from the front.

And, as shown in FIG. 8, the injection nozzle 28 according to the present embodiment has a cross-section from the inner surface of the front wall 26 to the outer surface so that the air introduced to the front wall 26 passes with a flow rate. It is formed in a cone shape to be reduced.

Combustion air that reaches the front wall 26 through the flow space 29 passes through the conical injection nozzle 28, which has an inlet with a large cross-section and an outlet with a small cross-section, and the flow rate increases, which causes the grate block 16 The cooling efficiency of the front can be improved and clinker can be prevented from being generated in the spray nozzle 28.

And, referring to FIG. 8, the injection nozzle 28 is inclined overall downward, which is intended to increase combustion efficiency and induce complete combustion by allowing combustion air to reach the ignition point located at the bottom of the waste.

Meanwhile, cooling fins 39 are provided on the inner surface of the side wall 22 and the partition wall 38 of the opposing flow space 29 so that the grate block body 21 is cooled according to the flow of air in the flow space 29 so as to be staggered. It may be formed to protrude.

Referring to FIG. 6, the combustion air supplied from the lower part of the grate block 16 moves along the separated flow space 29. At this time, the heat transfer area of the combustion air is increased by the cooling fins 39 during the combustion air flow process. As a result, the cooling efficiency of the grate block 16 can be increased, and as a result, thermal expansion and wear of the upper part of the grate device 11 due to combustion heat can be minimized.

In this embodiment, the cooling fins 39 described above are inclined toward the front wall 26 so that air is guided to the inner surface of the front wall 26 along the flow space 29. Referring to FIG. 6, the cooling fins 39 formed on the inner surface of the side wall 22 and the inner surface of the partition wall 38 opposing it are formed at an angle while crossing each other toward the front wall 26 to flow into each flow space 29. The combustion air flows in a wave shape to the front wall 26 by the inclined cooling fins 38, efficiently cooling the grate block 16.

And, referring to FIGS. 4 and 9, the grate block body 21 is formed so that a long slit 36 through which air passes is formed between the side walls 22 of the grate block body 21 disposed adjacent to each other. A gap maintaining protrusion 34 may be formed on at least one of the pair of side walls 22.

As shown in FIG. 3, the grate blocks 16 are arranged continuously so that the side surfaces are adjacent to each other to form the grate rows 18 and 20. At this time, the grate blocks (16) are adjacent to each other by the gap maintaining protrusion 34. A long slit 36 is formed between the side walls 22 of 16). Combustion air supplied from the lower part of the grating device 11 passes through this long slit 36 and is supplied to the waste placed on the upper part of the grating device 11.

In this embodiment, in order to increase the amount of combustion air flowing into the slit 36 and increase its flow rate, a chamfer 40 is formed in the longitudinal direction on the outer side of the lower end of the side wall 22 of the grate block body 21. did.

Figure 9 is a diagram for explaining the combustion air supply method of the grate block 16 according to the present embodiment. Referring to Figure 9, the grate blocks 16 are sequentially formed to form grate rows 18 and 20. When placed, a slit 36 is formed between the grate blocks 16 by the gap maintaining protrusion 34, and the long chamfer 40 at the bottom of the side wall 22 of the grate block 16 separates two grate blocks ( The inlet of the slit 36 formed by 16) is enlarged into a V-cut shape. Due to the enlarged inlet of the slit 36, the amount of combustion air supplied from the bottom increases into the slit 36, and as a result, the flow rate of the combustion air increases and the cooling efficiency of the grate block 16 increases. Combustion air can be efficiently supplied to the waste located at the top of the grating device (11).

Figure 10 is a side view of the grate block 16 according to another embodiment of the present invention, and Figure 11 is a view for explaining the combustion air supply method of the grate block 16 according to another embodiment of the present invention. .

10 and 11, the side wall 22, the upper wall 24, the front wall 26, the coupling portion 30, the defect groove portion 32, the chamfer 40, the recessed portion 42, and the mountain-shaped portion ( 44) is shown.

Unlike the grate block according to the above embodiment, the grate block 16 according to the present embodiment has a recessed portion 42 that is recessed in a trapezoidal shape upward along the longitudinal direction at the lower end of the side wall 22 of the grate block 16. ) and mountain-shaped portions 44 in the shape of a trapezoid are formed alternately in the downward direction.

At this time, as shown in FIGS. 10 and 11, the inlet of the slit 36 is enlarged outside the upper end of the recessed portion 42 and the lower end of the mountain-shaped portion 44 when the grate blocks 16 are sequentially placed. A chamfer 40 is formed in the longitudinal direction.

According to the above embodiment, since the side walls 22 of the grate blocks 16 facing each other are the same in length, the combustion air flowing into the inlet of the slit 36 formed by the chamfer 40 can be considered to be approximately the same. However, according to the present embodiment, the inlet of the slit 36 formed by the opposing recessed portions 42 is inclined to the inner side with respect to the inlet of the slit 36 formed by the opposing mountain-shaped portions 44. Because it is located, more combustion air supplied from the bottom flows in along the slope of the trapezoidal recessed portion 42 compared to the mountain-shaped portion 44.

Therefore, the amount of combustion air passing through the slit 36 on the upper side of the depression 42 is greater than the amount of combustion air passing through the slit 36 on the upper side of the mountain-shaped portion 44, resulting in combustion at a faster flow rate on the upper side of the depression 42. By supplying air, the cooling efficiency of the grate block 16 and the efficiency of continuous air supply can be improved.

Although the present invention has been described above with reference to embodiments, those skilled in the art can modify the present invention in various ways without departing from the spirit and scope of the present invention as set forth in the claims below. It will be easy to understand that and can be changed.

10: Stalker-type incinerator 11: Stalker-type fire apparatus
12: Inlet 13: Combustion gas exhaust port
14: combustion chamber 15: outlet
16: grate block 17: support rod
18: fixed grate row 29: floating space
20: Movable grate column 21: Grate block body
22: side wall 24: top wall
26: front wall 28: spray nozzle
30: coupling portion 32: coupling groove portion
34: gap maintenance protrusion 36: slit
38: bulkhead 39: cooling fin
40: Chamfer 42: Indentation
44: Mountain section 46: Waste heat boiler
48: semi-dry reaction tower 50: filter dust collector
52: selective catalytic reaction tower 54: induced blower
56: chimney

Claims (13)

A pair of side walls disposed opposite to each other, an upper wall coupled to cover the top of the pair of side walls, a front wall extending from the upper wall and coupled to cover a front end of the pair of side walls, and It is formed at the rear end of a pair of side walls and includes a coupling part coupled to the grate support, and a flow space with a lower portion open inside is defined by the pair of side walls, the upper wall, the front wall, and the coupling part. a grate block body;
a partition extending downward from the bottom of the upper wall into the flow space to divide the flow space in the longitudinal direction;
It is formed on the front wall to correspond to each of the divided flow spaces and includes a plurality of spray nozzles having different formation heights,
A gap maintaining protrusion is formed on at least one of the pair of side walls so that a long slit through which air passes is formed between the side walls of the grate block main body disposed adjacent to each other,
A grate block, characterized in that the lower end of the side wall is alternately formed with recessed portions in the upper direction along the longitudinal direction in a trapezoidal shape and trapezoidal mountain-shaped portions in the lower direction.
According to paragraph 1,
A grate block, characterized in that cooling fins are formed to protrude in a staggered manner on the inner surface of the side wall and the partition wall of the flow space facing each other so that the grate block main body is cooled according to the flow of air in the flow space.
According to paragraph 2,
A grate block, wherein the cooling fins are formed to be inclined toward the front wall so that the air is guided to the inner surface of the front wall along the flow space.
According to paragraph 3,
A grate block, characterized in that the spray nozzle is formed in a cone shape so that its cross-section is reduced in the direction from the inner surface of the front wall to the outer surface so that the air introduced to the inner surface of the front wall passes with a flow rate.
According to clause 4,
A grate block, characterized in that the spray nozzle is formed with a downward slope.
delete According to paragraph 1,
A grate block, characterized in that a chamfer is formed in the longitudinal direction on the outer side of the lower end of the side wall so that the inlet of the slit is enlarged when the grate block is continuously disposed.
delete According to paragraph 1,
A grate block, characterized in that a chamfer is formed on the outer side of the upper end of the recessed portion and the lower end of the mountain-shaped portion in the longitudinal direction to enlarge the inlet of the slit when the grate block is continuously disposed.
a fixed grate row in which the grate blocks according to any one of claims 1 to 5, 7, and 9 are arranged continuously so that the sides are adjacent to each other;
It includes a movable grate row in which the grate blocks according to any one of claims 1 to 5, 7, and 9 are continuously arranged so that the sides are adjacent to each other, and , A stoker-type grate device in which the fixed grate rows and the movable grate rows alternately form steps.
a combustion chamber in which a waste inlet is formed on one side, an incineration outlet is formed on the other side, and a combustion gas exhaust port is formed on the upper side;
A fixed grate row located at the lower part of the combustion chamber and in which the grate blocks according to any one of claims 1 to 5, 7, and 9 are continuously arranged so that the sides are adjacent to each other, and an upper part of the fixed grate row. It includes a movable grate row in which the grate blocks according to any one of claims 1 to 5, 7, and 9 are arranged continuously so that the sides are adjacent to each other, and the fixed grate row and A stoker-type incinerator comprising a stoker-type grate device in which the rows of movable grates form alternating steps.
a combustion chamber in which a waste inlet is formed on one side, an incineration outlet is formed on the other side, and a combustion gas exhaust port is formed on the upper side;
A fixed grate row located at the lower part of the combustion chamber and in which the grate blocks according to any one of claims 1 to 5, 7, and 9 are continuously arranged so that the sides are adjacent to each other, and an upper part of the fixed grate row. It includes a movable grate row in which the grate blocks according to any one of claims 1 to 5, 7, and 9 are arranged continuously so that the sides are adjacent to each other, and the fixed grate row and a stoker-type grate device in which the rows of movable grates form alternating steps;
a waste heat boiler that communicates with the combustion gas exhaust port and recovers waste heat from the combustion gas through heat exchange;
a semi-dry reaction tower for removing acidic gas from the combustion gas that has passed through the waste heat boiler;
a filtering dust collector that removes dust from the combustion gas that has passed through the semi-dry reaction tower;
A waste incineration system comprising an induced blower that discharges the combustion gas passing through the filter dust collector to the outside air.
According to clause 12,
A waste incineration system disposed at a rear end of the filter dust collector and further comprising a selective catalytic reaction tower for removing nitrogen oxides (NOx) from the combustion gas that has passed through the filter dust collector.