JP5016470B2 - Melting furnace and waste treatment system - Google Patents

Description

  The present invention relates to a melting furnace for treating waste such as municipal waste.

  2. Description of the Related Art Conventionally, a waste disposal apparatus that includes a melting furnace that melts ash in pyrolysis gas generated by thermal decomposition of waste is known.

  As the melting furnace, for example, Patent Document 1 discloses a melting furnace B10 connected to a gasification furnace B6 as shown in FIG. The melting furnace B10 has a melting part B12, a discharge part B14, and a chute B20.

The melting part B12 melts the ash content of the pyrolysis gas of the waste to generate slag. The chute B20 discharges the slag generated in the melting part B12 downward, and has a substantially cylindrical shape extending downward. The discharge part B14 guides the high-temperature gas discharged from the melting part B12 to a boiler or the like, and the bottom surface B14b is substantially the same height as the bottom surface B12b of the melting part B12 downstream of the melting part B12. It is provided as follows. The slag generated in the melting part B12 is discharged to the chute B20, and the high-temperature gas discharged from the melting part B12 is guided to a boiler or the like via the discharge part B14. Here, the bottom surface B12b of the melting part B12 is provided with an overhanging part B15 protruding inside the chute B20, and the slag generated in the melting part B12 is caused from the inner surface of the chute B20 by the overhanging part B15. It is discharged into the chute B20 at a separated position.
JP 2006-194486 A

  In the conventional melting furnace B10, a part of the slag discharged from the inside of the chute B20 by the overhanging portion B15 is scattered on the inner side surface of the chute B20 while flowing down in the chute B20, and the inside of the chute B20. May stick to the side. The possibility of adhesion of this slag becomes higher as the vertical dimension of the chute B20 is larger than the projecting dimension of the projecting part B15. And if the slag adhering to the inner surface of the chute B20 grows, it becomes difficult for the new slag to flow down from the upstream. Therefore, it is necessary to remove the adhering slag. This removal operation is difficult and time consuming. Therefore, in the conventional melting furnace B10, the slag removal work takes time and the operation efficiency is poor.

  In view of such circumstances, an object of the present invention is to provide a melting furnace that can increase the operation efficiency by suppressing the adhesion of slag to a chute with a simple configuration.

The invention according to claim 1 for solving the above problem is a melting furnace for melting ash in pyrolysis gas generated by pyrolyzing waste, wherein the waste in pyrolysis gas of the waste A melting part that burns and melts ash to generate slag; a chute that is provided downstream of the melting part and that extends downward and surrounds the slag that flows down from the melting part; and the chute from the melting part A discharge portion for guiding the high temperature gas led out to the outside of the furnace from the chute, the melting portion communicates with the chute to flow down the slag to the chute and lead the hot gas to the chute An outlet port, a melting portion side inclined portion connected to the outlet port and inclined downward toward the outlet port to guide the slag to the chute side, and the melting portion side inclined portion A melting part side projecting part that projects from the lower end toward the inside of the chute and causes the slag to flow down the melting part side inclined part to the chute from the inside of the chute, Below, an intermediate projecting portion is provided that projects from the inner surface of the chute toward the inside of the chute, and flows down the slag that has flowed down from the melted portion side projecting portion at a position separated from the inner surface of the chute , the intermediate expansion part is characterized in Rukoto which have a shape which is inclined downward toward the inside from the inner surface of the chute so as to guide the slug inside the chute (claim 1).

  In this melting furnace, first, the melting part side projecting part guides the slag flowing down the melting part side inclined part to the inside of the chute, so that the outlet of the melting part connected to the melting part side inclined part is provided. The adhesion of slag to the side surface of the chute in the vicinity is suppressed. Then, an intermediate projecting portion provided below the melted portion side projecting portion guides the slag to the inside of the chute again, so that the slag discharged from the melted portion side inclined portion into the chute is in the middle of dropping. Even if the slag is scattered on the side surface of the chute, the slag is prevented from adhering to the inner surface of the chute. This suppresses adhesion of slag to the entire side surface of the chute, and hence sticking of the slag, reduces the frequency of removing the slag, and increases operating efficiency.

  Here, if the overhanging portion dimension of the melting portion side overhanging portion is set to be small in order to ensure the flow path area in the chute, the melting portion side overhanging portion does not sufficiently guide the slag to the inside of the chute, The slag is likely to be scattered on the chute side surface on the lower side of the melted portion side projecting portion. On the other hand, if the intermediate overhanging portion is provided at least at a position directly below the melting portion side overhanging portion, the intermediate overhanging portion suppresses adhesion of slag scattered to the lower side of the melting portion side overhanging portion. Therefore, it is possible to reduce the overhang dimension of the melted portion side overhang portion while suppressing the adhesion of the slag to the inner surface of the chute. This secures the channel area of the chute as well as improving the operation efficiency (Claim 2).

  Moreover, in this invention, it is preferable that the said intermediate | middle overhang | projection part is provided over the inner surface whole periphery of the said chute | shoot (Claim 3).

  In this way, the adhesion of the slag to the side surface of the chute is more reliably suppressed.

  Further, in the present invention, the discharge part has an inlet for communicating with the chute and for introducing the high-temperature gas from the chute to the discharge part, and the inlet is connected to the melting part through the outlet. It is preferable that the high-temperature gas led out to the chute side is provided below the lead-out port so as to flow down in the chute together with the slag.

  In this configuration, the hot gas led out from the outlet into the chute moves downward in the chute together with the slag. Therefore, the slag is in contact with the hot gas until it is led out to the chute, and the slag at the outlet is maintained at a high temperature by the hot gas. This further suppresses slag sticking in the vicinity of the outlet. Here, when the high temperature gas is introduced into the chute, the slag is likely to be scattered on the side surface of the chute in the middle of the fall with the diffusion of the high temperature gas. Suppresses adhesion. As described above, according to this configuration, it is possible to further suppress the adhesion of the slag in the vicinity of the outlet, while suppressing the adhesion of the slag to the entire side surface of the chute.

  Further, according to this melting furnace, the introduction port is provided below, so that the height of the upper end position of a boiler or the like connected to the introduction port can be reduced.

  In addition, the discharge portion has a discharge portion side inclined portion that is inclined downward toward the introduction port and guides the slag to the chute side at the bottom portion, and the intermediate projecting portion is at least the melting portion It is preferable to be provided at a position directly below the side projecting portion and a position along the lower end portion of the discharge portion side inclined portion.

  In this configuration, the frequency of removing the slag is further reduced because adhesion of the slag generated in the discharge section to the side surface of the chute is suppressed in addition to the slag generated in the melting section by the intermediate projecting section. The

  In this configuration, it is preferable that the intermediate projecting portion is provided over the entire inner surface of the chute at a position along the lower end portion of the discharge portion side inclined portion.

  In the present invention, the chute is disposed at a position that is horizontally displaced from the melting portion, and the discharge portion is disposed at a position that is horizontally displaced from the chute, and the discharge portion The direction of deviation from the chute is preferably substantially perpendicular to the direction of deviation between the melted portion and the chute (Claim 7). And according to such a configuration, a gasification furnace connected to the melting part, pyrolyzing the waste to generate pyrolysis gas, and leading the pyrolysis gas to the melting part, In a waste treatment system having a boiler connected to the discharge unit and recovering waste heat from a high-temperature gas introduced from the chute through the introduction port into the discharge unit, the gasification furnace includes: It is arranged at a position shifted in a direction substantially perpendicular to the melting direction of the melting part and the chute with respect to the melting part, and the boiler is substantially the same as the deviation direction of the discharging part and the chute with respect to the discharging part. By disposing at a position shifted in the direction, the shift direction of the gasification furnace and the melting part and the shift direction of the chute, the discharge part and the boiler can be made substantially parallel, and the gasification furnace To the boiler It is possible to reduce the distance. This leads to a reduction in the installation space of the waste treatment system (claim 8).

  As described above, according to the present invention, it is possible to provide a melting furnace that can increase the operation efficiency by suppressing sticking of slag in the melting furnace with a simple configuration.

  A preferred first embodiment of the present invention will be described below with reference to the drawings.

  FIG. 1 is a schematic diagram showing an overall configuration of a waste treatment facility (waste treatment system) 1 including a melting furnace according to a first embodiment of the present invention. First, the waste disposal procedure in the waste disposal facility 1 will be described.

  In addition to the melting furnace 10, the waste treatment facility 1 mainly includes a waste pit 2, a dust feeder 4, a fluidized bed gasifier 6, a boiler 30, and a gas cooler 42 mainly from the upstream side. And a bag filter 44, a denitration device 46, and a chimney 48.

  In the waste treatment facility 1, first, waste stored in the garbage pit 2 is input to the dust feeder 4. The waste introduced into the dust feeder 4 is quantitatively supplied from the dust feeder 4 to the fluidized bed gasifier 6 and thermally decomposed in the fluidized bed gasifier 6. . In the fluidized bed gasifier 6, for example, the waste is partially combusted under an air ratio of 0.2 to 0.4, and the temperature of the fluidized bed composed of a sand layer or the like is maintained at 450 ° C to 650 ° C. Pyrolysis or gasification is performed. The pyrolysis gas generated in the fluidized bed gasification furnace 6 is guided to the melting furnace 10. On the other hand, non-combustible materials out of the waste are extracted from the bottom of the hearth, separated into non-ferrous metals, iron, etc., and transported outside the waste treatment facility 1 to be reused.

  In the melting furnace 10, the pyrolysis gas is further burned. A swirling flow is formed in the melting furnace 10 and, for example, high-temperature combustion at about 1300 ° C. is performed under conditions of a total air ratio of 1.3 to 1.5. At this time, the ash in the pyrolysis gas is melted to produce slag. The generated slag flows down a chute 20 described later provided in the melting furnace 10 and is discharged to a slag cooling device 28 provided below the chute 20. The slag is rapidly cooled by the slag cooling device 28 and conveyed to the outside for reuse.

  Further, high temperature gas is discharged from the melting furnace 10. This high temperature gas is introduced into the boiler 30, and the waste heat is recovered by the boiler 30. Here, the boiler 30 recovers the waste heat by bringing the high-temperature gas into contact with a heat exchanger or the like. The boiler 30 includes a gas passage 31 extending upward from a connecting portion of the melting furnace 10 and a boiler body 32 having the heat exchanger and the like. In the boiler 30, after the high temperature gas is cooled to a predetermined temperature suitable for introduction into the boiler body 32 in the gas passage 31, the gas is introduced into the boiler body 32. The main body 32 collects the waste heat of the hot gas. The gas from which the waste heat has been recovered by the boiler 30 is cooled by the gas cooler 42, then dust is removed by the bag filter 44, and is discharged from the chimney 48 through the denitration device 46.

  Next, the details of the melting furnace 10 will be described.

  2 is an enlarged schematic cross-sectional view showing a part of the melting furnace 10, FIG. 3 is a cross-sectional view taken along line AA of FIG. 2, and FIG. 4 is the waste treatment facility in the vicinity of the melting furnace 10. 1 is a schematic top view of FIG. The melting furnace 10 has a melting part 12 communicating with the fluidized bed gasification furnace 6, a chute 20 provided downstream of the melting part 12, and a discharge part 14 provided further downstream of the chute 20. is doing. Here, in the melting furnace 10 concerning this embodiment, as shown in FIG. 4, the said fusion | melting part 12, the said chute | shoot 20, and the said discharge part 14 are arrange | positioned substantially linearly.

  The melting portion 12 is a portion that burns the pyrolysis gas introduced from the fluidized bed gasification furnace 6 with a burner and melts the ash content of the pyrolysis gas to generate slag. The melting portion 12 has a substantially cylindrical shape extending in the vertical direction, and the burner is attached to the top portion 11 of the melting portion 12. In addition, a communication port 12c communicating with the fluidized bed gasification furnace 6 is provided at the upper end of the melting part 12, and the thermal decomposition is performed from the fluidized bed gasification furnace 6 through the communication port 12c. Gas is introduced. On the other hand, an outlet 12a communicating with the chute 20 is provided at the lower end of the melting part 12, and the slag generated in the melting part 12 is discharged to the chute 20 through the outlet 12a. The

  The chute 20 is for flowing down the slag derived from the outlet 12a. The chute 20 has a shape surrounding the slag flowing down from the outlet 12a. Specifically, the chute 20 is a hollow member having a substantially rectangular outer cross section and has a shape extending in the vertical direction. The outlet 12 a communicates with the upper end of the chute 20, and the slag cooling device 28 is connected to the lower end of the chute 20. Then, the slag discharged to the chute 20 from the outlet 12 a is guided to the slag cooling device 28 by flowing down the chute 20.

  Here, at the bottom of the melting portion 12, a melting portion-side inclined portion 12b that is inclined downward toward the outlet 12a is provided. Further, a melted portion side projecting portion 15 that projects toward the inside of the chute 20 is provided at the lower end of the melted portion side inclined portion 12b. The melted portion side projecting portion 15 is, for example, a plate-like member made of stainless steel, and is inclined downward along the inclined surface of the melted portion side inclined portion 12b, that is, toward the inside of the chute 20. It is fixed to the side surface of the chute 20. Then, the melted portion side projecting portion 15 guides the slag flowing down along the melted portion side inclined portion 12 b to the inside of the inner surface of the chute 20. In this way, the slag guided to the inside of the chute 20 by the melting portion side overhanging portion 15 flows down in the chute 20 in a state where adhesion to the side surface of the chute 20 is suppressed.

  The discharge part 14 is for guiding the hot gas discharged from the melting part 12 to the boiler 30. The discharge portion 14 is a portion having a substantially cylindrical shape extending upward, and the boiler 30 is continuously provided above the discharge portion 14. Further, the discharge portion 14 has an introduction port 14 a communicating with the chute 20 at the lower end portion.

  The introduction port 14 a is for introducing the high-temperature gas discharged from the melting part 12 to the chute 20 from the chute 20 to the discharge part 14. The inlet 14a is provided below the outlet 12a. More specifically, the introduction port 14a is provided such that its lower end is below the lower end of the outlet 12a and its upper end is near the lower end of the outlet 12a. Accordingly, the hot gas is led out to the chute 20 from the outlet 12a along the melting part side inclined part 12b as shown by an arrow in FIG. After flowing down together with the slag, it is introduced from the introduction port 14a to the discharge unit 14 side. The hot gas introduced into the discharge unit 14 is introduced into a boiler 30 that is connected to the discharge unit 14.

  At the bottom of the discharge portion 14, a discharge portion-side inclined portion 14b that is inclined downward toward the introduction port 14a is provided. The discharge portion side inclined portion 14b is for guiding the slag generated by the discharge portion 14 to the chute 20, and the slag generated by the discharge portion 14 is generated by the discharge portion side inclined portion 14b. It is discharged into the chute 20.

  At a position along the lower end of the discharge portion side inclined portion 14b, that is, the lower end of the introduction port 14a, as shown in FIG. It is provided over the entire circumference of the inner surface of the chute 20.

  As shown in FIG. 3, the intermediate projecting portion 16 is composed of a plurality of plate-like members. Specifically, the intermediate overhanging portion 16 includes a plurality of first plate-like members 16a provided immediately below the melting portion side overhanging portion 15 and a plurality of lower end portions of the discharge portion side inclined portion 14b. The second plate member 16b and a plurality of third plate members 16c provided between the first plate member 16a and the second plate member 16b. These plate-like members 16a, 16b, and 16c are attached without gaps over the entire circumference of the inner surface of the chute 20, so that the intermediate overhanging portion 16 as a whole extends over the entire circumference of the inner surface of the chute 20. . Each of the plate-like members 16a, 16b, and 16c is, for example, a plate-like member made of stainless steel, and has a shape that is inclined downward from the inner side surface of the chute 20 toward the inside. And this intermediate | middle overhang | projection part 16 suppresses adhesion to the side surface of the chute | shoot 20 by guiding the slag produced | generated in the said fusion | melting part 12 or the discharge part 14 to the inner side of the chute | shoot 20.

  In particular, the first plate-like member 16a of the intermediate overhanging portion 16 has a chute 20 on the lower side of the melting portion side overhanging portion 15 mainly in the middle of the slag flowing down from the melting portion side overhanging portion 15. The slag scattered on the side surface is again guided inside the chute 20. Here, in this embodiment, the overhanging dimension of the melted portion side overhanging portion 15 is not set so large in order to secure the flow passage area of the chute 20 in the vicinity of the introduction port 12a. Therefore, the slag discharged from the melting part 12 is likely to be scattered on the chute side surface below the melting part side projecting part 15. However, the scattered slag flows down in a state in which adhesion to the side surface of the chute 20 is suppressed by being guided again inside the chute 20 by the first plate-like member 16a.

  In addition, the second plate-like member 16b of the intermediate overhanging portion 16 is formed inside the chute 20 with the slag generated mainly by the discharge portion 14 and flowing down to the chute 20 side along the discharge portion-side inclined portion 14b. invite. And by being guided to the inside of the chute 20 by the second plate-like member 16b, the slag generated by the discharge part 14 also moves inside the chute 20 in a state in which adhesion to the side surface of the chute 20 is suppressed. It will flow down.

  In the melting furnace 10 configured as described above, first, the pyrolysis gas burns in the melting section 12 to generate slag. The slag generated in the melted part 12 flows down the melted part side inclined part 12b of the melted part 12 to the outlet 12a in contact with the hot gas, and the melted part side projecting part 15 It is led out to the inside of the chute 20 while being prevented from adhering to the inner surface. Here, as described above, in the vicinity of the outlet 12a, the slag moves in contact with the high-temperature gas. That is, in the vicinity of the outlet 12a, the slag is maintained at a high temperature by the high temperature gas. Accordingly, at least in the vicinity of the outlet 12a, the slag is suppressed from being cooled by the wall surface in the vicinity of the outlet 12a, so that the slag is prevented from sticking.

  The slag led out to the chute 20 while being maintained at a high temperature as described above flows down together with the high-temperature gas in the chute 20. At this time, as the hot gas diffuses in the chute 20, a part of the slag is scattered on the side surface side of the chute 20. However, as described above, since the slag scattered on the side surface side of the chute 20 is guided again to the inside of the chute 20 by the intermediate overhanging portion 16, the slag scattered due to the diffusion of the high temperature gas is also absorbed by the chute 20. The chute 20 flows down while the adhesion to the inner surface is suppressed. On the other hand, the high temperature gas is introduced into the discharge unit 14 through the introduction port 14a.

  In addition, the slag generated by the discharge part 14 flows down the discharge part side inclined part 14b toward the introduction port 14a. The slag is guided to the inside of the chute 20 by the intermediate projecting portion 16 and is led out to the chute 20 side while being prevented from adhering to the inner surface of the chute 20.

  Thus, in the present melting furnace 10, the slag is maintained at a high temperature at the outlet 12 a, and the slag is prevented from sticking at the outlet 12 a, and the molten portion side protruding portion 15 and the intermediate protruding portion 16 Since the slag is prevented from adhering to the inner surface of the chute 20 while flowing down the chute 20, it is possible to reduce the frequency of removing the adhering slag and the adhering slag. Driving efficiency increases.

  Further, the boiler 30 requires a predetermined length upward in order to cool the high temperature gas introduced from the discharge unit 14 to a predetermined temperature or lower. Therefore, in the present melting furnace 10, the discharge port 14a into which the high temperature gas is introduced is provided below, so that the upper end position is lowered in a state where the length for cooling the high temperature gas is secured. It is possible to reduce the overall height of the waste treatment facility 1.

  Next, the waste treatment facility 100 including the melting furnace 110 according to the second embodiment of the present invention will be described. However, description of components having the same configuration as the waste treatment facility 1 according to the first embodiment will be omitted.

  5 is a schematic top view of the waste treatment facility 100 in the vicinity of the melting furnace 110, FIG. 6 is a cross-sectional view taken along line CC in FIG. 5, and FIG. 7 is a cross-sectional view taken along line DD in FIG. is there.

  Similar to the waste treatment facility 1 according to the first embodiment, the waste treatment facility 100 includes a fluidized bed gasification furnace 6, a melting furnace 10, and a boiler 130. The melting furnace 10 has a melting part 112, a chute 120, and a discharge part 114. However, in the present embodiment, as shown in FIG. 5, the melting portion 112, the chute 120, and the discharge portion 114 are configured such that the melting portion 112 and the chute 120 are displaced in the horizontal direction, the chute 120, the discharge portion 114, From the fluidized bed gasifier 6 connected to the melting part 112 to the boiler 130 connected to the discharge part 114. The distance is reduced. Further, the direction of displacement between the fluidized bed gasifier 6 connected to the melting part 112 and the melting part 112, the boiler 130 connected to the discharge part 114, the discharge part 114, and the chute. The direction of deviation from 120 is substantially perpendicular. And by such arrangement | positioning, length L1 from the upstream end of the fluidized bed type gasification furnace 6 which concerns on this 2nd embodiment shown in FIG. 5 to the downstream end of the said boiler 130 is the said 1st shown in FIG. Space saving is achieved by shortening the length L2 from the upstream end of the fluidized bed gasification furnace 6 to the downstream end of the boiler 130 according to an embodiment.

  Similarly to the melting portion 12 according to the first embodiment, the melting portion 112 has a lead-out port 112a communicating with the chute 120 and a melt-portion-side sloping portion 112b that slopes toward the lead-out port 112a. Is provided. Furthermore, a melted portion side projecting portion 115 projecting inside the chute 120 is provided at the lower end of the melted portion side inclined portion 112b. Similarly, the discharge portion 114 is provided with an introduction port 114a communicating with the chute 120 and a discharge portion side inclined portion 114b inclined toward the introduction port 114a.

  On the other hand, in this embodiment, the outlet 112a opens in a direction perpendicular to the opening direction of the communication port 112c of the fluidized bed gasifier 6 provided at the upper end of the melting part 112 in a plan view. ing. The inlet 114a opens in a direction perpendicular to the opening direction of the outlet 112a in plan view. The introduction port 114a is provided at a position where the upper end of the introduction port 114a and the lower end of the outlet port 112a are sufficiently separated from each other. An intermediate projecting portion protruding inward from the inner surface of the chute 120 includes an upper intermediate projecting portion 116 provided at a position along the lower end of the introduction port 114a, the introduction port 114a, and the outlet port 112a. And a lower intermediate projecting portion 117 provided between the two.

  In the main melting furnace 110 configured as described above, the slag generated in the melting part 112 flows down the melting part side inclined part 112b to the outlet 112a in a state of being in contact with the high temperature gas, and the melting part It is led out from the side projecting portion 115 to the inside of the chute 120. At this time, the slag and the high-temperature gas are led to the chute 120 in a direction perpendicular to the introduction direction from the fluidized bed gasification furnace 6 in plan view. As in the first embodiment, the slag led out to the chute 120 is maintained at a high temperature by the high-temperature gas, that is, in a state where sticking in the vicinity of the outlet 112a is suppressed. It flows down toward the mouth 114a. In the middle of the flow from the inlet 114a to the outlet 112a, the slag is guided to the inside of the chute 120 by the upper intermediate projecting portion 116, and adhesion to the inner side surface of the chute 120 is suppressed. It flows down in the state. More specifically, of the slag, the slag scattered on the side surface of the chute 120 directly below the melted portion side projecting portion 115 is struck by the first plate member 116 a provided below the melted portion side projecting portion 115. The slag guided to the inside of 120 and splashed to the side surface other than the substantially directly-lower side surface of the melted portion side projecting portion 115 is chute 120 by the third plate-like member 116c provided along the side surface other than the approximately directly-underly-side surface. Guided inside.

  Of the slag and the high-temperature gas flowing down to the vicinity of the introduction port 114a, the high-temperature gas is introduced into the discharge unit 113 in a direction perpendicular to the lead-out direction from the melting unit 112 in plan view, and is provided above the boiler. 130. On the other hand, the slag is composed of a first plate-like member 117a provided mainly on the side surface of the chute 120 directly below the melted portion side projecting portion 115 of the lower intermediate projecting portion 117 and the melted portion side projecting portion. 115 is guided to the inside of the chute 120 by the third plate-like member 117c provided on the side surface of the chute 120 except for the side surface substantially below and the portion along the lower end of the discharge portion side inclined portion 114b. In a state where the adhesion is suppressed, it flows down further and is discharged to the slag cooling device 28. Further, the slag generated by the discharge unit 114 is mainly formed at the second plate-like member 117b provided at a position along the lower end of the discharge unit side inclined portion 114b of the lower intermediate projecting portion 117 and the discharge. The part-side inclined part 114b is discharged to the slag cooling device 28 in a state where adhesion to the inner surface of the chute 120 is suppressed.

  As described above, in the present melting furnace 110, the slag is maintained at a high temperature at the introduction port 114a to prevent the slag from sticking to the introduction port 114a, and the upper intermediate overhanging portion 116 and the lower intermediate overhanging portion. 117 prevents the slag from adhering to the inner surface of the chute 220, so the frequency for removing the adhering or adhering slag can be reduced, and the operating efficiency of the melting furnace 110 is increased. In particular, in the present melting furnace 110, the upper end of the inlet 114a and the lower end of the outlet 112a are sufficiently separated from each other, and the slag led out from the outlet 112a into the chute 120 is in the middle of its flow down the chute. Although it is easy to scatter to the 120 side, the lower intermediate projecting portion 117 provided between the introduction port 114a and the outlet port 112a guides the scattered slag to the inside of the chute 120 again. Is more reliably suppressed.

  Here, the specific structure, the number, etc., of the melted part side projecting parts 15, 115 and the intermediate projecting parts 16, 116, 117 are not limited to those described above. In particular, the intermediate projecting portions 16, 116, and 117 may be provided only on part of the inner surfaces of the chutes 20 and 120. However, if these intermediate projecting portions 16, 116, 117 are provided over the entire inner surface of the chute 20, 120, slag adhesion to the side surfaces of the chute 20, 120 is more reliably suppressed. Further, if the intermediate projecting portions 16 and 117 are provided along the lower ends of the discharge portion side inclined portions 14b and 114b, the discharge portion in addition to the slag flowing down from the melting portion side inclined portions 12b and 112b. Since the adhesion of the slag generated at 14 and 114 to the side surfaces of the chutes 20 and 120 is suppressed, the slag removal frequency can be further reduced.

  Here, the positions of the outlets 12a and 112a and the inlets 14a and 114a are not limited to the above, and the inlets 14a and 114a may be provided at the same height as the outlets 12a and 112a. However, if the inlets 14a and 114a are provided below the outlets 12a and 112a, the slag can be maintained at a high temperature in the vicinity of the outlets 12a and 112a, and in the vicinity of the outlets 12a and 112a. Slag sticking can be more reliably suppressed.

  Further, the melting parts 12 and 112 and the chutes 20 and 120 may be connected in the vertical direction. And the said outlets 12a and 112a may connect the said fusion | melting part 12 and the said chute | shoot 20 in an up-down direction.

  Further, the application of the melting furnaces 10 and 110 is not limited to the waste treatment facilities 1 and 100.

It is the schematic which shows the whole structure of a waste treatment facility provided with the melting furnace which concerns on 1st embodiment of this invention. It is a schematic sectional drawing which expands and shows a part of melting furnace shown in FIG. It is the sectional view on the AA line of FIG. It is a schematic top view of the waste treatment facility in the vicinity of the melting furnace shown in FIG. It is a schematic top view which shows a part of waste disposal facility provided with the melting furnace which concerns on 2nd embodiment of this invention. It is CC sectional view taken on the line of FIG. It is the DD sectional view taken on the line of FIG. It is explanatory drawing for demonstrating the conventional melting furnace.

Explanation of symbols

1 Waste treatment facility (waste treatment system)
10 Melting furnace (first embodiment)
DESCRIPTION OF SYMBOLS 12 Melting part 12a Outlet 12b Melting part side inclined part 14 Discharge part 14a Inlet 14b Discharge part side inclined part 15 Melting part side overhang part 16 Intermediate overhang part 20 Chute 30 Boiler 100 Waste processing equipment (waste processing system)
110 Melting furnace (second embodiment)
112 melting portion 112a outlet port 112b melting portion side inclined portion 114 discharging portion 114a introducing port 114b discharging portion side inclined portion 115 melting portion side protruding portion 116 upper intermediate protruding portion (intermediate protruding portion)
117 Lower intermediate overhang (intermediate overhang)

Claims (8)

A melting furnace for melting ash in pyrolysis gas generated by pyrolyzing waste,
A melting part that burns and melts ash in the pyrolysis gas of the waste to generate slag;
A chute provided downstream of the melting portion and provided to surround a slag extending downward and flowing down from the melting portion;
A discharge part for guiding the high temperature gas led out from the melting part to the chute out of the furnace from the chute,
The melting part communicates with the chute and causes the slag to flow down to the chute and lead out the hot gas to the chute, and is connected to the lead-out port and toward the lead-out port A sloping portion that slopes downward and guides the slag toward the chute, and a slag that projects from the lower end of the sloping portion toward the inside of the chute and flows down the sloping portion. A melted part side projecting part that flows down from the inside of the chute to the chute,
The slag that protrudes from the inner surface of the chute to the inside of the chute below the melting portion side protruding portion, and flows down from the inner surface of the chute at a position spaced from the inner surface of the chute. the intermediate expansion part is provided, the melting furnace intermediate overhang, wherein Rukoto which have a shape which is inclined downward toward the inside from the inner surface of the chute so as to guide the slug inside the chute . In the melting furnace according to claim 1,
The melting furnace, wherein the intermediate overhanging portion is provided at least at a position directly below the overhanging portion on the melting portion side. In the melting furnace according to claim 1 or 2,
The melting furnace, wherein the intermediate projecting portion is provided over the entire inner surface of the chute. The melting furnace according to any one of claims 1 to 3,
The discharge part has an inlet for communicating the chute and introducing the hot gas from the chute to the discharge part,
The introduction port is provided below the outlet so that the high-temperature gas led out from the melting part to the chute side through the outlet port flows down along with the slag in the chute. Melting furnace. In the melting furnace according to claim 4,
The discharge part has a discharge part side inclined part at the bottom part thereof, which is inclined downward toward the introduction port and guides the slag to the chute side,
The intermediate overhanging portion is provided at least at a position immediately below the melting portion side overhanging portion and a position along the lower end portion of the discharge portion side inclined portion. In the melting furnace according to claim 5,
The melting furnace characterized in that the intermediate projecting portion is provided over the entire inner surface of the chute at a position along the lower end of the discharge portion side inclined portion. In the melting furnace in any one of Claims 1-6,
The chute is arranged at a position displaced in the horizontal direction from the melting part,
The discharge part is arranged at a position shifted in the horizontal direction from the chute,
A melting furnace characterized in that a displacement direction between the discharge portion and the chute is substantially perpendicular to a displacement direction between the melting portion and the chute. A waste treatment system,
A melting furnace according to claim 7;
A gasification furnace connected to the melting section to pyrolyze the waste to generate a pyrolysis gas and to lead the pyrolysis gas to the melting section;
A boiler that is connected to the discharge unit and recovers waste heat from the high-temperature gas introduced from the chute to the discharge unit via the inlet;
The gasification furnace is disposed at a position shifted in a direction substantially perpendicular to a shift direction of the melt portion and the chute with respect to the melt portion,
The boiler is disposed at a position displaced in the same direction as the displacement direction of the discharge portion and the chute with respect to the discharge portion,
The waste treatment system, wherein a deviation direction between the gasification furnace and the melting portion and a deviation direction between the chute, the discharge portion, and the boiler are substantially parallel.

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