JP6109400B1 - Refractories and incinerators - Google Patents

Abstract

[PROBLEMS] To improve operation efficiency by minimizing the operation stop of an incinerator. A refractory 40 is disposed in a hearth of an incinerator S so as to eject combustion air from the hearth, and the refractory 40 is formed by a refractory material 45 and is a jet that ejects combustion air. A blower pipe 41 having an outlet 44; and a blower pipe 42 that is connected to the blower pipe 41 and supplies combustion air to the blower pipe 41. The blower pipe 41 and the blower pipe 42 communicate with each other, and Arranged so as to penetrate the inside, the outlet 44 of the blower pipe 41 is provided on the first wall surface of the refractory 40, and the blower pipe 42 is opposite to the first end and the first end. A second end portion of the air supply pipe 41, the air blow pipe 42 is connected to the air blow pipe 41, the first end portion projects into the air blow pipe 41, and the second end portion is a first end provided with a jet port 44. It protrudes from the second wall surface of the refractory 40 that is different from the wall surface, and inside the refractory material 45, Between the tube 42 and the refractory material 45, a predetermined gap is provided. [Selection] Figure 4

Description

  The present invention relates to a refractory and an incinerator.

  Conventionally, there are several types of incinerators for burning waste, including a stoker furnace and a fluidized bed furnace. In the stoker furnace, combustion air (hereinafter referred to as combustion air) is sent from the bottom to make it easy to burn waste. It is a combustion furnace that burns after burning. On the other hand, in a fluidized bed furnace, heated combustion air is blown upward from the bottom to flow sand heated to high temperature in the furnace, and the crushed waste in the fluidized high temperature sand is removed. It is an incinerator that burns. For example, Patent Document 1 proposes a waste incinerator using a stoker furnace and a fluidized bed furnace.

Japanese Patent Laid-Open No. 11-190509

  However, the incinerator described above has the following problems. For example, in a stoker furnace, the incinerated product, which is waste, is moved in the downstream direction by moving the grate back and forth, and combustion air is sent from the lower direction of the grate to burn the incinerated product. For this reason, the gap between the grate and the grate becomes large due to aging degradation of the grate, and the combustion product may fall from the gap and ignite the hydraulic device that drives the grate and may cause a fire. Moreover, since incineration residue other than combustion ash is generated, the cost for final disposal is large.

  On the other hand, the fluidized bed furnace dries and burns the incineration object by placing the incineration object on the high-temperature circulating sand and moving the sand using the supply of combustion air. As a result, metals such as iron and aluminum remain as incineration residues. In a fluidized bed furnace, combustion air is supplied from a blower pipe, but iron, aluminum, etc. remaining as an incineration residue may be cooled and solidified to block the blower outlet of the blower pipe. Moreover, as a result of accidentally throwing large waste into the furnace without being crushed, the sand vent pipe, which is provided in the most downstream of the fluidized bed furnace's hearth and into which fluid sand and incineration residue flow, is blocked. Sometimes. In such a case, the operation of the incinerator is stopped and the operation of removing the waste blocking the sand removal pipe is performed, so that the operation efficiency of the incinerator is lowered.

  In addition, the blower pipe that supplies combustion air is built in the hearth when constructing an incinerator, and the individual blower pipes can be replaced according to the degree of deterioration and clogging of the blower pipes due to incineration residues. It is not. Therefore, in order to replace the blower pipe, it is necessary to perform a work for stopping the operation of the incinerator and remodeling the blower pipe.

  The present invention has been made in view of the above circumstances, and it is exemplary to provide a refractory that can improve operation efficiency with minimum operation stop of the incinerator and an incinerator having the refractory. Let it be an issue.

  In order to solve the above problems, the present invention has the following gist.

[Purpose 1]
A refractory arranged to eject combustion air from the hearth of the incinerator,
The hearth is composed of a plurality of steps.
The incinerator is configured to burn the incinerated material on the fluidized medium while moving the fluidized medium deposited on the hearth to the downstream of the hearth by jetting the combustion air,
The refractory is
Formed of refractory material,
A first blower pipe having a jet outlet for jetting the combustion air; and a second blower pipe connected to the first blower pipe and supplying the combustion air to the first blower pipe;
The first blower pipe and the second blower pipe communicate with each other and are arranged so as to penetrate the inside of the refractory material,
The jet outlet of the first blower pipe is provided on the first wall surface of the refractory,
The second air duct has a first end and a second end opposite to the first end,
The second air duct is connected to the first air duct, the first end protrudes into the first air duct, and the second end includes the first wall surface provided with the jet port. Protrudes from the second wall of the different refractory,
Inside the refractory material, a predetermined gap is provided between the first blast tube and the second blast tube and the refractory material.

[Purpose 2]
The staircase where the refractory is installed;
A funnel-shaped inclined surface that is arranged downstream of the hearth and that guides the incineration residue of the fluid medium and the incinerated material moved by the combustion air toward the sand pipe;
A plurality of air diffuser pipes arranged at intervals so as to cover the sand vent pipe between the hearth and the sand vent pipe, and formed with a plurality of air jets;
A plurality of fixing members arranged at intervals to connect the plurality of air diffusers,
The incinerated material on the fluidized medium is combusted while the fluidized medium deposited on the hearth is moved downstream of the hearth by the combustion air ejected from the hearth configured by the plurality of stepped portions. An incinerator for moving the incineration residue to the sand extraction pipe,
The longest distance inside the closed space formed by the two adjacent air diffusers and the two adjacent fixing members is smaller than the diameter of the sand pipe.

[Purpose 3]
The plurality of aeration tubes are arranged radially around the sand extraction pipe above the inclined surface, or arranged in a lattice shape so as to cover the sand extraction pipe above the inclined surface.

[Purpose 4]
The air diffuser is
Rising upward from the inclined surface, and
A first air diffuser, and a second air diffuser shorter than the first air diffuser,
The rising positions of the first air diffuser and the second air diffuser are at the same height from the sand extraction tube of the inclined surface,
The end of the first air diffuser on the sand vent pipe side is located on the inner side of the outer peripheral portion of the sand vent pipe.

[Purpose 5]
The first air diffuser and the second air diffuser are installed so that the height from the sand vent is the same.

[Purpose 6]
The inclined surface is composed of a plurality of step portions,
The said refractory is installed in the said step part.

[Purpose 7]
The position of the jet outlet in a specific staircase portion of the plurality of staircase portions of the hearth and the position of the jet outlet in the next staircase portion are orthogonal to the jet direction of the combustion air. The plurality of refractories are arranged so as not to overlap in the width direction.

  Operation efficiency can be improved by minimizing the operation stop of the incinerator.

It is sectional drawing which shows the whole structure of the incinerator of embodiment. It is sectional drawing which shows the structure of the circulating sand extrusion apparatus of embodiment. It is a top view of the hearth part of the incinerator of an embodiment. It is sectional drawing explaining the structure of the air duct of embodiment. It is a figure explaining the composition of the diffuser pipe of an embodiment.

[Description of incinerator]
Hereinafter, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a cross-sectional view showing the overall configuration of the incinerator S of the present embodiment. With reference to FIG. 1, the operation | movement of each apparatus which comprises the structure of the incinerator S and the incinerator S is demonstrated. In addition, the white arrow in FIG. 1 shows the flow of combustion air.

  The incinerator S of the present embodiment causes the combustion sand 2 to flow from the upstream to the downstream of the hearth made of refractory, and dries the incineration waste 14 (incineration object) deposited on the sand 2. This is an incinerator of a type in which after burning and post-combustion, the incineration residue after the sand 2 and incineration waste 14 are combusted is poured into the sand extraction pipe 4 provided at the most downstream of the hearth. In the incinerator S of this embodiment, the sand 2 which is a fluid medium for burning the incineration waste 14 is supplied from the circulating sand extrusion device 1 to the stepped hearth 3 of the incinerator. And since the sand 2 supplied from the circulating sand extrusion apparatus 1 is moved from the upstream side of the hearth part 3 to the downstream direction, high-temperature and high-pressure combustion air is sent from the blower 5 to the header pipe 7. The combustion air sent to the header pipe 7 was provided on the rising surface (corner of the adjacent staircase) of the staircase part 3 of the hearth part 3 formed of refractory material via the branch pipe 8 and the blower pipe 9. It ejects from the ejection port 44 (refer FIG. 4). And the sand 2 moves to the downstream direction (in FIG. 1, black arrow direction) of the hearth part 3 by the wind pressure of the jetted combustion air. The branch pipe 8 is provided with a valve for adjusting the wind pressure, and the wind pressure when the combustion air is ejected can be adjusted. In this way, the sand 2 is moved to the most downstream inclined surface 15 provided with the sand extraction pipe 4 serving as an outlet for incineration residue at the center by the combustion air supplied from the jet nozzles 44 provided in the respective step portions. Moving. On the most downstream inclined surface 15, the combustion air is sent from the blower 6 to the wind box 10, and the combustion air is evenly ejected from the air diffusion pipe 11 provided around the sand removal pipe 4, and the air around the air diffusion pipe 11 is inclined. The sand 2 in the surface 15 is caused to flow from the bottom to the top. The sand 2 moved to the sand removal pipe 4 is separated from the incineration residue, and then conveyed to the circulating sand extrusion device 1 by a conveyor device (not shown) to burn the incineration waste 14 again. Is supplied to the hearth part 3.

  On the other hand, the incineration waste incinerated in the incinerator S is first put into the hopper 16 and finely crushed by the biaxial crusher 17, and then falls and accumulates on the chute portion 21. The incinerated garbage 12 accumulated in the chute part 21 is pushed into the incinerator S in order from the one deposited in the lower part of the chute part 21 by the pusher 13 for pushing incinerated garbage operating in the direction of the arrow x in the figure. Move onto the sand 2. The incineration waste 14 that has moved onto the sand 2 (on the fluid medium) is dried by the sand 2 that has been heated to high temperature by the high-temperature combustion air supplied to the hearth part 3 through the blower tube 9. Then, the incineration garbage 14 deposited on the sand 2 moves downstream of the hearth part 3 together with the sand 2 that moves by the wind pressure of the combustion air pushed from the jet port 44. In the initial combustion part 22, the dried incineration waste 14 is heated by the sand 2 deposited on the hearth part 3 as the hot sand 2 moves in the downstream direction of the hearth part 3. By hitting, carbonization occurs simultaneously with drying and intermediate combustion. Further, the incineration waste 14 that has moved to the final combustion section 23 in which the most downstream inclined surface 15 is installed is completely burned by the high-temperature and high-pressure combustion air sent from the blower 18. As a result, the unburned gas and the combustion gas rise to the secondary combustion section 24 at the upper part of the incinerator S, and the incineration residue such as incombustibles in the incineration waste 14 moves together with the sand 2 to the lower sand removal pipe 4. .

  Unburned gas and combustion gas move to the secondary combustion part 24 provided in the upper part of the incinerator S, and are secondary-combusted by the combustion air from the blower 20, and the unburned gas part is completely burned. Thereby, the dioxin density | concentration in the waste gas 25 discharged | emitted from the incinerator S can be suppressed. The exhaust gas 25 generated by the secondary combustion can be effectively used for a power generation boiler, for example.

  Further, the high-temperature sand 2 that has moved in the downstream direction on the hearth 3 of the incinerator S becomes a higher temperature on the most downstream inclined surface 15 and is mixed with the incineration waste 14 to be in a molten state. Incineration residues, which are non-combustible materials such as iron cans, are moved to the sand removal pipe 4 together. The sand 2 and the incineration residue that have moved to the sand removal tube 4 fall below the sand removal tube 4 and are separated by a vibrating screen (not shown). The sand 2 is conveyed to the circulating sand extrusion apparatus 1 for reuse, and incineration residues such as aluminum cans and iron cans are separately collected and recycled as valuable materials.

[Circulating sand extrusion equipment]
FIG. 2 is an enlarged cross-sectional view of the circulating sand extrusion device 1 shown in FIG. The circulating sand extruding device 1 is configured to have two rollers 50 and 51, and is a device that supplies sand 2 for burning the incineration waste 14 to the wall surface portion 52 of the fluidized bed. As described above, the sand 2 is the sand that has been recovered from the sand removal pipe 4 and returned to the circulating sand extrusion apparatus 1 to be supplied to the incinerator S again. When supplying the sand 2 to the wall surface portion 52, the roller 50 is a direction perpendicular to the width direction of the wall surface portion 52 (the direction in which combustion air is ejected from the ejection port 44 (see FIG. 4)). It is provided to transport the sand 2 in the depth direction. The roller 50 has screw-like blades on the rotation shaft, and the blades are rotated by the rotation of the rotation shaft, and the sand 2 is moved from one end portion of the rotation shaft of the roller 50 to the other end portion or the roller 50. The sand 2 is conveyed in the direction from the both ends of the rotating shaft toward the center. The roller 51 has four partition plates for collecting sand around the rotation shaft. And the roller 51 scoops up the sand 2 conveyed by the width direction of the wall surface part 52 with the roller 50 with the partition plate rotated in the arrow direction in the figure, and supplies a fixed amount to the wall surface part 52 (in the figure, White arrow direction).

[Configuration of hearth]
FIG. 3 is a plan view of the hearth part 3 and the inclined surface 15 as viewed from above the incinerator S of FIG. The left side of FIG. 3 corresponds to the side where the circulating sand extrusion device 1 of FIG. 1 is provided. The hearth part 3 from the left side (circulated sand extrusion device 1 side) to the right side (sand removal pipe 4 side) of FIG. 3 is stepped in the direction of the inclined surface 15 provided with the sand removal pipe 4 from the circulation sand extrusion device 1. Inclined. The step part 30 provided in the hearth part 3 is formed with a refractory. Similarly, the circular inclined surface 15 on the most downstream side provided with the sand removal pipe 4 is also formed of a refractory. The refractory is made of a castable that is a refractory material. In addition, on the rising surface of each step of each staircase portion 30, an ejection port 44 through which combustion air sent via the blower tube 9 is ejected is disposed so as to face the downstream direction of the hearth portion 3. In FIG. 3, in order to explain that the position of the jet port 44 arranged in the specific step portion 30 and the position of the jet port 44 arranged in the next step portion 30 are shifted, Are displayed so that the rising surfaces of the respective staircase portions 30 that cannot be visually recognized appear schematically.

(Stairs)
The refractory 31 having the outlet 44 of the blower tube 9 disposed on the rising surface of each staircase portion 30 of the hearth portion 3 is a refractory having the same shape and size, and is arranged in the vertical direction in FIG. It has been. Further, the refractories 31 arranged in the adjacent staircase portions 30 are arranged so as to be shifted so that the outlets 44 of the blower tubes 9 are not at the same position in the width direction of the hearth portion 3. The sand 2 is caused to flow in the downstream direction of the hearth 3 by the combustion air ejected from the ejection port 44 of the blower tube 9. Furthermore, since the jet nozzle 44 is shifted for each adjacent stepped portion 30, the entire sand 2 on the hearth portion 3 is moved uniformly by the combustion air regardless of the position in the width direction. Further, while the incineration waste 14 moves from the upstream side to the downstream side by the sand 2 on the hearth part 3, drying, combustion, and post-combustion are performed on the incineration waste 14.

(The most downstream inclined surface)
A plurality of diffused pipes (aeration pipes) arranged radially are installed on the circular inclined surface 15 provided with the sand removal pipe 4 in the center. The diffuser pipe includes a diffuser pipe having a long pipe length (for example, diffuser pipe 33) and a diffuser pipe having a short pipe length (for example, diffuser pipe 34), which are alternately arranged at a fixed angle. ing. The tip of the long air diffuser pipe (for example, air diffuser pipe 33) extends inward from the outer peripheral portion 36 of the sand vent pipe 4, and the tip of the short air diffuser pipe (for example, air diffuser pipe 34) extends to the sand vent pipe 4. It does not extend to the outer peripheral portion 36. The diffuser pipes are fixed to each other by a diffuser tube fixing ring (fixing member) 35 arranged concentrically. In this way, the diffuser pipes (diffuser pipes) are coupled and fixed by the diffuser pipe fixing ring 35 to form a mesh (closed space, hereinafter also referred to as a mesh), and a large size is formed inside the sand vent pipe 4. Incineration residue can be prevented from falling.

  Moreover, the circular inclined surface 15 is a funnel-shaped inclined surface inclined toward the central sand removal pipe 4, and is made of a refractory material. In the present embodiment, the inclined surface 15 is not provided with the jet port 44 for supplying combustion air like the stepped portion 30.

[Composition of refractory]
Next, the structure of the refractory 40 arranged in the hearth part 3 will be described with reference to FIG. FIG. 4 is a cross-sectional view showing the internal configuration (such as the shape of the air duct) of the refractory 40 (corresponding to the refractory 31 described in FIG. 3). FIGS. 4A to 4C are views showing cross sections obtained by cutting the refractory 40 in different cross sections, and FIG. 4D shows the refractory 40 in the staircase portion 30 of the hearth part 3. It is the figure which showed the cross section of the state installed in. Moreover, the white arrow in a figure has shown the flow of the combustion air from the branch pipe 8 (FIG. 1).

  FIG.4 (b) has shown the cross section when the center part of the refractory 40 is cut | disconnected in the direction of the sand extraction pipe | tube 4 (FIG. 3). 4 (a) is a cross-section of the refractory 40 of FIG. 4 (b) cut along the B cross section (arrow) shown in FIG. 4 (b) when viewed from the direction of the sand pipe 4 (FIG. 3). The cross section of is shown. Similarly, FIG.4 (c) saw the cross section when the refractory 40 of FIG.4 (b) was cut | disconnected from the A cross section (arrow) shown in FIG.4 (b) from the direction of the sand pipe 4 (FIG.3). The cross-section is shown.

  The refractory 40 has a blower pipe 41 (first blower pipe), a blower pipe 42 (second blower pipe), and a refractory material 45, and the blower pipe 41 and the blower pipe 42 penetrate the inside of the refractory material 45. Are arranged as follows. As shown in FIGS. 4A to 4C, each of the blower pipe 41 and the blower pipe 42 is a cylindrical pipe. One end of the blower pipe 41 is a jet outlet 44 that jets combustion air in the downstream direction of the hearth part 3, and the other end is in a state of being blocked by providing a gap with the refractory material 45. . The blower pipe 42 is connected to the blower pipe 41 by welding. The front end portion of the blower tube 42 protrudes inside the blower tube 41 and is higher than the bottom surface of the blower tube 41. This is to prevent the sand 2 (FIG. 1) that has entered the inside of the blower pipe 41 and the metal in the incineration waste from entering the blower pipe 42. Further, the rear end portion of the blower pipe 42 (on the blower pipe 9 side) is threaded to connect with the blower pipe 9. Note that the blow pipes 41 and 42 are made of, for example, steel made of iron, and the refractory 40 is made of castable which is a refractory material.

  As shown in FIG. 4D, the outlet 44 of the blower pipe 41 is provided on the wall surface (first wall surface) on the downstream side of the hearth part 3 of the refractory 40. Further, the end (second end) on the side opposite to the end (first end) connected to the blower pipe 41 of the blower pipe 42 (second end) is a wall surface provided with the jet port 44. Are in a state of protruding from the wall surface (second wall surface) of the different refractory 40. The other parts of the blower pipe 41 and the blower pipe 42 are configured to penetrate the inside of the refractory material 45. When the combustion air supplied from the blower 5 to the hearth part 3 through the header pipe 7 and the branch pipe 8 passes, the blow pipes 41 and 42 expand by touching the high-temperature combustion air. Similarly, the refractory material 45 of the refractory 40 is also deposited on the stepped portion 30 of the hearth portion 3 and expands due to heat from the sand 2 that has been heated to high temperature by the combustion air. Since the coefficient of thermal expansion of the blast pipes 41 and 42 is larger than that of the refractory material 45, when the space is not provided between the refractory material 45 and the blast pipes 41 and 42, the expansion of the blast pipes 41 and 42. The refractory material 45 may be cracked. Therefore, even if the blow pipes 41 and 42 expand, a predetermined gap (space) is provided so as not to contact the wall surface of the refractory material 45 inside the refractory 40 facing the blow pipes 41 and 42. Yes.

  As shown in FIG. 4 (d), a pipe 43 through which the blower tube 9 is passed is formed in the staircase 30 in advance, and the inner diameter of the pipe 43 is larger than the outer diameter of the blower tube 9. By connecting one end of the blast pipe 9 to the end of the blast pipe 42 protruding from the wall surface of the refractory 40 and inserting it into the pipe 43, the refractory 40 in which the three blast pipes 41, 42, 9 are communicated with each other. Installed on the staircase 30. Then, by connecting the other end of the blower pipe 9 to the branch pipe 8 (FIG. 1), the combustion air pushed out from the blower 5 becomes the header pipe 7 (FIG. 1), the branch pipe 8, the blower pipe 9, and the blower pipe. 42, and supplied to the hearth part 3 from the ejection port 44 through the blower pipe 41. And the combustion air supplied to the hearth part 3 flows the sand 2 (FIG. 1) deposited on the hearth part 3 in the downstream direction. As described above, the refractory 40 arranged so that the blow pipes 41 and 42 penetrate the inside of the refractory material 45 is a single unit. Then, by installing the necessary number of refractories 40 on the rising surface of the staircase portion 30 of the hearth, it is possible to efficiently perform the air pipe installation work. Further, when the refractory 40 is replaced due to aging or the like, the refractory 40 having deteriorated can be individually replaced.

[Configuration of diffuser pipe]
FIG. 5 is a schematic view when the inclined surface 15 installed at the most downstream side of the incinerator S is viewed from above the incinerator S in FIG. FIG. 5A is an enlarged view of the circular inclined surface 15 centering on the sand removal pipe 4, and FIG. 5B is an air pipe fixing ring (an air pipe fixing ring for fixing the air pipe 67, which is an air pipe). (Hereinafter, referred to as a fixing ring) 64.

  In FIG. 5A, reference numerals 53 to 59 denote diffuser pipes, and reference numerals 60 to 62 indicated by solid concentric circles denote fixing rings for fixing the diffuser pipes 53 to 59. A broken circle indicates the outer peripheral portion 36 of the sand removal pipe 4. In addition, the diffuser pipes 53 to 59 illustrated in FIG. 5A illustrate a part of the diffuser pipes installed on the inclined surface 15 for explanation. The air diffusion pipes 53 to 59 are arranged radially on the inclined surface 15 with the sand removal pipe 4 as the center. The inclined surface 15 is provided with two types of aeration pipes depending on the length thereof. The long air diffuser pipes (first air diffuser pipes) 53, 55, 57, 59 extend to the inside of the outer peripheral part 36 of the sand vent pipe 4 at the tip of the sand vent pipe 4 side (sand vent pipe side). On the other hand, the short air diffuser pipes (second air diffuser pipes) 54, 56, and 58 have a tip part on the sand vent pipe 4 side (sand vent pipe side) outside the outer peripheral part 36 of the sand vent pipe 4, and the outer peripheral part of the sand vent pipe 4. The length does not reach 36. By increasing the length of the long air diffusion pipes 53, 55, 57, 59 protruding to the inside of the sand removal pipe 4, a smaller incineration residue is generated than the case where the pipe length of the air diffusion pipe is short. Can be prevented from falling to. In FIG. 3, a total of 16 long aeration pipes and 8 short aeration pipes are alternately arranged, for a total of 16 arrangements. The number and the arrangement thereof are not limited.

  The broken-line circles shown at the ends of the diffuser pipes 53 to 59 on the side far from the sand removal pipe 4 in FIG. 5A are the inclined surfaces of the diffuser pipes 53 to 59 connected to the wind box 10 (FIG. 1). The rising position from 15 is shown. The rising positions of the air diffusion pipes 53 to 59 are provided on the same concentric circle of the inclined surface 15. The diffuser pipe 57 is a view showing the inside of the diffuser pipe, and the position of an air outlet 68 (indicated by a circle in the figure) for ejecting combustion air and the direction in which the combustion air flows (open arrow) Is shown. Similar to the diffuser pipe 57, each diffuser pipe is provided with air jets 68 (not shown) at positions facing each other on both sides of the diffuser pipe with a certain interval. As shown in the diffuser pipe 57, in each diffuser pipe, high-temperature and high-pressure combustion air sent from the wind box 10 flows in the diffuser pipe in the direction of the white arrow in the figure, and the air outlet 68. To the inclined surface 15.

  FIG. 5B is a diagram illustrating the connection between the diffuser pipe 67 and the fixing ring 64. In order to connect the diffuser pipe 67 and the fixing ring 64, an engagement plate 65 is attached to the diffuser pipe 67 in advance by welding. The air diffuser pipe 67 is fixed to the air diffuser pipe 67 by connecting the coupling plate 65 and the fixing ring 64 with the mounting bolt 66. Moreover, each air diffusion pipe 53-59 is installed so that the height from the sand removal pipe 4 may become the same height irrespective of the length of an air diffusion pipe. Thereby, it can prevent that each aeration pipe 53-59 deform | transforms into the direction of the inclined surface 15 with the weight of the sand 2 or incineration residue from the upward direction of the inclined surface 15. FIG.

  In addition, as shown in FIG. 5B, the air outlet 68 of the air diffusion pipe 67 is provided on the lower half side (the inclined surface 15 side) of the air diffusion pipe 67, and the combustion air is directed obliquely downward. Erupts. For example, when the air outlet 68 is provided on the upper half side or the center of the diffuser pipe 67, the combustion air is ejected upward or horizontally, and the sand accumulated above the diffuser pipe 67. Only 2 flows can occur. On the other hand, as in the present embodiment, the combustion air is jetted obliquely downward to convect the sand 2 deposited below the diffuser pipe 67 and the sand 2 deposited on the upper side. It becomes possible to stir. Thereby, while being able to keep the temperature of the sand 2 in the inclined surface 15 uniform, the incineration degree of the incineration waste 14 can be further advanced.

  As shown in FIG. 5 (a), the fixing rings 60, 61, 62 are fixed to the diffuser pipes 53 to 59, thereby preventing the incineration residue from falling into the sand removal pipe 4 (mesh (mesh). ) Is formed. As a result, it is possible to avoid a situation in which a large incombustible material in the incineration garbage becomes an incineration residue and falls into the sand draining pipe 4 to block the sand draining pipe 4. For example, in FIGS. 2 and 5A, the longest distance (for example, the length in the diagonal direction) inside the closed space formed by the diffuser pipe and the fixing ring is the diameter C of the sand removal pipe 4 (FIG. 5A). The aeration pipe and the fixing ring are arranged so as to be smaller than (). Further, by further increasing the length of the long air diffusion pipes 53, 55, 57, 59 protruding inside the sand removal pipe 4, it is possible to prevent a smaller incineration residue from falling into the sand removal pipe 4. On the other hand, the incineration residue caught on the mesh portion formed by the diffuser pipe and the fixing ring also prevents the sand 2 from falling to the sand removal pipe 4. Therefore, the position of the fixing ring 62 provided on the innermost side may be determined in consideration of the size of the incineration residue to be prevented from falling. And the length of the diagonal direction used as the maximum width of closed space (for example, a square mesh part) becomes the installation position of a fixing ring so that it may become smaller than the maximum size of the incineration residue which wants to prevent the fall to the sand removal pipe 4. What is necessary is just to determine the number and the number of aeration pipes.

  Further, in this embodiment, as shown in FIG. 3, the shape of the inclined surface 15 when viewed from above the incinerator S has a circular shape, but the circular shape is an example. It may be. In the present embodiment, the air diffusion pipes 53 to 59 are arranged radially around the sand removal pipe 4 in accordance with the shape of the inclined surface 15, but when the inclined surface 15 is rectangular, for example, the inclined surface 15. You may make it arrange | position in parallel with the wall surface which surrounds. Further, when the shape of the inclined surface 15 is circular, the fixing ring for connecting the diffuser pipe was circular, but when the shape of the inclined surface 15 is rectangular, the shape of the fixing ring is: It is not a circular shape but a linear shape (hereinafter, a linear fixing ring is referred to as a fixing member). Then, the fixing member is arranged so as to cross or be orthogonal to the air diffusion pipe, and by connecting with each air diffusion pipe, a mesh of a lattice configuration is provided by the air diffusion pipe and the fixing member, and the large size The incineration residue may be prevented from dropping into the sand removal pipe. In addition, you may provide the opening which considered the size of the incineration residue which wants to prevent a fall in the mesh part which covers the upper part of a sand removal pipe | tube. Further, in this embodiment, each air diffuser pipe is configured to rise from the inclined surface 15. However, for example, a configuration in which the air diffuser pipe extends from the inclined surface 15 in the horizontal direction may be used.

  In the present embodiment, the inclined surface 15 is not provided with the ejection port 44 for ejecting combustion air. For example, the inclined surface 15 is a stepped inclined surface, and the refractory 40 is installed on the rising surface of each step of each step portion in the same manner as the hearth portion 3, and the combustion air in the wind box 10 is blown through the blow pipe 9, It is good also as a structure supplied to the inclined surface 15 from the jet nozzle 44 via the ventilation pipe 42 and the ventilation pipe 41. FIG. As a result, combustion air is also supplied from a position close to the sand vent pipe 4, and the flow of the sand 2 in the inclined surface 15 is more efficiently and effectively performed as compared with the case of using only the air diffusion pipe. Incineration waste can be completely incinerated.

  As described above, according to the present embodiment, operation efficiency can be improved with minimum operation stop of the incinerator. By making a hearth part using a refractory having a blower tube penetrating the inside of the refractory material, it is possible to efficiently replace the refractory in the hearth part due to deterioration over time. Moreover, it is possible to prevent a large incineration residue, metal, or the like from falling on the sand vent pipe by installing an aeration pipe around the sand vent pipe installed on the most downstream side of the hearth. Thereby, the operation stop of an incinerator can be reduced and the fall of the operation efficiency of an incinerator can be suppressed.

x: Operation direction of pusher 13 1: Circulating sand extrusion device 2: Sand 3: Hearth part 4: Sand vent pipe 5, 6: Blower 7: Header pipe 8: Branch pipe 9: Blower pipe 10: Wind box 11: Air diffuser Pipe 12: Incineration waste 13: Pusher 14: Incineration waste 15: Inclined surface 16: Hopper 17: Biaxial crusher 18, 20: Blower 21: Chute part 22: Initial combustion part 23: Final combustion part 24: Secondary combustion part 25: exhaust gas 30: staircase 31: refractory 33, 34: diffuser pipe 35: diffuser pipe fixing ring 36: outer peripheral part 40 (refractory pipe 4): refractory 41, 42: blower pipe 43: blower pipe 44 : Jet 45: Refractory material 50: Screw roller 51: Sand supply roller 52: Wall portion 53 to 59: Air diffuser pipe 60 to 62, 64: Air diffuser pipe fixing ring 65: Joint plate 66: Mounting bolt 67: Air diffuser pipe 68: Air jet Mouth

Claims (7)

A refractory arranged to eject combustion air from the hearth of the incinerator,
The hearth is composed of a plurality of steps.
The incinerator is configured to burn the incinerated material on the fluidized medium while moving the fluidized medium deposited on the hearth to the downstream of the hearth by jetting the combustion air,
The refractory is
Formed of refractory material,
A first blower pipe having a jet outlet for jetting the combustion air; and a second blower pipe connected to the first blower pipe and supplying the combustion air to the first blower pipe;
The first blower pipe and the second blower pipe communicate with each other and are arranged so as to penetrate the inside of the refractory material,
The jet outlet of the first blower pipe is provided on the first wall surface of the refractory,
The second air duct has a first end and a second end opposite to the first end,
The second air duct is connected to the first air duct, the first end protrudes into the first air duct, and the second end includes the first wall surface provided with the jet port. Protrudes from the second wall of the different refractory,
A refractory material in which a predetermined gap is provided between the first and second blast pipes and the refractory material inside the refractory material. The step portion on which the refractory according to claim 1 is installed;
A funnel-shaped inclined surface that is arranged downstream of the hearth and that guides the incineration residue of the fluid medium and the incinerated material moved by the combustion air toward the sand pipe;
A plurality of air diffuser pipes arranged at intervals so as to cover the sand vent pipe between the hearth and the sand vent pipe, and formed with a plurality of air jets;
A plurality of fixing members arranged at intervals to connect the plurality of air diffusers,
The incinerated material on the fluidized medium is combusted while the fluidized medium deposited on the hearth is moved downstream of the hearth by the combustion air ejected from the hearth configured by the plurality of stepped portions. An incinerator for moving the incineration residue to the sand extraction pipe,
An incinerator in which the longest distance inside a closed space formed by two adjacent diffuser tubes and two adjacent fixed members is smaller than the diameter of the sand pipe.   The plurality of air diffusion tubes are arranged radially around the sand extraction tube above the inclined surface, or are arranged in a lattice shape so as to cover the sand extraction tube above the inclined surface. The incinerator described in 1. The air diffuser is
Rising upward from the inclined surface, and
A first air diffuser, and a second air diffuser shorter than the first air diffuser,
The rising positions of the first air diffuser and the second air diffuser are at the same height from the sand extraction tube of the inclined surface,
4. The incinerator according to claim 2, wherein an end portion of the first air diffusion pipe on the sand vent pipe side is located on an inner side than an outer peripheral portion of the sand vent pipe.   The incinerator according to claim 4, wherein the first air diffuser and the second air diffuser are installed so that the height from the sand vent tube is the same. The inclined surface is composed of a plurality of step portions,
The incinerator according to any one of claims 2 to 5, wherein the refractory is installed in the stepped portion.   The position of the jet outlet in a specific staircase portion of the plurality of staircase portions of the hearth and the position of the jet outlet in the next staircase portion are orthogonal to the jet direction of the combustion air. The incinerator according to any one of claims 2 to 5, wherein the plurality of refractories are arranged so as not to overlap in the width direction.

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