JP6039005B1 - Biomass fuel incinerator - Google Patents

Abstract

An object of the present invention is to reliably remove a generated clinker. SOLUTION: An incineration chamber 410 is provided in an incineration chamber surrounded by a cylindrical outer wall, in which fuel is placed and incinerated; A clinker having a fuel supply chamber 413 for supplying fuel, a main body portion provided along the diameter of the incineration dish 410, and a protrusion protruding from the main body part toward the incineration dish. A removing member 426, a rotating shaft 417 for rotating the clinker removing member 426, and a driving means for rotating the rotating shaft 417 are provided, and the clinker generated in the incineration dish is removed by the rotation of the clinker removing member 426. . [Selection] Figure 1

Description

  The present invention relates to a biomass fuel incinerator, and more particularly to a biomass fuel incinerator capable of removing clinker while the incinerator is in an operating state.

  In Patent Document 1, a feed valve is provided via a porous cylinder at the lower end opening of a cylindrical combustion furnace body, and the rotation of the feed valve is switched between normal rotation and reverse rotation by a rotation drive instruction unit. It is disclosed that the burned charcoal of the biomass fuel is prevented from falling off the porous cylinder and the clinker is not generated on the inner wall of the combustion furnace main body.

  In Patent Document 2, since a flowing water pipe for generating curtain-shaped flowing water in an incinerator is piped, dust in contact with the curtain-shaped flowing water is solidified and hardly adheres to the wall of the incinerator. An incinerator having an effect of preventing clinker and removing clinker which has already adhered and grown is disclosed.

  Further, in Patent Document 3, two rows of air discharge ports are formed obliquely on the lower surface of an air supply pipe disposed on the bottom surface of the incinerator, and the interval between the air supplies is passed through a scraper for scraping incineration ash. An incinerator is disclosed that prevents the air discharge port from being clogged or damaged by scraping out of the scraper by arranging them at intervals.

JP 2007-291155 A JP 2008-82660 A JP 2005-274001 A

  However, according to the incinerator of patent document 1, since it does not act directly on the site | part which a clinker generate | occur | produces, an effect must be limited.

  In addition, the incinerator of Patent Document 2 generates flowing water from a rotary kiln outlet for drying and incinerating waste to a site where clinker is likely to occur, such as a site following a secondary incinerator. It is. Therefore, running water cannot be applied to a type of incinerator that simply incinerates biomass fuel.

  Further, the incinerator of Patent Document 3 may not be able to be removed when ash or clinker scraping residue covers the air discharge port or when the clinker is generated near the air discharge port. There is a possibility that proper incineration cannot be secured.

  The present invention has been made in view of the current state of the incinerator as described above, and its purpose is to prevent the combustion from being hindered by the generated clinker, particularly in a high-efficiency incinerator. Even if the clinker is generated and the glass becomes melted during high-temperature combustion, the air supply path is blocked and combustion is stopped reliably. It is another object of the present invention to provide a biomass fuel incinerator capable of reliably removing generated clinker from the center of combustion.

A biomass fuel incinerator according to the present invention is provided in an incineration chamber surrounded by a cylindrical outer wall, an incineration tray provided in the incineration chamber, on which fuel is placed and incinerated, and a lower center of the incineration tray. A fuel supply chamber for supplying biomass fuel to the upper incineration dish, a fuel conveyance path for conveying biomass fuel from a fuel hopper to the fuel supply chamber, and a diameter of the incineration dish. A clinker removing member having a main body portion extending along the main body and a protrusion protruding from the main body portion toward the incineration dish, and extending from the center of the bottom surface of the incineration chamber to the center of the main body of the clinker removing member. wherein a rotary shaft for rotating, comprising a drive means for rotating the rotary shaft, wherein is configured to remove clinker generated in incineration pan by the rotation of the clinker removal member, and the outer peripheral portion of the incineration pan A gap is provided between the wall of the incineration chamber, an incineration ash primary accumulation chamber is provided at the bottom of the incineration chamber, and the incineration ash and clinker on the incineration dish are incinerated from the gap. The ash primary accumulation chamber is configured to be dropped, and at a predetermined position on the floor surface of the incineration ash primary accumulation chamber, a hole for introducing the incineration ash and clinker into the lower incineration ash stacker is formed, and the incineration The floor surface of the ash primary accumulation chamber is provided with floor cleaning rotary feathers for dropping incinerated ash and clinker accumulated on the floor surface by a rotation shaft at the center of the floor surface from the hole .

  In the biomass fuel incinerator according to the present invention, a first air chamber is provided in a lower portion of the fuel supply chamber, and the axial direction of the rotary shaft from the portion of the first air chamber in the rotary shaft and An air flow path is formed in the main body part and the protrusion part of the clinker removing member, an air hole communicating from the air flow path to the outside is formed in the protrusion part, and air is supplied to the first air chamber. A first air supply path is attached.

  In the biomass fuel incinerator according to the present invention, a second air chamber is provided in a lower portion of the incineration dish, and the incineration dish communicates with the second air chamber and the surface side of the incineration dish. The second air chamber is provided with a second air supply path for supplying air from the outside.

  In the biomass fuel incinerator according to the present invention, air is supplied together with the biomass fuel from the fuel conveyance path and the fuel supply chamber to a central portion of the incineration dish.

  In the biomass fuel incinerator according to the present invention, crushing means for crushing the falling clinker is provided between the hole formed in the floor surface of the incineration ash primary accumulation chamber and the incineration ash stacker. It is characterized by.

  The biomass fuel incinerator according to the present invention is characterized in that an air nozzle for sending air to the incineration chamber is provided on a wall portion of the incineration chamber above the clinker removing member.

  According to the present invention, the clinker removal having a main body portion along the diameter of the incineration dish and a protrusion protruding from the main body part in the incineration dish direction above the incineration dish on which the fuel is placed and incinerated. Since the clinker generated in the incineration dish is removed by the rotation of the clinker removing member, the clinker is continuously generated in the high-efficiency incinerator, and the glass is melted during high-temperature combustion. Even in the incineration dish, the integrated clinker can be reliably removed from the incineration dish.

  Further, when air is supplied from the first air supply path to the first air chamber combustion chamber, the portion of the first air chamber and the shaft in the axial direction of the rotation shaft, the main body of the clinker removing member, and the clinker removing member Air is sent through the air flow path formed in these, air can be sent into the combustion chamber from the air holes formed in the clinker removal member, and the air necessary for combustion is reliably sent It is possible to reliably prevent a situation where a clinker is generated continuously in a high-efficiency incinerator and the combustion is stopped by blocking the air supply path even if it becomes a molten glass during high-temperature combustion. It is.

Front sectional drawing of the biomass fuel incinerator which concerns on embodiment of this invention. The principal part top view of the biomass fuel incinerator which concerns on embodiment of this invention. II sectional drawing of FIG. The principal part front sectional view of the biomass fuel incinerator concerning the embodiment of the present invention.

  Hereinafter, an embodiment of a biomass fuel incinerator according to the present invention will be described with reference to the accompanying drawings. In the drawings, the same components are denoted by the same reference numerals and redundant description is omitted. In FIG. 1, front sectional drawing of the biomass fuel incinerator which concerns on embodiment is shown. The biomass fuel incinerator has an incineration chamber 401 surrounded by a cylindrical outer wall 401A. An incineration dish 410 is provided at a required height position of the incineration chamber 401. The incineration dish 410 has a flat disc-shaped central portion 411 and a ring-shaped outer peripheral portion 412 in which a hole is formed in the central portion continuous around the central portion 411.

  A fuel supply chamber 413 for supplying biomass fuel to the upper incineration dish 410 is provided below the center of the incineration dish 410. The fuel supply chamber 413 is a chamber surrounded by a cylindrical wall having the same diameter as the central portion 411 of the incineration dish 410. The fuel supply chamber 413 is connected to a fuel transfer path 414 including a screw 414A for transferring biomass fuel to the fuel supply chamber 413 in the radial direction. The screw 414A is rotated by a motor 415 via power transmission means such as a sprocket or a chain.

  Above the outer end side of the fuel conveyance path 414, a hopper 416 for supplying biomass fuel and supplying it to the fuel conveyance path 414 is provided. A rotation shaft 417 extending in the vertical direction is provided at the center of the fuel supply chamber 413, and a screw 418 is provided on the rotation shaft 417. The rotating shaft 417 extends to the bearings 421 and 422 of the base portion 420 of the apparatus, and is supported by the bearings 421 and 422. The rotating shaft 417 is rotated by a motor 423. Biomass fuel and air are supplied from the hopper 416 to the upper portion of the incineration dish 410 via the fuel conveyance path 414 and the fuel supply chamber 413.

  For example, the sprocket 419 is provided on the rotating shaft 417, and the sprocket 424 is fitted on the shaft of the motor 423. The sprocket 419 and the sprocket 424 are coupled by a chain, and the rotating shaft 417 is connected to the motor. 423 is rotated. The motor 423 and the sprockets 419 and 424 are rotation driving means for the rotating shaft 417, and may have other configurations as long as they can rotate. The screw 418 is also rotated by the rotation of the rotating shaft 417, and the biomass fuel in the fuel supply chamber 413 is pushed upward and supplied to the incineration dish 410 from the central hole of the incineration dish 410.

  A clinker removing member 426 is provided above the incineration dish 410. The clinker removing member 426 includes a substantially bar-shaped main body 430 extending along the diameter of the incineration dish 410 as shown in a plan view in FIG. The main body portion 430 includes a central portion 427 having a circular planar shape having a shaft hole 427A fitted to the rotation shaft 417, and arm portions 428 and 428 extending from the central portion 427 to the left and right. In the present embodiment, the two arm portions 428 and 428 are provided, but three or more arm portions may be provided.

  A plurality of projecting portions 431 extend from the lower surfaces of the arm portions 428 and 428 of the main body portion 430 to a position close to the outer peripheral portion 412 of the incineration dish 410. Further, a rotating body 433 is coupled to the lower surface of the central portion 427 of the main body portion 430 via a frustoconical connecting portion 432. The rotating body 433 has a truncated cone shape opposite to the connecting portion 432, and includes a claw body 434 that protrudes downward from the outer peripheral portion of the bottom surface to a position close to the rotating shaft 417.

  A second air chamber 440 is provided below the incineration dish 410. That is, the vertical wall 441 extends downward from the outer peripheral edge of the outer peripheral portion 412 of the incineration dish 410, and the flat bottom plate 442 intersects the vertical wall 441 in the radial direction from the lower surface of the boundary portion between the outer peripheral portion 412 and the central portion 411. It extends to the position to do. The bottom plate 442 and the vertical wall 441 are joined at an intersecting position.

  As shown in the partially enlarged view of FIG. 1, the incineration dish 410 is formed with innumerable communication holes 429 that communicate the surface side of the incineration dish 410 with the second air chamber 440. A second air supply path 443 for supplying air from the outside is attached to the second air chamber 440.

  An air flow path 435 is formed inside the main body 430 and the protrusion 431 of the clinker removing member 426. The projecting portion 431 has innumerable air holes 436 that communicate with the air flow path 435 and the outside.

  A first air chamber 450 is provided below the fuel supply chamber 413. In addition, an inner shaft hole 438 that is an air flow path extending in the axial direction is formed inside the rotation shaft 417. The shaft hole 438 communicates with a hole 451 that communicates with the first air chamber 450, a hole 452 that communicates with the air flow path 435 of the clinker removal member 426, and a hole 453 that communicates with the vicinity of the central portion 411 of the incineration dish 410. doing. A first air supply path 454 for supplying air is attached to the first air chamber 450. The first air supply path 454 may be configured integrally with the second air supply path 443.

  The structure of the incineration dish 410, the fuel supply chamber 413, the second air chamber 440, and the structure of the first air chamber 450 are integrated, as shown in FIG. 3, which is a cross-sectional view taken along the line II of FIG. In addition, two arms 461 extending from an outer wall 460 provided at the lower portion of the incineration chamber 401 and a connecting member 462 are supported.

  The bottom of the incineration chamber 401 is an incineration ash primary accumulation chamber 463. A gap S is provided between the outer peripheral part of the incineration dish 410 and the wall part of the incineration chamber 401, and the incineration ash and clinker on the incineration dish 410 are dropped from the gap S into the incineration ash primary accumulation chamber 463. The

  A hole 464 for introducing incineration ash and clinker into a lower incineration ash stacker (not shown) is formed at a predetermined position on the floor surface of the incineration ash primary accumulation chamber 463. Further, the floor surface of the incineration ash primary accumulation chamber 463 is provided with three floor cleaning rotary feathers 465 for dropping the incineration ash and clinker accumulated on the floor surface from the hole 464 by the rotation shaft 417 at the center of the floor surface. . Three are just examples.

  Ratchet roll crushers 466 and 466 which are crushing means for crushing the falling clinker are provided between a hole 464 formed on the floor surface of the incinerated ash primary accumulation chamber 463 and an incineration ash stacker (not shown). The ratchet roll crushers 466 and 466 crush the falling clinker by crushing teeth rotating around the shafts 466A and 466A. The shafts 466A and 466A are rotationally driven by a motor 467 via sprockets and chains.

  The portion of the outer wall 401A that constitutes the incineration chamber 401 can be configured as shown in FIG. An inner wall 401B is provided, and an air chamber 471 is provided between the outer wall 401A and the inner wall 401B. The outer wall 401A of the air chamber 471 may be covered with a heat insulating material.

  Reference numeral 480 denotes an ignition nozzle that ignites biomass fuel on the incineration dish 410 at the initial stage. An air supply pipe 481 is connected to the outer wall 401 </ b> A below the air chamber 471, and air is supplied via a valve 482. A discharge pipe 483 is connected to the outer wall 401A above the air chamber 471. For example, a fan (not shown) can be provided in the discharge pipe 483. In the air chamber 471, air heated by the heat of the incineration chamber 401 can be taken from the discharge pipe 483. The air taken in from the discharge pipe 483 can be sent to the first air chamber 450 and the second air supply path 443.

  In addition, a plurality of air nozzles 485 whose tips are directed downward are provided on the inner wall 401B above the incineration chamber 401. Air is discharged from the air nozzle 485 toward the lower side of the incineration chamber 401, and the incomplete combustion gas or the vaporized gas of the biomass fuel can be returned to the lower flame and burned efficiently.

  Further, the inner wall 401B below the incineration chamber 401 is provided with a plurality of air nozzles 486 whose tips are directed in the horizontal direction. From the air nozzle 486, air is discharged slightly upward of the incineration dish 410 in the incineration chamber 401, and contributes to the combustion of biomass fuel on the incineration dish 410.

  Combustion exhaust gas can be discharged from an exhaust port provided above the incineration chamber 401 to be used for boiling water, heating for agricultural facilities, or the like. Moreover, an exhaust port may be provided toward the side wall of the rotary kiln, and it may be used for heating the raw material of the biomass fuel to be dried in the rotary kiln.

  In the biomass fuel incinerator configured as described above, biomass fuel incineration is performed as follows. Biomass fuel is put into the hopper 416, and rotation of driving means such as motors 415, 423, and 467 is started. As a result, the biomass fuel is conveyed from the hopper 416 to the fuel supply chamber 413 by the screw 414A, and further sent upward by the screw 418 to reach the incineration dish 410.

  The ignition burner 480 is ignited from the time just before the biomass fuel arrives on the incineration dish 410. The biomass fuel in the incineration dish 410 is ignited by the ignition burner 480 and combustion starts. Although the combustion time by the ignition burner 480 is changed depending on the state of the biomass fuel, it can be approximately 15 minutes.

  When the biomass fuel burns on the incineration dish 410, air is supplied from the second air supply path 443 to the second air chamber 440, and the air in the second air chamber 440 is on the surface of the incineration dish 410. Are supplied to the upper side of the incineration dish 410 through innumerable communication holes 429.

  In addition, air is supplied from the first air supply path 454 to the first air chamber 450, and the air in the first air chamber 450 passes through the hole 451 and the shaft inner hole 438 in the rotating shaft 417. And is discharged from the hole 453 to the vicinity of the central portion 411 of the incineration dish 410, reaches the air flow path 435 from the shaft inner hole 438, and is supplied to the upper side of the incineration dish 410 from the innumerable air holes 436 of the protrusions 431. .

  Since the clinker removing member 426 and the rotating body 433 are rotated by the rotating shaft 417 during the combustion of the biomass fuel, the biomass fuel burns on the incineration dish 410 while being stirred. As the combustion of the biomass fuel proceeds, incineration ash and clinker are generated on the incineration dish 410, but the clinker is scraped off by the rotation of the clinker removing member 426 and the rotating body 433 and is not fixed on the incineration dish 410. That is, in particular, it is possible to reliably prevent a situation in which a clinker is continuously generated in a high-efficiency incinerator and the combustion is stopped by closing the air supply path even when the clinker is melted into a glassy state. Is possible.

  The clinker and incineration ash scraped by the rotation of the clinker removing member 426 and the rotating body 433 are removed from the gap S between the outer periphery of the incineration dish 410 and the wall of the incineration chamber 401, and the floor surface of the incineration ash primary accumulation chamber 463. It is dropped to. Three floor cleaning rotary blades 465 are rotating on the floor surface of the incineration ash primary accumulation chamber 463, and are moved so as to sweep the clinker and the incineration ash that have fallen on the floor surface of the incineration ash primary accumulation chamber 463. Then, it is dropped from the hole 464 to the meshing portions of the ratchet roll crushers 466 and 466.

  As described above, the clinker removing member 426 and the rotating body 433 are rotated by the rotating shaft 417, whereby the clinker in the molten state is removed from the incineration dish, and is dropped onto the floor surface of the incineration ash primary accumulation chamber 463 and cooled. Solidifies into a glassy solid. The solid clinker arrives at the meshing portion of the ratchet roll crushers 466 and 466 by the rotation of the blades 465, and the clinker and the incineration ash are finely crushed and dropped to an incineration ash stacker (not shown). In other words, the clinker that is continuously generated and melted in a high-efficiency incinerator is removed as a large molten mass from the portion of the incineration dish where the air supply function is concentrated in the molten state, cooled, solidified and pulverized. A series of processes that become fine waste and accumulate in the incineration ash stacker is secured. The incineration ash accumulated in the incineration ash stacker can be used as an agricultural fertilizer.

401 Incineration chamber 401A Outer wall 401B Inner wall 410 Incineration tray 413 Fuel supply chamber 414 Fuel transfer path 414A Screw 416 Hopper 417 Rotating shaft 426 Clinker removal member 428 Arm portion 429 Communication hole 430 Main body portion 431 Projection portion 432 Connection portion 433 Rotating body 434 Claw body 435 Air flow path 436 Air hole 438 Shaft inner hole 440 Second air chamber 443 Second air supply path 450 First air chamber 454 First air supply path 463 First incineration ash primary accumulation chamber 466 First Ratchet roll crusher 471 First air chamber 480 First ignition burner 481 First air supply pipe

Claims (6)

An incineration chamber surrounded by a cylindrical outer wall;
An incineration dish provided in the incineration chamber for incinerating the fuel;
A fuel supply chamber provided below the center of the incineration dish and supplying biomass fuel to the upper incineration dish;
A fuel transfer path for transferring biomass fuel from a fuel hopper to the fuel supply chamber;
A clinker removing member that is provided above the incineration dish and has a main body part along the diameter of the incineration dish, and a protrusion that protrudes from the main body part in the incineration dish direction,
A rotating shaft that extends from the center of the bottom surface of the incineration chamber to the center of the main body of the clinker removing member, and rotates the clinker removing member;
Driving means for rotating the rotating shaft, and configured to remove clinker generated in the incineration dish by rotation of the clinker removing member ,
A gap is provided between the outer peripheral portion of the incineration dish and the wall portion of the incineration chamber,
At the bottom of the incineration chamber, an incineration ash primary accumulation chamber is provided,
Incineration ash and clinker on the incineration dish are configured to fall from the gap to the incineration ash primary accumulation chamber,
At a predetermined position on the floor surface of the incineration ash primary accumulation chamber, a hole for introducing the incineration ash and clinker into the lower incineration ash stacker is formed,
Biomass fuel, wherein the floor of the incineration ash primary accumulation chamber is provided with floor cleaning rotary feathers for dropping incineration ash and clinker accumulated on the floor surface by a rotation shaft at the center of the floor surface from the hole. Incinerator. A first air chamber is provided at a lower portion of the fuel supply chamber,
An air flow path is formed in the axial direction of the rotating shaft from the portion of the first air chamber in the rotating shaft and in the main body portion and the protruding portion of the clinker removing member,
The protrusion is formed with an air hole leading from the air channel to the outside,
The biomass fuel incinerator according to claim 1, wherein a first air supply path for supplying air is attached to the first air chamber. A second air chamber is provided in a lower portion of the incineration dish, and a communication hole is formed in the incineration dish to communicate the second air chamber and the surface side of the incineration dish.
The biomass fuel incinerator according to claim 1 or 2, wherein a second air supply path for supplying air from the outside is attached to the second air chamber.   The biomass fuel incinerator according to any one of claims 1 to 3, wherein air is supplied together with biomass fuel from the fuel conveyance path and the fuel supply chamber to a central portion of the incineration dish. The crushing means which crushes the clinker which falls is provided between the hole formed in the floor of the incineration ash primary storage room, and the incineration ash stacker. The biomass fuel incinerator according to any one of the preceding claims. The biomass fuel according to any one of claims 1 to 5, wherein an air nozzle for sending air to the incineration chamber is provided in a wall portion of the incineration chamber above the clinker removing member. Incinerator.

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