EP2587146B1 - Fluidized bed furnace and waste treatment method - Google Patents
Fluidized bed furnace and waste treatment method Download PDFInfo
- Publication number
- EP2587146B1 EP2587146B1 EP11797836.1A EP11797836A EP2587146B1 EP 2587146 B1 EP2587146 B1 EP 2587146B1 EP 11797836 A EP11797836 A EP 11797836A EP 2587146 B1 EP2587146 B1 EP 2587146B1
- Authority
- EP
- European Patent Office
- Prior art keywords
- waste
- fluidized bed
- fluidization region
- fluidization
- region
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Not-in-force
Links
- 239000002699 waste material Substances 0.000 title claims description 276
- 238000000034 method Methods 0.000 title claims description 21
- 238000005243 fluidization Methods 0.000 claims description 191
- 239000002245 particle Substances 0.000 claims description 118
- 239000000126 substance Substances 0.000 claims description 97
- 239000004576 sand Substances 0.000 claims description 36
- 238000002309 gasification Methods 0.000 claims description 15
- 238000007664 blowing Methods 0.000 claims description 9
- 238000010438 heat treatment Methods 0.000 claims description 5
- 230000015572 biosynthetic process Effects 0.000 claims 2
- 238000002360 preparation method Methods 0.000 claims 2
- 239000007789 gas Substances 0.000 description 199
- VYPSYNLAJGMNEJ-UHFFFAOYSA-N Silicium dioxide Chemical compound O=[Si]=O VYPSYNLAJGMNEJ-UHFFFAOYSA-N 0.000 description 37
- 238000002485 combustion reaction Methods 0.000 description 25
- 239000011261 inert gas Substances 0.000 description 11
- 239000010813 municipal solid waste Substances 0.000 description 11
- 238000010586 diagram Methods 0.000 description 10
- 238000000926 separation method Methods 0.000 description 9
- QVGXLLKOCUKJST-UHFFFAOYSA-N atomic oxygen Chemical compound [O] QVGXLLKOCUKJST-UHFFFAOYSA-N 0.000 description 7
- 239000001301 oxygen Substances 0.000 description 7
- 229910052760 oxygen Inorganic materials 0.000 description 7
- 239000000203 mixture Substances 0.000 description 6
- 230000005855 radiation Effects 0.000 description 5
- 230000000087 stabilizing effect Effects 0.000 description 4
- 239000004033 plastic Substances 0.000 description 3
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 3
- IJGRMHOSHXDMSA-UHFFFAOYSA-N Atomic nitrogen Chemical compound N#N IJGRMHOSHXDMSA-UHFFFAOYSA-N 0.000 description 2
- 239000003570 air Substances 0.000 description 1
- 238000003491 array Methods 0.000 description 1
- 238000006243 chemical reaction Methods 0.000 description 1
- 230000001419 dependent effect Effects 0.000 description 1
- 230000005484 gravity Effects 0.000 description 1
- 238000002844 melting Methods 0.000 description 1
- 230000008018 melting Effects 0.000 description 1
- 229910052757 nitrogen Inorganic materials 0.000 description 1
- 239000002985 plastic film Substances 0.000 description 1
- 238000010248 power generation Methods 0.000 description 1
- 230000000452 restraining effect Effects 0.000 description 1
- 239000000377 silicon dioxide Substances 0.000 description 1
- 238000005507 spraying Methods 0.000 description 1
- 239000002344 surface layer Substances 0.000 description 1
- 239000002023 wood Substances 0.000 description 1
Images
Classifications
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F23—COMBUSTION APPARATUS; COMBUSTION PROCESSES
- F23G—CREMATION FURNACES; CONSUMING WASTE PRODUCTS BY COMBUSTION
- F23G5/00—Incineration of waste; Incinerator constructions; Details, accessories or control therefor
- F23G5/30—Incineration of waste; Incinerator constructions; Details, accessories or control therefor having a fluidised bed
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F23—COMBUSTION APPARATUS; COMBUSTION PROCESSES
- F23C—METHODS OR APPARATUS FOR COMBUSTION USING FLUID FUEL OR SOLID FUEL SUSPENDED IN A CARRIER GAS OR AIR
- F23C10/00—Fluidised bed combustion apparatus
- F23C10/18—Details; Accessories
- F23C10/20—Inlets for fluidisation air, e.g. grids; Bottoms
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F23—COMBUSTION APPARATUS; COMBUSTION PROCESSES
- F23C—METHODS OR APPARATUS FOR COMBUSTION USING FLUID FUEL OR SOLID FUEL SUSPENDED IN A CARRIER GAS OR AIR
- F23C10/00—Fluidised bed combustion apparatus
- F23C10/18—Details; Accessories
- F23C10/22—Fuel feeders specially adapted for fluidised bed combustion apparatus
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F23—COMBUSTION APPARATUS; COMBUSTION PROCESSES
- F23C—METHODS OR APPARATUS FOR COMBUSTION USING FLUID FUEL OR SOLID FUEL SUSPENDED IN A CARRIER GAS OR AIR
- F23C10/00—Fluidised bed combustion apparatus
- F23C10/18—Details; Accessories
- F23C10/24—Devices for removal of material from the bed
- F23C10/26—Devices for removal of material from the bed combined with devices for partial reintroduction of material into the bed, e.g. after separation of agglomerated parts
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F23—COMBUSTION APPARATUS; COMBUSTION PROCESSES
- F23G—CREMATION FURNACES; CONSUMING WASTE PRODUCTS BY COMBUSTION
- F23G5/00—Incineration of waste; Incinerator constructions; Details, accessories or control therefor
- F23G5/02—Incineration of waste; Incinerator constructions; Details, accessories or control therefor with pretreatment
- F23G5/027—Incineration of waste; Incinerator constructions; Details, accessories or control therefor with pretreatment pyrolising or gasifying stage
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F23—COMBUSTION APPARATUS; COMBUSTION PROCESSES
- F23G—CREMATION FURNACES; CONSUMING WASTE PRODUCTS BY COMBUSTION
- F23G2205/00—Waste feed arrangements
- F23G2205/10—Waste feed arrangements using ram or pusher
- F23G2205/101—Waste feed arrangements using ram or pusher sequentially operated
Definitions
- the present invention relates to a fluidized bed furnace designed to heat waste in a fluidized bed formed by fluidizing fluidizable particles to thereby extract a combustible gas from the waste, and a waste treatment method.
- this fluidized bed furnace comprises a furnace body 104 having fluidizable sand (fluidizable particles) 102 in a furnace bottom section, and an air supply section 106 for supplying air into the fluidizable sand 102 in the furnace bottom section so as to fluidize the fluidizable sand 102 to form a fluidized bed.
- the furnace body 104 has a sidewall. The sidewall is provided with an input section 108 for inputting waste onto the fluidized bed therefrom.
- the air supply section 106 is adapted to supply air into high-temperature fluidizable sand 102. Consequently, the fluidizable sand 102 is fluidized in a levitated or suspended state to form a fluidized bed.
- the air supply section 106 is adapted to supply air in such a manner that a fluidized state of the fluidizable sand 102 becomes approximately equalized in the entire region of the fluidized bed so as to allow waste input from the input section 108 onto the fluidized bed to be entrapped inside the fluidized bed and efficiently combusted.
- Waste input into the fluidized bed furnace 100 is entrapped in the active fluidized bed and combusted or gasified.
- waste is intermittently input, combustible substances in the waste are rapidly combusted, so that a rapid fluctuation in amount, concentration, etc., of a generated combustible gas will repeatedly occur.
- a change in the gasification reaction is largely dependent on a quantitative characteristic in supply of waste.
- it is impossible to stably generate a combustible gas.
- a large amount of easily combustible trash such as paper or sheet-shaped plastic is comprised in waste, a fluctuation of generation of a combustible gas becomes larger, and therefore there is a need for stabilizing the gas generation.
- a fluidized bed furnace is designed to heat waste by high-temperature fluidizable particles, to extract a combustible gas from the waste.
- the fluidized bed furnace comprises fluidizable particles 12, a furnace body 20, a gas supply section 30, a waste supply section 40 and a sand circulation device 50.
- the fluidizable particles 12 are particles make up a fluidized bed 14 to heat waste 18, inside the furnace body 20. More specifically, the fluidizable particles 12 are mixed with waste 18 while being heated up to a high temperature by combustion of a part of waste components, so that the waste 18 is gasified to generate a combustible gas.
- the fluidizable particles 12 may be silica sand.
- the furnace body 20 is configured to internally have the fluidizable particles 12 and extract a combustible gas from waste 18 by means of the fluidizable particles 12 in a high temperature state.
- the furnace body 20 has a bottom wall 21 supporting the fluidizable particles 12 from therebelow, a sidewall 22 standing upwardly from the bottom wall 21, and a combustible gas outlet portion 23 provided at an upper end of the sidewall 22.
- the sidewall 22 has a rectangular tubular shape extending in an up-down (vertical) direction. Specifically, as also illustrated in FIG. 2 , the sidewall 22 has a front wall (supply-side sidewall portion) 24 and a rear wall 25 which are disposed in opposed and spaced-apart relation to each other in a front-rear direction (in FIG. 2 , in a right-left direction), and a pair of lateral walls 26, 26 each connecting corresponding ends of the front wall 24 and the rear wall 25.
- the lateral walls 26, 26 are disposed parallel to each other.
- the furnace body 20 has a shape in plan view, in which a dimension in a width direction (widthwise dimension) as a distance between the lateral walls 26, 26 is equalized in the front-rear direction.
- a portion (front wall) 24 of the sidewall 22 located on a side opposite to an aftermentioned non-combustible substance discharge port 29 across a center position of the bottom wall 21 has a sand introduction section 27 and a waste introduction port 28.
- the sand introduction section 27 is adapted to introduce fluidizable particles 12 into the furnace body 20, and the waste introduction port 28 is adapted to introduce waste 18 into the furnace body 20.
- the sand introduction section 27 is provided at each of widthwise opposite ends of a lower portion of the front wall 24 to allow fluidizable particles to be introduced to widthwise opposite end areas of an inside of the furnace body 20 (see FIG. 2 ).
- the sand introduction section 27 is provided at a height position where fluidizable particles 12 can be input from above the fluidizable particles 12 supported by the bottom wall 21 (fluidized bed 14), toward the fluidized bed 14. It is to be noted that an input area of fluidizable particles 12 is not limited to the widthwise opposite end areas.
- the input area of fluidizable particles 12 may be one of the widthwise opposite end areas.
- the input area of fluidizable particles 12 may be an upper surface of the introduced waste 18 (a central area adjacent to the front wall 24 in FIG. 2 ).
- the fluidizable particles 12 serve as an ignition source to allow only easily combustible trash to be stably combusted (gasified) initially.
- the waste introduction port 28 is provided in approximately the entire region of the lower portion of the front wall 24 in the width direction.
- the waste introduction port 28 is provided at a height position where waste 18 can be pushed generally horizontally onto an upper surface of the fluidized bed 14 made up of the fluidizable particles 12 supported by the bottom end 21.
- the waste introduction port 28 is provided in such a manner that a lower end thereof is located at a position slightly higher than the upper surface of the fluidized bed 14.
- the combustible gas outlet portion 23 is designed to discharge a combustible gas generated inside the furnace body 20.
- the combustible gas outlet portion 23 has an outer diameter squeezed more than the sidewall 22, so that a duct or the like for supplying the combustible gas obtained in the furnace body 20 to a subsequent stage, for example, a gas engine for electric power generation processes, can be connected thereto.
- the bottom wall 21 has a non-combustible substance discharge port 29 provided at a position offset from the center position thereof in a specific direction to discharge non-combustible substances in waste 18 together with a part of the fluidizable particles 12.
- the non-combustible substance discharge port 29 has an opening extending over the widthwise entire region of the bottom wall 21.
- the bottom wall 21 has an upper surface 21a is inclined to become lower toward the non-combustible substance discharge port 29 so as to cause the non-combustible substances to fall on the upper surface 21a.
- the bottom wall 21 in this embodiment has a non-combustible substance discharge port 29 at a position offset rearwardly, and an upper surface 21a of the bottom wall 21 extends rearwardly (in FIG. 1 , in a left-to-right direction) at a constant downward inclination.
- the upper surface 21a of the bottom wall 21 has an inclination angle of 15 degrees to 25 degrees with respect to a horizontal plane.
- the gas supply section 30 is designed to blow a fluidizing gas from the bottom wall 21 toward the fluidizable particles 12 to fluidize the fluidizable particles 12.
- the gas supply section 30 comprises a plurality of nozzles 31 for blowing the fluidizing gas, a gas box 32 for supplying the fluidizing gas to the nozzles 31, and a gas feeding unit 33 for feeding the fluidizing gas to the gas box 32.
- the plurality of nozzles 31 are installed to the bottom wall 21 in spaced-apart relation to each other in the width direction and the front-rear direction, i.e., in a lattice arrangement. Each of the nozzles 31 is attached to the bottom wall 21 to penetrate through the bottom wall 21.
- the bottom wall 21 is divided into a front region 21b and a rear region 21c. Then, the plurality of nozzles 31 are installed to the front and rear regions 21b, 21c in such a manner that the number of nozzles 31 provided in the front region 21b becomes greater than the number of nozzles 31 provided in the rear region 21c.
- a relationship between the respective numbers of nozzles 31 in the front and rear regions 21b, 21c is not particularly limited.
- the number of nozzles 31 in the front region 21b may be equal to the number of nozzles 31 in the rear region 21c.
- the number of nozzles 31 in the rear region 21c may be greater than the number of nozzles 31 in the front region 21b.
- the gas box 32 has a box shape extending in the width direction.
- the gas box 32 serves as a header for distributing the fluidizing gas to an array of the nozzles 31 arranged side-by-side in the width direction in the bottom wall 21.
- the gas box 32 has a function of equalizing respective flow volumes of the fluidizing gas to be blown from the array of nozzles 31 arranged in the width direction.
- a plurality of the gas boxes 32 are provided on the side of a lower surface of the bottom wall 21 and arranged side-by-side in the front-rear direction.
- the flow volume of the fluidizing gas to be blown from the array of nozzles 31 can be changed.
- five gas boxes 32a, 32b, 32c, 32d, 32e are arranged side-by-side in the front-rear direction. Specifically, four gas boxes 32a, 32b, 32c, 32d are disposed on the side of the front wall 24 with respect to the non-combustible substance discharge port 29, and one gas box 32e is disposed on the side of the rear wall 25 with respect to the non-combustible substance discharge port 29.
- the gas feeding unit 33 is designed to feed (supply) the fluidizing gas to the respective gas boxes 32.
- the gas feeding unit 33 is capable of feeding the fluidizing gas to each of the gas boxes 32 in a different flow volume.
- the gas feeding unit 33 in this embodiment is configured to feed the fluidizing gas to two of the gas boxes 32 adjacent to each other in the front-rear direction, in such a manner that a flow volume of the fluidizing gas to be fed to a rear one of the adjacent gas boxes 32 becomes greater than a flow volume of the fluidizing gas to be fed to a front one of the adjacent gas boxes 32.
- the gas feeding unit 33 is adapted to feed only air to the respective gas boxes 32 to serve as the fluidizing gas. Alternatively, an inert gas such as nitrogen may be fed in combination with the air.
- the gas feeding unit 33 is operable to cause the fluidizing gas to be blown from around the non-combustible substance discharge port 29.
- the gas feeding unit 33 is operable to form a first fluidization region 15 where the fluidizable particles 12 are moved in a convection-like pattern and mixed with the introduced waste 18 to gasify the waste 18.
- the gas feeding unit 33 is operable to blow the fluidizing gas between the first fluidization region 15 and the front wall 24 at a flow velocity less than that of the fluidizing gas to be blown in the first fluidization region 15, to form a second fluidization region 16 having a degree of fluidization of the fluidizable particles 12 lower than that in the first fluidization region 15. More specifically, as mentioned above, the gas feeding unit 33 is configured such that a flow volume of the fluidizing gas to be fed to a rear one (e.g., the gas box 32c) of the gas boxes 32 adjacent to each other in the front-rear direction becomes greater than a flow volume of the fluidizing gas to be fed to a front one (e.g., the gas box 32b) of the adjacent gas boxes 32.
- a rear one e.g., the gas box 32c
- the gas feeding unit 33 is operable to, in the fluidized bed 14, form a first fluidization region 15 actively fluidized, around the non-combustible substance discharge port 29, while forming a second fluidization region 16 restrained in fluidization, between the first fluidization region 15 and the front wall 24.
- the gas feeding unit 33 may be configured such that a flow volume of the fluidizing gas to be fed to each of the gas boxes 32c, 32d, 32e on the side of the rear wall 25 becomes greater than a flow volume of the fluidizing gas to be fed to each of the gas boxes 32a, 32b on the side of the front wall 24.
- the gas feeding unit 33 is operable to, in the fluidized bed 14, form a second fluidization region 16 restrained in fluidization, in a region corresponding to the gas boxes 32a, 32b on the side of the front wall 24, while forming a first fluidization region 15 actively fluidized, in a region corresponding to the gas boxes 32c, 32d, 32e on the side of the rear wall 25.
- the gas feeding unit 33 is adapted to cause the fluidizing gas to be blown in the second fluidization region 16 at the flow velocity satisfying a condition that U o /U mf ranges from 1 to less than 2, and blown in the first fluidization region 15 at the flow velocity satisfying a condition that U o /U mf ranges from 2 to less than 5.
- U mf is a minimum fluidization velocity which is a minimum flow velocity of the fluidizing gas to be blown so as to fluidize the fluidizable particles 12.
- U o is a cross-sectional average flow velocity of the fluidizing gas.
- the gas feeding unit 33 is operable to feed a mixture formed by mixing an inert gas with air, as the fluidizing gas to be supplied to the respective gas boxes 32. Then, the gas feeding unit 33 is operable to gradually increase the inert gas in a ratio between air and the inert gas in the fluidizing gas. Consequently, the gas feeding unit 33 can suppress violent or rapid combustion of the waste 18 remaining in the furnace body 20, thereby restraining a rise in internal temperature of the furnace body 20.
- the oxygen concentration in the furnace body 20 reaches a value suitable for combustion of the waste 18 remaining in the furnace body 20, the waste 18 is violently or rapidly combusted, so that the internal temperature of the furnace body 20 becomes higher than that during the normal operation.
- the fluidizable particles 12 forming the fluidized bed 14 are agglomerated due to the heat. Once the fluidizable particles 12 are agglomerated, even if the fluidizing gas is subsequently blown into the agglomerated fluidizable particles 12 in order to form the fluidized bed 14, the agglomerated fluidizable particles 12 will never be fluidized.
- the gas feeding unit 33 is operable, when the introduction of waste 18 into the furnace body 20 is stopped, to mix an inert gas with air to be blown into the furnace body 20, and gradually increase the ratio of the inert gas. This allows the oxygen concentration in the furnace body 20 to be kept at a value less than that suitable for combustion of the waste 18. Consequently, it becomes possible to suppress violent or rapid combustion of the waste 18 remaining in the furnace body 20.
- the gas feeding unit 33 is adapted to be capable of adjusting a temperature of the fluidizing gas to be fed to the gas boxes 32.
- the gas feeding unit 33 is operable, upon start of the operation of the fluidized bed furnace 10, to blow the fluidizing gas in a high-temperature state from around the non-combustible substance discharge port 29 toward the fluidizable particles 12.
- the gas feeding unit 33 is operable to heat the fluidizable particles 12 until the fluidizable particles 12 reach a temperature capable of performing combustion and gasification of the waste 18.
- the gas feeding unit 33 may be configured to lower the temperature of the fluidizing gas to be fed to the gas boxes 32 just after start of the combustion.
- the waste supply section 40 is designed to supply waste 18 from the front wall 24 to a region on the fluidized bed 14 adjacent to the front wall 24.
- the waste supply section 40 in this embodiment is configured to push waste 18 generally horizontally from the front wall 24 (specifically, the waste introduction port 28 of the front wall 24) onto the fluidized bed 14, thereby causing the waste 18 to be moved toward the non-combustible substance discharge port 29.
- the waste supply section 40 is adapted to push waste 18 to cause the waste 18 to be accumulated on the second fluidization region 16 while causing the accumulated waste 18 to be moved into the first fluidization region 15 step-by-step.
- the waste supply section 40 comprises a pusher 41 and a drive unit (illustration is omitted) for driving the pusher 41.
- the pusher 41 has a pushing surface 42 extending in the width direction.
- the pushing surface 42 has a widthwise length equal to a width of the waste introduction port 28 of the front wall 24. Further, the pushing surface 42 has a vertical length which is approximately a half of a height dimension of an opening of the waste introduction port 28.
- the pusher 41 is installed to be movable in the front-rear direction, at the same height position as that of the waste introduction port 28.
- the drive unit comprises a driving power source such as a motor or a cylinder, and is adapted to reciprocatingly move the pusher 41 in the front-rear direction by the driving power. It is to be noted that the waste supply section 40 is not limited to a specific configuration.
- the waste supply section 40 in this embodiment is configured such that the pusher 41 is employed to push waste 18 into the furnace body.
- the waste supply section may be configured such that a screw extruder or the like is employed to push waste 18 into the furnace body. Based on employing the pusher 41 or the screw extruder, it becomes possible to supply trash which is likely to be scattered due to its small bulk specific gravity, such as paper or plastic sheet, into the furnace body 20 while keeping a massive form. This makes it possible to suppress scattering of trash inside the furnace body 20, as compared to a conventional furnace in which trash is input from an upper portion thereof.
- the sand circulation device 50 is designed to return the fluidizable particles 12 discharged from the non-combustible substance discharge port 29, to the fluidized bed 14 at a position on the side of the waste supply section 40 to circulate the fluidizable particles 12.
- the sand circulation device 50 operates to return the fluidizable particles 12 discharged from the non-combustible substance discharge port 29, to the fluidized bed 14 at a position on the side of the front wall 24, in the above manner, a flow of the fluidizable particles 12 directed from the front wall 24 to the non-combustible substance discharge port 29 is formed inside the fluidized bed 14.
- the second fluidization region 16 is maintained at a high temperature to some extent.
- the sand circulation device 50 comprises a non-combustible substance discharge section 51, a separation section 52, and a conveyance section 53.
- the non-combustible substance discharge section 51 is provided just below the non-combustible substance discharge port 29 of the bottom wall 21, and adapted to move a mixture of non-combustible substances and a part of the fluidizable particles 12 dropping from the non-combustible substance discharge port 29, to the separation section 52.
- the non-combustible substance discharge section 51 in this embodiment is configured to move the mixture dropping from the non-combustible substance discharge port 29, to the separation section 52 by using a screw extruder.
- the separation section 52 is adapted to separate the fluidizable particles 12 from the mixture sent from the non-combustible substance discharge section 51.
- the separation section 52 in this embodiment is configured to separate the fluidizable particles 12 from the mixture by using a sieve.
- the conveyance section 53 is adapted to convey the fluidizable particles 12 separated in the separation section 52, to the sand introduction section 27, and introduce the conveyed fluidizable particles 12 into the furnace body 20 via the sand introduction section 27.
- the sand circulation device 50 in this embodiment is configured to return the fluidizable particles 12 discharged from the non-combustible substance discharge port 29, to the fluidized bed 14 by inputting the fluidizable particles 12 from above the fluidized bed 14 toward an upper surface of the fluidized bed 14.
- the fluidizable particles 12 discharged from the non-combustible substance discharge port 29 may be directly returned to an inside of the fluidized bed 14.
- a sand introduction section (sand introduction opening) 27A is provided in the front wall 24 at an intermediate height position of the fluidized bed 14.
- a screw extruder 55 is provided at an end of the conveyance section 53 of the sand circulation device 50 on the side of the furnace body 20, and the furnace body-side end of the conveyance section 53 is inserted into the sand introduction section 27.
- the fluidizable particles 12 discharged from the non-combustible substance discharge port 29 may be returned to the fluidized bed 14 in such a manner as to be directly pushed into the fluidized bed 14.
- the sand introduction section 27 is not limited to the intermediate height position of the fluidized bed 14, but may be located on a relatively upper or lower side in a height direction of the fluidized bed 14.
- a combustible gas is collected from waste 18 in the following manner.
- the fluidizing gas Upon feeding the fluidizing gas from the gas feeding unit 33 to the respective gas boxes 32, the fluidizing gas is blown from the bottom wall 21 into the furnace body 20 toward the fluidizable particles 12, so that the fluidized bed 14 is formed inside the furnace body 20.
- the gas feeding unit 33 adjusts a flow volume of the fluidizing gas to be fed to each of the gas boxes 32. Through this adjustment, in the fluidized bed 14, the first fluidization region 15 actively fluidized is formed on the side of the non-combustible substance discharge port 29, and the second fluidization region 16 restrained in fluidization is formed between the first fluidization region 15 and the front wall 24.
- the gas feeding unit 33 feeds the fluidizing gas in a high-temperature state to a part (e.g., in this embodiment, the gas boxes 32c, 32d, 32e) of the gas boxes 32 corresponding to the first fluidization region 15 to positively heat the fluidizable particles 12 in the first fluidization region 15.
- the sand circulation device 50 circulates the fluidizable particles 12 to form a flow of the fluidizable particles 12 in the fluidized bed.
- the non-combustible substance discharge section 51 sends the fluidizable particles 12 dropping from the non-combustible substance discharge port 29 of the furnace body 20, to the separation section 52.
- the conveyance section 53 conveys the fluidizable particles 12 passing through the separation section 52, to the sand introduction section 27 of the furnace body 20.
- the conveyed fluidizable particles 12 are returned to the fluidized bed 14 at a position on the side of the front wall 24, via the sand introduction section 27.
- the second fluidization region 16 has a temperature less than that of the first fluidization region 15.
- the temperature of the first fluidization region 15 is kept in the range of 600 to 800°C, whereas the temperature of the second fluidization region 16 is kept in the range of about 400 to 600°C.
- the waste supply section 40 starts to push waste 18 into the furnace body 20 via the waste introduction port 28.
- the pusher 41 driven by the drive unit pushes waste 18 generally horizontally toward the rear wall 25.
- the waste 18 is pushed onto the second fluidization region 16 at a position adjacent to the front wall 24 (see FIG. 2 ).
- the fluidization of the fluidizable particles 12 in the second fluidization region 16 is restrained.
- the pushed waste 18 is not positively mixed with the fluidizable particles 12, so that most of the waste 18 is accumulated on the second fluidization region 16, and heavy non-combustible substances therein sink down. Consequently, in the second fluidization region 16, rapid combustion of the waste 18 is suppressed, and easily-gasifiable substances in the waste are gasified by heat radiation within the furnace body 20.
- easily gasifiable waste 18 such as plastic or paper is gasified while being moved in a surface layer of the second fluidization region 16.
- not-easily gasifiable waste such as a wood piece is partially gasified, but a large part thereof reaches the first fluidization region 15 without being gasified.
- the easily gasifiable waste 18 is gasified under a mild condition in the second fluidization region 16 before it reaches the highly fluidized bed (first fluidization region 15).
- the accumulated waste 18 is combusted by radiation heat within the furnace body 20, as mentioned above.
- the radiation heat has a temperature of 800 to 900°C which is greater than that of the fluidizable particles 12 forming the fluidized bed 14, a contact between the waste 18 and air is not satisfactory.
- the second fluidization region 16 has a relatively low temperature, and an amount of air (fluidizing gas) to be supplied to the second fluidization region 16 is relatively small, so that even the easily combustible trash will be gradually gasified.
- the fluidizable particles 12 are gradually discharged through the non-combustible substance discharge port 29, so that, according to the discharge of the fluidizable particles 12 and the fluidization of the fluidizable particles 12 by the fluidizing gas, a part of the accumulated waste 18 is moved or spread step-by-step in a left-to-right direction in FIG. 1 .
- waste 18 is input in a massive form, and easily combustible papers are comprised therein, it can be expected to promote gasification of the papers based on a phenomenon that the papers are moved toward a surface of the massive waste during the spreading.
- rapid combustion of the waste 18 is suppressed to prevent a rapid increase of combustible gas during introduction of waste 18.
- the first fluidization region 15 is actively fluidized and heated up to a high temperature by combustion of the waste 18, so that the waste 18 moved from a position on the second fluidization region 16 is mixed with the fluidizable particles 12 and sufficiently gasified. Consequently, a combustible gas is generated. More specifically, in the fluidized bed 14, a fluidized state gradually becomes more active in a direction from the front wall 24 to the non-combustible substance discharge port 29.
- the waste 18 newly pushed onto the second fluidization region 16 by the pusher 41 is accumulated on the second fluidization region 16 almost without being mixed with the fluidizable particles 12 as mentioned above. Then, the accumulated waste 18 is gradually combusted under the condition that violent or rapid combustion is suppressed.
- waste 18 is pushed in one after another by the pusher 41, which makes it possible to suppress intermittent and rapid generation of a combustible gas, thereby stabilizing the gas generation.
- the pushing of waste 18 into the furnace body 20 by the pusher 41 is firstly stopped.
- the gas feeding unit 33 feeds a mixture formed by mixing an inert gas with air, as the fluidizing gas to be supplied to the respective gas boxes 32.
- the gas feeding unit 33 operates to gradually increase the inert gas in a ratio between air and the inert gas in the fluidizing gas, with time. In this manner, the gas feeding unit 33 restrains an oxygen concentration within the furnace body 20 to suppress violent or rapid combustion of the waste 18 remaining in the fluidized bed 14.
- the fluidized bed furnace 10 is capable of suppressing intermittent and rapid generation of a combustible gas to stabilize the gas generation, even in a situation where a large amount of easily combustible trash is comprised in waste.
- the first fluidization region 15 around the non-combustible substance discharge port 29 and the second fluidization region 16 having a fluidization degree lower than that in the first fluidization region 15 are formed.
- new waste 18 is pushed onto the second fluidization region 16.
- the input of the new waste 18 causes the waste 18 accumulated on the second fluidization region 16 to be moved toward the first fluidization region 15 step-by-step. The above operation will be repeated.
- the fluidized bed furnace 10 can sufficiently gasify the waste 18, while suppressing rapid fluctuation of generation of a combustible gas. Consequently, it becomes possible to stably generate a combustible gas from the waste 18.
- the waste 18 is not exposed to the highly fluidized bed (the first fluidization region 15), so that it becomes possible to suppress a situation where a large amount of lightweight trash flies up inside the furnace body 20 and undergoes rapid combustion in a free board section.
- the upper surface 21a of the bottom wall 21 is inclined to become lower toward the non-combustible substance discharge port 29.
- the non-combustible substances in the waste 18 sinks down to the bottom wall 21 in the fluidized bed 14, they fall on the upper surface 21a of the bottom wall 21 toward the non-combustible substance discharge port 29.
- the non-combustible substances are discharged from the non-combustible substance discharge port 29 together with a part of the fluidizable particles 12, so that it becomes possible to easily discharge non-combustible substances from the furnace body 20.
- the non-combustible substances discharged from the non-combustible substance discharge port 29 together with a part of the fluidizable particles 12 are separated from the fluidizable particles 12 in the separation section 52 of the sand circulation device 50.
- the furnace body 20 has a shape in plan view, in which a dimension in the width direction thereof is equalized in a pushing direction of waste 18.
- the pusher 41 is adapted to be reciprocatingly moved in a direction parallel to the pushing direction (front-rear direction) to allow the pushing surface 42 to push waste 18 onto the fluidized bed 14 simultaneously by the entire widthwise region of the pushing surface 42. This allows the pushing surface 42 to push waste 18 onto the fluidized bed 14 with an even force in the width direction.
- the movement of the waste 18 from the second fluidization region 16 to the first fluidization region 15 is approximately equalized in the width direction, so that it becomes possible to prevent the waste 18 from concentrating on a certain portion inside the furnace.
- the sidewall 22 stands upwardly and straight from the bottom wall 21 to the combustible gas outlet portion 23.
- the sidewall may comprise a front wall 24A having a reflecting portion 224 extending toward the rear wall 25 to cover an upper side of the second fluidization region 16 at a predetermined height position.
- the front wall 24A allows the waste 18 accumulated on the second fluidization region 16 to be heated by radiation heat from the reflecting portion 224. Consequently, it becomes possible to generate a combustible gas from the waste 18 accumulated on the second fluidization region 16. In other words, gasification of the waste 18 accumulated on the second fluidization region 16 is promoted.
- the sidewall may comprise a rear wall 25A having a guide portion 225 extending toward the front wall 24 to cover an upper side of the first fluidization region 15 at a predetermined height position.
- the guide portion 225 is adapted to guide a high-temperature combustible gas generated from the waste 18 in the first fluidization region 15 to allow the combustible gas to be brought into contact with the waste 18 accumulated on the second fluidization region 16.
- the guide portion 225 allows the combustible gas to contribute to heating of the waste 18 accumulated on the second fluidization region 16. Consequently, it becomes possible to promote gasification of the waste 18 accumulated on the second fluidization region 16 without adding special heating means to the furnace body 20.
- the sidewall may comprise a front wall 24B and a rear wall 25B having, respectively, two roof portions 324, 325 extending in a direction causing them to come closer to each other at the same height position.
- the front wall 24B and the rear wall 25B allow the waste 18 accumulated on the second fluidization region 16 to be heated by radiation heat from the roof portion 324 of the front wall 24B, so as to promote gasification thereof.
- a dimension of a furnace body 20B in the front-rear direction is reduced at a position lower than the combustible gas outlet portion 23 at the upper end of the furnace body 20B, so that it becomes possible to facilitate a reduction in size of the furnace body 20B.
- the upper surface 21a of the bottom wall 21 has an inclination angle which is constant in the range from the front wall 24 to the non-combustible substance discharge port 29, the present invention is not limited thereto.
- an inclination angle ⁇ of an upper surface 21d of a bottom wall 21A on the side of the second fluidization region 16 with respect to a horizontal surface may be greater than an inclination angle ⁇ of an upper surface 21e of the bottom wall 21A on the side of the first fluidization region 15 with respect to the horizontal surface.
- the inclination angle ⁇ of the upper surface 21e on the side of the first fluidization region 15 with respect to the horizontal surface is in the range of 15 degrees to 25 degrees
- the inclination angle ⁇ of the upper surface 21d on the side of the second fluidization region 16 with respect to the horizontal surface is in the range of 20 degrees to 75 degrees, preferably, in the range of 20 degrees to 30 degrees.
- the upper surface 21a of the bottom wall 21 may be curved from the front wall 24 to the non-combustible substance discharge port 29, instead of being inclined straight.
- thermometers T are disposed just above the second fluidization region 16, and an air supply section 60 capable of supplying air onto the second fluidization region 16 is provided.
- an accumulated amount of the waste 18 accumulated on the second fluidization region 16 can be estimated, so that it becomes possible to control the accumulated amount.
- the accumulated amount of the waste 18 on the second fluidization region 16 is estimated by utilizing a phenomenon that an indication value of the thermometer T embedded in the waste 18 is lowered.
- the air supply section 60 is operable to supply air to increase an internal temperature of the furnace body 20. Accordingly, gasification of the waste 18 accumulated on the second fluidization region 16 is prompted, so that the accumulated amount of the waste 18 is reduced.
- an amount of the air may be controlled based on determinations made as follows: when a temperature of a designated one of the thermometers T is equal to or greater than a threshold value, it is determined that there is no waste at a position of the designated thermometer T, and, when the temperature is less than the threshold value, it is determined that there is waste at the position of the designated thermometer T (the designated thermometer T is embedded in waste).
- the gas feeding unit 33 is configured to feed air and/or an inert gas as the fluidizing gas.
- the gas feeding unit 33 may be configured to feed water vapor and/or oxygen as the fluidizing gas, depending on a combustion state within the furnace body 20.
- the fluidized bed furnace 10 may further comprise a second gas supply section provided in the sidewall 22 in addition to the first gas supply section 30, wherein the second gas supply section may be configured to be capable of supplying air, oxygen, water vapor or the like into the furnace body 20, depending on a combustion state in the fluidized bed 14 or of the waste 18.
- the fluidizing gas to be supplied to the second fluidization region 16 may be a high-temperature fluidizing gas.
- the temperature of the second fluidization region 16 can be maintained at a high value without increasing an amount of the fluidizing gas to be supplied.
- the waste introduction port 28 is provided at a height position partially overlapping with respect to the waste 18 accumulated on the fluidized bed 14 in the up-down direction, so that waste 18 supplied from the waste introduction port 28 positively moves the waste 18 accumulated on the upper surface of the fluidized bed 14, generally horizontally (toward the first fluidization region 15).
- the fluidized bed furnace 10 may have any configuration capable of supplying waste 18 to a region on the fluidized bed 14 adjacent to the front wall (supply-side sidewall portion) 24. For example, as illustrated in FIG. 10A and FIG.
- the waste introduction port 28 may be provided at a height position which is located adjacent to the upper surface of the fluidized bed 14, and free of contact with waste 18 when it is newly supplied onto the waste 18 accumulated (on the second fluidization region 16) in a region of the upper surface of the fluidized bed 14 adjacent to the front wall 24.
- the waste introduction port 28 may be provided to allow new waste to be supplied generally horizontally from a height position above the waste 18 accumulated on the fluidized bed 14.
- the waste introduction port 28 may be provided to allow new waste to be supplied downwardly from a height position above the waste 18 accumulated on the fluidized bed 14.
- the fluidizing gas to be supplied to the fluidized bed 14 is supplied in the second fluidization region 16 at a flow velocity satisfying the condition that U o /U mf ranges from 1 to less than 2, and supplied in the first fluidization region 15 at a flow velocity satisfying a condition that U o /U mf ranges from 2 to less than 5, as mentioned above.
- the fluidizing gas may also be supplied in the second fluidization region 16 at a flow velocity satisfying the condition that U o /U mf ranges from 2 to less than 5, only for a certain period of time in order to discharge the accumulated non-combustible substances to the outside.
- an amount of the fluidizing gas to be supplied to each of the gas boxes 32 is increased step-by-step in a direction from the front wall 24 (left side in FIG. 1 ) to the rear wall 25 (right side in FIG.
- a flow volume of the fluidizing gas to be supplied to the gas box 32a becomes greater than that of the fluidizing gas to be supplied to each of the remaining gas boxes.
- the flow volume of the fluidizing gas to be supplied to the gas box 32a is returned to a value during a normal operation, and a flow volume of the fluidizing gas to be supplied to the adjacent gas box 32b becomes greater than that of the fluidizing gas to be supplied to each of the remaining gas boxes.
- the flow volume of the fluidizing gas to be supplied to the gas box 32b is returned to an original value, and a flow volume of the fluidizing gas to be supplied to the adjacent gas box 32c becomes greater than that of the fluidizing gas to be supplied to each of the remaining gas boxes.
- the fluidized bed furnace according to the above embodiment is designed to heat waste to extract a combustible gas from the waste.
- the fluidized bed furnace comprises the features of claim 1.
- the first fluidization region around the non-combustible substance discharge port and the second fluidization region having a fluidization degree lower than that in the first fluidization region are formed in the fluidized bed.
- the waste supply section supplies waste to a region on the fluidized bed adjacent to the supply-side sidewall portion to cause the waste to be accumulated on the second fluidization region while causing the waste accumulated on the second fluidization region to be moved into the first fluidization region step-by-step.
- gasification of the waste is sufficiently performed while suppressing rapid fluctuation of generation of a combustible gas to be collected from the fluidized bed furnace, so that it becomes possible to stably generate a combustible gas from the waste.
- fluidization in the second fluidization region is restrained, so that the waste is accumulated on the second fluidization region without being mixed with the fluidizable particles, and easily combustible components of the waste are slowly gasified. Therefore, in the second fluidization region, rapid combustion of the waste is suppressed, and generation of a combustible gas caused by rapid gasification of the waste is minimized.
- the waste accumulated on the second fluidization region is moved into the first fluidization region step-by-step.
- the fluidizable particles are actively fluidized and heated to a high temperature by combustion of the waste, so that the waste moved from a position on the second fluidization region is sufficiently mixed with the fluidizable particles, and thereby the waste is sufficiently gasified to generate a combustible gas. Consequently, it becomes possible to suppress intermittent and rapid generation of a combustible gas, thereby stabilizing the gas generation.
- a temperature of the second fluidization region is maintained by the sand circulation device which returns the high-temperature fluidizable particles discharged from the non-combustible substance discharge port, to the second fluidization region of the fluidized bed.
- the upper surface of the bottom wall is inclined to become lower toward the non-combustible substance discharge port, so that, when non-combustible substances in the waste sinks down to the bottom wall in the fluidized bed, they fall on the upper surface of the bottom wall toward the non-combustible substance discharge port.
- the non-combustible substances are discharged from the non-combustible substance discharge port together with a part of the fluidizable particles, so that it becomes possible to easily discharge non-combustible substances from the furnace body.
- the waste supply section is adapted to push new waste generally horizontally from the supply-side sidewall portion toward the waste accumulated on the second fluidization region, thereby causing the waste accumulated on the second fluidization region to be moved into the first fluidization region step-by-step.
- new waste is pushed generally horizontally toward the waste accumulated on the second fluidization region.
- the waste accumulated on the second fluidization region is pushed by the new waste and reliably moved into the first fluidization region.
- the gas supply section is adapted to blow the fluidizing gas in the second fluidization region at a flow velocity satisfying a condition that U o /U mf ranges from 1 to less than 2, and blow the fluidizing gas in the first fluidization region at a flow velocity satisfying a condition that U o /U mf ranges from 2 to less than 5, where U mf is a minimum fluidization velocity which is a minimum flow velocity of the fluidizing gas to be blown so as to fluidize the fluidizable particles, and U o is a cross-sectional average flow velocity of the fluidizing gas.
- the first fluidization region and the second fluidization region can be desirably formed by blowing the fluidizing gas at the above flow velocities. Consequently, it becomes possible to desirably gasify the waste while suppressing rapid combustion of the waste, thereby stably obtaining a combustible gas from the waste.
- the furnace body has a shape in plan view, in which a dimension in a width direction perpendicular to a pushing direction along which waste is pushed by the waste supply section is equalized in the pushing direction.
- the movement of the waste is stabilized, because the dimension of the furnace body in a direction perpendicular to the waste pushing direction (width direction) is equalized.
- the flow of the fluidizable particles formed in a direction from the second fluidization region to the first fluidization region by the sand circulation device is directionally the same as the movement of the waste, so that the flow of the fluidizable particles is also stabilized.
- the waste supply section comprises a pusher having a pushing surface extending in the width direction, and a drive unit for reciprocatingly moving the pusher in a direction parallel to the pushing direction to allow the pushing surface of the pusher to push waste onto the fluidized bed simultaneously by the entire widthwise region of the pushing surface.
- waste is pushed onto the fluidized bed with an even force in the width direction, so that the movement of the waste from the second fluidization region to the first fluidization region is approximately equalized in the width direction.
- the waste treatment method according to the above embodiment is designed to heat waste to extract a combustible gas from the waste.
- the method comprises the steps described in claim 6.
- the first fluidization region around the non-combustible substance discharge port and the second fluidization region having a fluidization degree lower than that in the first fluidization region are formed in the fluidized bed. Then, the waste is accumulated on the second fluidization region, and the waste accumulated on the second fluidization region is moved into the first fluidization region step-by-step.
- gasification of the waste is sufficiently performed while suppressing rapid fluctuation of generation of a combustible gas to be collected from the fluidized bed furnace, so that it becomes possible to stably generate a combustible gas from the waste.
- the upper surface of the bottom wall is inclined to become lower toward the non-combustible substance discharge port, so that non-combustible substances in the waste fall on the upper surface of the bottom wall toward the non-combustible substance discharge port.
- the non-combustible substances are discharged from the non-combustible substance discharge port together with a part of the fluidizable particles, so that it becomes possible to easily discharge non-combustible substances from the furnace body.
- the gasification step includes pushing new waste generally horizontally from the supply-side sidewall portion toward the waste accumulated on the second fluidization region, thereby causing the waste accumulated on the second fluidization region to be moved into the first fluidization region step-by-step and gasified.
- new waste is pushed generally horizontally toward the waste accumulated on the second fluidization region.
- the waste accumulated on the second fluidization region is pushed by the new waste and reliably moved into the first fluidization region, and gasified.
- the fluidizing gas is blown in the second fluidization region at a flow velocity satisfying a condition that U o /U mf ranges from 1 to less than 2, and blown in the first fluidization region at a flow velocity satisfying a condition that U o /U mf ranges from 2 to less than 5, where U mf is a minimum fluidization velocity which is a minimum flow velocity of the fluidizing gas to be blown so as to fluidize the fluidizable particles, and U o is a cross-sectional average flow velocity of the fluidizing gas.
- the first fluidization region and the second fluidization region can be desirably formed by blowing the fluidizing gas at the above flow velocities. Consequently, it becomes possible to desirably gasify the waste while suppressing rapid combustion of the waste, thereby stably obtaining a combustible gas from the waste.
- the fluidized bed furnace and the waste treatment method of the present invention are useful in heating waste in a fluidized bed formed by fluidizing fluidizable particles, to extract a combustible gas from the waste, and suitable for stably obtaining a combustible gas even from waste comprising easily combustible trash.
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Chemical & Material Sciences (AREA)
- Combustion & Propulsion (AREA)
- Fluidized-Bed Combustion And Resonant Combustion (AREA)
- Gasification And Melting Of Waste (AREA)
Description
- The present invention relates to a fluidized bed furnace designed to heat waste in a fluidized bed formed by fluidizing fluidizable particles to thereby extract a combustible gas from the waste, and a waste treatment method.
- Heretofore, as a fluidized bed furnace, there has been known one type described in the following Patent Document 1. As illustrated in
FIG. 11 , this fluidized bed furnace comprises afurnace body 104 having fluidizable sand (fluidizable particles) 102 in a furnace bottom section, and anair supply section 106 for supplying air into thefluidizable sand 102 in the furnace bottom section so as to fluidize thefluidizable sand 102 to form a fluidized bed. Thefurnace body 104 has a sidewall. The sidewall is provided with aninput section 108 for inputting waste onto the fluidized bed therefrom. - In this fluidized
bed furnace 100, theair supply section 106 is adapted to supply air into high-temperaturefluidizable sand 102. Consequently, thefluidizable sand 102 is fluidized in a levitated or suspended state to form a fluidized bed. In this process, theair supply section 106 is adapted to supply air in such a manner that a fluidized state of thefluidizable sand 102 becomes approximately equalized in the entire region of the fluidized bed so as to allow waste input from theinput section 108 onto the fluidized bed to be entrapped inside the fluidized bed and efficiently combusted. - Every time waste is input from the
input section 108 onto the high-temperaturefluidizable sand 102, the input waste is mixed with the high-temperaturefluidizable sand 102 of the fluidized bed, and thermally decomposed (gasified). Consequently, a combustible gas is generated. For example, this combustible gas will be combusted at high temperatures in a melting furnace in a subsequent stage. - Waste input into the fluidized
bed furnace 100 is entrapped in the active fluidized bed and combusted or gasified. In this process, every time waste is intermittently input, combustible substances in the waste are rapidly combusted, so that a rapid fluctuation in amount, concentration, etc., of a generated combustible gas will repeatedly occur. A change in the gasification reaction is largely dependent on a quantitative characteristic in supply of waste. Thus, in the case where there is a fluctuation in supply of waste or a qualitative change in components of waste, it is impossible to stably generate a combustible gas. Particularly, when a large amount of easily combustible trash such as paper or sheet-shaped plastic is comprised in waste, a fluctuation of generation of a combustible gas becomes larger, and therefore there is a need for stabilizing the gas generation. - For example, in the case where generated combustible gas is used for a gas engine to generate electric power, if a combustible gas is generated with large fluctuations, it is impossible to obtain stable energy. Therefore, there is a need for further stabilizing a combustible gas to be obtained in a fluidized bed furnace.
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- Patent Document 1:
JP 2006-242454A - Patent Document 2:
JPH109511A - It is an object of the present invention to provide a fluidized bed furnace according to claim 1, capable of stably obtaining a combustible gas even from waste comprising easily combustible trash, and a waste treatment method according to claim 6.
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FIG. 1 is a schematic configuration diagram of a fluidized bed furnace where the thermometers and the air supply according to the present invention are not represented. -
FIG. 2 is a horizontal sectional view of a furnace body, for explaining an introduction position of waste and an introduction position of fluidizable particles in the fluidized bed furnace. -
FIG. 3 is a diagram for explaining a nozzle arrangement in a bottom wall of the furnace body. -
FIG. 4 is a diagram for explaining a configuration for pushing fluidizable particles directly onto a fluidized bed in the furnace body, where the thermometers and the air supply section according to the invention have not been represented. -
FIG. 5 is a diagram for explaining a furnace body having a reflecting portion in a front wall thereof, in a fluidized bed furnace where the thermometers and the air supply section according to the invention have not been represented. -
FIG. 6 is a diagram for explaining a furnace body having a guide portion in a rear wall thereof, in a fluidized bed furnace where the thermometers and the air supply section according to the invention have not been represented. -
FIG. 7 is a diagram for explaining a furnace body having a roof portion in each of front and rear walls thereof, in a fluidized bed furnace where the thermometers and the air supply according to the invention have not been represented. -
FIG. 8 is a diagram for explaining a furnace body having a bent bottom wall thereof, in a fluidized bed furnace where the thermometers and the air supply section according to the invention have not been represented. -
FIG. 9 is a diagram for explaining a furnace body comprising a thermometer and an air supply section, in a fluidized bed furnace according to the present invention. -
FIG. 10 is a diagram for explaining a waste supply section, in a fluidized bed furnace where the thermometers and the air supply section according to the invention are not represented. -
FIG. 11 is a schematic configuration diagram of a conventional fluidized bed furnace. - A fluidized bed furnace according to this embodiment is designed to heat waste by high-temperature fluidizable particles, to extract a combustible gas from the waste. As illustrated in
FIG. 1 , the fluidized bed furnace comprisesfluidizable particles 12, afurnace body 20, agas supply section 30, awaste supply section 40 and asand circulation device 50. - The
fluidizable particles 12 are particles make up a fluidizedbed 14 to heatwaste 18, inside thefurnace body 20. More specifically, thefluidizable particles 12 are mixed withwaste 18 while being heated up to a high temperature by combustion of a part of waste components, so that thewaste 18 is gasified to generate a combustible gas. For example, thefluidizable particles 12 may be silica sand. - The
furnace body 20 is configured to internally have thefluidizable particles 12 and extract a combustible gas fromwaste 18 by means of thefluidizable particles 12 in a high temperature state. Thefurnace body 20 has abottom wall 21 supporting thefluidizable particles 12 from therebelow, asidewall 22 standing upwardly from thebottom wall 21, and a combustiblegas outlet portion 23 provided at an upper end of thesidewall 22. - The
sidewall 22 has a rectangular tubular shape extending in an up-down (vertical) direction. Specifically, as also illustrated inFIG. 2 , thesidewall 22 has a front wall (supply-side sidewall portion) 24 and arear wall 25 which are disposed in opposed and spaced-apart relation to each other in a front-rear direction (inFIG. 2 , in a right-left direction), and a pair oflateral walls front wall 24 and therear wall 25. Thelateral walls furnace body 20 has a shape in plan view, in which a dimension in a width direction (widthwise dimension) as a distance between thelateral walls - A portion (front wall) 24 of the
sidewall 22 located on a side opposite to an aftermentioned non-combustiblesubstance discharge port 29 across a center position of thebottom wall 21 has asand introduction section 27 and awaste introduction port 28. Thesand introduction section 27 is adapted to introducefluidizable particles 12 into thefurnace body 20, and thewaste introduction port 28 is adapted to introducewaste 18 into thefurnace body 20. - Specifically, the
sand introduction section 27 is provided at each of widthwise opposite ends of a lower portion of thefront wall 24 to allow fluidizable particles to be introduced to widthwise opposite end areas of an inside of the furnace body 20 (seeFIG. 2 ). Thesand introduction section 27 is provided at a height position wherefluidizable particles 12 can be input from above thefluidizable particles 12 supported by the bottom wall 21 (fluidized bed 14), toward the fluidizedbed 14. It is to be noted that an input area offluidizable particles 12 is not limited to the widthwise opposite end areas. For example, the input area offluidizable particles 12 may be one of the widthwise opposite end areas. Alternatively, the input area offluidizable particles 12 may be an upper surface of the introduced waste 18 (a central area adjacent to thefront wall 24 inFIG. 2 ). In the case wherefluidizable particles 12 are input ontowaste 18, thefluidizable particles 12 serve as an ignition source to allow only easily combustible trash to be stably combusted (gasified) initially. - The
waste introduction port 28 is provided in approximately the entire region of the lower portion of thefront wall 24 in the width direction. Thewaste introduction port 28 is provided at a height position wherewaste 18 can be pushed generally horizontally onto an upper surface of the fluidizedbed 14 made up of thefluidizable particles 12 supported by thebottom end 21. In other words, thewaste introduction port 28 is provided in such a manner that a lower end thereof is located at a position slightly higher than the upper surface of the fluidizedbed 14. - The combustible
gas outlet portion 23 is designed to discharge a combustible gas generated inside thefurnace body 20. The combustiblegas outlet portion 23 has an outer diameter squeezed more than thesidewall 22, so that a duct or the like for supplying the combustible gas obtained in thefurnace body 20 to a subsequent stage, for example, a gas engine for electric power generation processes, can be connected thereto. - The
bottom wall 21 has a non-combustiblesubstance discharge port 29 provided at a position offset from the center position thereof in a specific direction to discharge non-combustible substances inwaste 18 together with a part of thefluidizable particles 12. The non-combustiblesubstance discharge port 29 has an opening extending over the widthwise entire region of thebottom wall 21. Thebottom wall 21 has anupper surface 21a is inclined to become lower toward the non-combustiblesubstance discharge port 29 so as to cause the non-combustible substances to fall on theupper surface 21a. Thebottom wall 21 in this embodiment has a non-combustiblesubstance discharge port 29 at a position offset rearwardly, and anupper surface 21a of thebottom wall 21 extends rearwardly (inFIG. 1 , in a left-to-right direction) at a constant downward inclination. Specifically, theupper surface 21a of thebottom wall 21 has an inclination angle of 15 degrees to 25 degrees with respect to a horizontal plane. - The
gas supply section 30 is designed to blow a fluidizing gas from thebottom wall 21 toward thefluidizable particles 12 to fluidize thefluidizable particles 12. Thegas supply section 30 comprises a plurality ofnozzles 31 for blowing the fluidizing gas, agas box 32 for supplying the fluidizing gas to thenozzles 31, and agas feeding unit 33 for feeding the fluidizing gas to thegas box 32. - The plurality of
nozzles 31 are installed to thebottom wall 21 in spaced-apart relation to each other in the width direction and the front-rear direction, i.e., in a lattice arrangement. Each of thenozzles 31 is attached to thebottom wall 21 to penetrate through thebottom wall 21. In this embodiment, as also illustrated inFIG. 3 , thebottom wall 21 is divided into afront region 21b and arear region 21c. Then, the plurality ofnozzles 31 are installed to the front andrear regions nozzles 31 provided in thefront region 21b becomes greater than the number ofnozzles 31 provided in therear region 21c. It is to be noted that a relationship between the respective numbers ofnozzles 31 in the front andrear regions nozzles 31 in thefront region 21b may be equal to the number ofnozzles 31 in therear region 21c. Alternatively, the number ofnozzles 31 in therear region 21c may be greater than the number ofnozzles 31 in thefront region 21b. - The
gas box 32 has a box shape extending in the width direction. Thegas box 32 serves as a header for distributing the fluidizing gas to an array of thenozzles 31 arranged side-by-side in the width direction in thebottom wall 21. Thegas box 32 has a function of equalizing respective flow volumes of the fluidizing gas to be blown from the array ofnozzles 31 arranged in the width direction. In this embodiment, a plurality of thegas boxes 32 are provided on the side of a lower surface of thebottom wall 21 and arranged side-by-side in the front-rear direction. Thus, with respect to each of a plurality of the arrays ofnozzles 31 corresponding to respective ones of thegas boxes 32, the flow volume of the fluidizing gas to be blown from the array ofnozzles 31 can be changed. In this embodiment, fivegas boxes gas boxes front wall 24 with respect to the non-combustiblesubstance discharge port 29, and onegas box 32e is disposed on the side of therear wall 25 with respect to the non-combustiblesubstance discharge port 29. - The
gas feeding unit 33 is designed to feed (supply) the fluidizing gas to therespective gas boxes 32. Thegas feeding unit 33 is capable of feeding the fluidizing gas to each of thegas boxes 32 in a different flow volume. Thegas feeding unit 33 in this embodiment is configured to feed the fluidizing gas to two of thegas boxes 32 adjacent to each other in the front-rear direction, in such a manner that a flow volume of the fluidizing gas to be fed to a rear one of theadjacent gas boxes 32 becomes greater than a flow volume of the fluidizing gas to be fed to a front one of theadjacent gas boxes 32. Thegas feeding unit 33 is adapted to feed only air to therespective gas boxes 32 to serve as the fluidizing gas. Alternatively, an inert gas such as nitrogen may be fed in combination with the air. - Specifically, during a normal operation of the
fluidized bed furnace 10, i.e., whenwaste 18 is introduced into thefurnace body 20 to generate a combustible gas from the introducedwaste 18, thegas feeding unit 33 is operable to cause the fluidizing gas to be blown from around the non-combustiblesubstance discharge port 29. In this process, thegas feeding unit 33 is operable to form afirst fluidization region 15 where thefluidizable particles 12 are moved in a convection-like pattern and mixed with the introducedwaste 18 to gasify thewaste 18. Concurrently, thegas feeding unit 33 is operable to blow the fluidizing gas between thefirst fluidization region 15 and thefront wall 24 at a flow velocity less than that of the fluidizing gas to be blown in thefirst fluidization region 15, to form asecond fluidization region 16 having a degree of fluidization of thefluidizable particles 12 lower than that in thefirst fluidization region 15. More specifically, as mentioned above, thegas feeding unit 33 is configured such that a flow volume of the fluidizing gas to be fed to a rear one (e.g., thegas box 32c) of thegas boxes 32 adjacent to each other in the front-rear direction becomes greater than a flow volume of the fluidizing gas to be fed to a front one (e.g., thegas box 32b) of theadjacent gas boxes 32. In this case, thegas feeding unit 33 is operable to, in thefluidized bed 14, form afirst fluidization region 15 actively fluidized, around the non-combustiblesubstance discharge port 29, while forming asecond fluidization region 16 restrained in fluidization, between thefirst fluidization region 15 and thefront wall 24. Alternatively, thegas feeding unit 33 may be configured such that a flow volume of the fluidizing gas to be fed to each of thegas boxes rear wall 25 becomes greater than a flow volume of the fluidizing gas to be fed to each of thegas boxes front wall 24. In this case, thegas feeding unit 33 is operable to, in thefluidized bed 14, form asecond fluidization region 16 restrained in fluidization, in a region corresponding to thegas boxes front wall 24, while forming afirst fluidization region 15 actively fluidized, in a region corresponding to thegas boxes rear wall 25. - Specifically, the
gas feeding unit 33 is adapted to cause the fluidizing gas to be blown in thesecond fluidization region 16 at the flow velocity satisfying a condition that Uo/Umf ranges from 1 to less than 2, and blown in thefirst fluidization region 15 at the flow velocity satisfying a condition that Uo/Umf ranges from 2 to less than 5. In this formula, Umf is a minimum fluidization velocity which is a minimum flow velocity of the fluidizing gas to be blown so as to fluidize thefluidizable particles 12. Further, Uo is a cross-sectional average flow velocity of the fluidizing gas. - On the other hand, during stop of the
fluidized bed furnace 10, i.e., when the introduction ofwaste 18 into thefurnace body 20 is stopped, thegas feeding unit 33 is operable to feed a mixture formed by mixing an inert gas with air, as the fluidizing gas to be supplied to therespective gas boxes 32. Then, thegas feeding unit 33 is operable to gradually increase the inert gas in a ratio between air and the inert gas in the fluidizing gas. Consequently, thegas feeding unit 33 can suppress violent or rapid combustion of thewaste 18 remaining in thefurnace body 20, thereby restraining a rise in internal temperature of thefurnace body 20. - More specifically, during the normal operation, in the
furnace body 20, combustion, gasification, etc., of thewaste 18 are performed under a condition that an oxygen concentration is set to a value less than that suitable for combustion of thewaste 18. In this state, when the introduction ofwaste 18 into thefurnace body 20 is stopped, an amount of combustible substances in thefurnace body 20 will be reduced. In this process, the fluidizing gas (air) is continuously supplied into thefurnace body 20 in a predetermined flow volume to maintain thefluidized bed 14, so that the oxygen concentration in thefurnace body 20 will be increased. When the oxygen concentration in thefurnace body 20 reaches a value suitable for combustion of thewaste 18 remaining in thefurnace body 20, thewaste 18 is violently or rapidly combusted, so that the internal temperature of thefurnace body 20 becomes higher than that during the normal operation. In such a high-temperature state of the inside of thefurnace body 20, thefluidizable particles 12 forming thefluidized bed 14 are agglomerated due to the heat. Once thefluidizable particles 12 are agglomerated, even if the fluidizing gas is subsequently blown into the agglomeratedfluidizable particles 12 in order to form thefluidized bed 14, the agglomeratedfluidizable particles 12 will never be fluidized. Therefore, thegas feeding unit 33 is operable, when the introduction ofwaste 18 into thefurnace body 20 is stopped, to mix an inert gas with air to be blown into thefurnace body 20, and gradually increase the ratio of the inert gas. This allows the oxygen concentration in thefurnace body 20 to be kept at a value less than that suitable for combustion of thewaste 18. Consequently, it becomes possible to suppress violent or rapid combustion of thewaste 18 remaining in thefurnace body 20. - Further, the
gas feeding unit 33 is adapted to be capable of adjusting a temperature of the fluidizing gas to be fed to thegas boxes 32. Thegas feeding unit 33 is operable, upon start of the operation of thefluidized bed furnace 10, to blow the fluidizing gas in a high-temperature state from around the non-combustiblesubstance discharge port 29 toward thefluidizable particles 12. In this way, thegas feeding unit 33 is operable to heat thefluidizable particles 12 until thefluidizable particles 12 reach a temperature capable of performing combustion and gasification of thewaste 18. In this case, when thefluidizable particles 12 is heated up to a high temperature and combustion of thewaste 18 is started, the temperature of thefluidizable particles 12 will be maintained by the combustion. Thus, thegas feeding unit 33 may be configured to lower the temperature of the fluidizing gas to be fed to thegas boxes 32 just after start of the combustion. - The
waste supply section 40 is designed to supplywaste 18 from thefront wall 24 to a region on thefluidized bed 14 adjacent to thefront wall 24. Thewaste supply section 40 in this embodiment is configured to pushwaste 18 generally horizontally from the front wall 24 (specifically, thewaste introduction port 28 of the front wall 24) onto thefluidized bed 14, thereby causing thewaste 18 to be moved toward the non-combustiblesubstance discharge port 29. In other words, thewaste supply section 40 is adapted to pushwaste 18 to cause thewaste 18 to be accumulated on thesecond fluidization region 16 while causing the accumulatedwaste 18 to be moved into thefirst fluidization region 15 step-by-step. Thewaste supply section 40 comprises apusher 41 and a drive unit (illustration is omitted) for driving thepusher 41. Thepusher 41 has a pushingsurface 42 extending in the width direction. In this embodiment, the pushingsurface 42 has a widthwise length equal to a width of thewaste introduction port 28 of thefront wall 24. Further, the pushingsurface 42 has a vertical length which is approximately a half of a height dimension of an opening of thewaste introduction port 28. Thepusher 41 is installed to be movable in the front-rear direction, at the same height position as that of thewaste introduction port 28. The drive unit comprises a driving power source such as a motor or a cylinder, and is adapted to reciprocatingly move thepusher 41 in the front-rear direction by the driving power. It is to be noted that thewaste supply section 40 is not limited to a specific configuration. For example, thewaste supply section 40 in this embodiment is configured such that thepusher 41 is employed to pushwaste 18 into the furnace body. However, the waste supply section may be configured such that a screw extruder or the like is employed to pushwaste 18 into the furnace body. Based on employing thepusher 41 or the screw extruder, it becomes possible to supply trash which is likely to be scattered due to its small bulk specific gravity, such as paper or plastic sheet, into thefurnace body 20 while keeping a massive form. This makes it possible to suppress scattering of trash inside thefurnace body 20, as compared to a conventional furnace in which trash is input from an upper portion thereof. - The
sand circulation device 50 is designed to return thefluidizable particles 12 discharged from the non-combustiblesubstance discharge port 29, to thefluidized bed 14 at a position on the side of thewaste supply section 40 to circulate thefluidizable particles 12. When thesand circulation device 50 operates to return thefluidizable particles 12 discharged from the non-combustiblesubstance discharge port 29, to thefluidized bed 14 at a position on the side of thefront wall 24, in the above manner, a flow of thefluidizable particles 12 directed from thefront wall 24 to the non-combustiblesubstance discharge port 29 is formed inside thefluidized bed 14. In addition, thesecond fluidization region 16 is maintained at a high temperature to some extent. Thesand circulation device 50 comprises a non-combustiblesubstance discharge section 51, aseparation section 52, and aconveyance section 53. - The non-combustible
substance discharge section 51 is provided just below the non-combustiblesubstance discharge port 29 of thebottom wall 21, and adapted to move a mixture of non-combustible substances and a part of thefluidizable particles 12 dropping from the non-combustiblesubstance discharge port 29, to theseparation section 52. The non-combustiblesubstance discharge section 51 in this embodiment is configured to move the mixture dropping from the non-combustiblesubstance discharge port 29, to theseparation section 52 by using a screw extruder. Theseparation section 52 is adapted to separate thefluidizable particles 12 from the mixture sent from the non-combustiblesubstance discharge section 51. Theseparation section 52 in this embodiment is configured to separate thefluidizable particles 12 from the mixture by using a sieve. Theconveyance section 53 is adapted to convey thefluidizable particles 12 separated in theseparation section 52, to thesand introduction section 27, and introduce the conveyedfluidizable particles 12 into thefurnace body 20 via thesand introduction section 27. - The
sand circulation device 50 in this embodiment is configured to return thefluidizable particles 12 discharged from the non-combustiblesubstance discharge port 29, to thefluidized bed 14 by inputting thefluidizable particles 12 from above thefluidized bed 14 toward an upper surface of thefluidized bed 14. However, it is not limited to this configuration. For example, as illustrated inFIG. 4 , thefluidizable particles 12 discharged from the non-combustiblesubstance discharge port 29 may be directly returned to an inside of thefluidized bed 14. In the example illustrated inFIG. 4 , a sand introduction section (sand introduction opening) 27A is provided in thefront wall 24 at an intermediate height position of thefluidized bed 14. Ascrew extruder 55 is provided at an end of theconveyance section 53 of thesand circulation device 50 on the side of thefurnace body 20, and the furnace body-side end of theconveyance section 53 is inserted into thesand introduction section 27. In this manner, thefluidizable particles 12 discharged from the non-combustiblesubstance discharge port 29 may be returned to thefluidized bed 14 in such a manner as to be directly pushed into thefluidized bed 14. In this case, thesand introduction section 27 is not limited to the intermediate height position of thefluidized bed 14, but may be located on a relatively upper or lower side in a height direction of thefluidized bed 14. When thefluidizable particles 12 are pushed into thefluidized bed 14, a movement of thefluidizable particles 12 in a horizontal direction is more forcibly performed, so that it becomes possible to suppress non-combustible substances from being accumulated on a furnace floor. - In the
fluidized bed furnace 10 configured as above, a combustible gas is collected fromwaste 18 in the following manner. - Upon feeding the fluidizing gas from the
gas feeding unit 33 to therespective gas boxes 32, the fluidizing gas is blown from thebottom wall 21 into thefurnace body 20 toward thefluidizable particles 12, so that thefluidized bed 14 is formed inside thefurnace body 20. In this process, thegas feeding unit 33 adjusts a flow volume of the fluidizing gas to be fed to each of thegas boxes 32. Through this adjustment, in thefluidized bed 14, thefirst fluidization region 15 actively fluidized is formed on the side of the non-combustiblesubstance discharge port 29, and thesecond fluidization region 16 restrained in fluidization is formed between thefirst fluidization region 15 and thefront wall 24. Further, thegas feeding unit 33 feeds the fluidizing gas in a high-temperature state to a part (e.g., in this embodiment, thegas boxes gas boxes 32 corresponding to thefirst fluidization region 15 to positively heat thefluidizable particles 12 in thefirst fluidization region 15. - Concurrently, the
sand circulation device 50 circulates thefluidizable particles 12 to form a flow of thefluidizable particles 12 in the fluidized bed. Specifically, the non-combustiblesubstance discharge section 51 sends thefluidizable particles 12 dropping from the non-combustiblesubstance discharge port 29 of thefurnace body 20, to theseparation section 52. Then, theconveyance section 53 conveys thefluidizable particles 12 passing through theseparation section 52, to thesand introduction section 27 of thefurnace body 20. The conveyedfluidizable particles 12 are returned to thefluidized bed 14 at a position on the side of thefront wall 24, via thesand introduction section 27. When thefluidizable particles 12 discharged from the non-combustiblesubstance discharge port 29 located on the side of therear wall 25 is returned to thefluidized bed 14 at a position on the side of thefront wall 24, in the above manner, a flow of thefluidizable particles 12 directed from thefront wall 24 to the non-combustiblesubstance discharge port 29 is formed in thefluidized bed 14. In this process, thefluidizable particles 12 in thefirst fluidization region 15 in a higher-temperature state are partially discharged from the non-combustiblesubstance discharge port 29, and thesand circulation device 50 returns the dischargedfluidizable particles 12 to thefluidized bed 14 at a position on the side of thefront wall 24. This allows a temperature of thesecond fluidization region 16 to be maintained at a predetermined value. However, during the period in which thefluidizable particles 12 discharged from the non-combustiblesubstance discharge port 29 are returned to thefluidized bed 14 by thesand circulation device 50, a temperature of thefluidizable particles 12 is lowered. Therefore, thesecond fluidization region 16 has a temperature less than that of thefirst fluidization region 15. Preferably, the temperature of thefirst fluidization region 15 is kept in the range of 600 to 800°C, whereas the temperature of thesecond fluidization region 16 is kept in the range of about 400 to 600°C. - When the temperatures of the
regions fluidized bed 14 within thefurnace body 20 reach respective predetermined values, thewaste supply section 40 starts to pushwaste 18 into thefurnace body 20 via thewaste introduction port 28. Specifically, thepusher 41 driven by the drive unit pusheswaste 18 generally horizontally toward therear wall 25. Through this operation, thewaste 18 is pushed onto thesecond fluidization region 16 at a position adjacent to the front wall 24 (seeFIG. 2 ). - The fluidization of the
fluidizable particles 12 in thesecond fluidization region 16 is restrained. Thus, the pushedwaste 18 is not positively mixed with thefluidizable particles 12, so that most of thewaste 18 is accumulated on thesecond fluidization region 16, and heavy non-combustible substances therein sink down. Consequently, in thesecond fluidization region 16, rapid combustion of thewaste 18 is suppressed, and easily-gasifiable substances in the waste are gasified by heat radiation within thefurnace body 20. In other words, easilygasifiable waste 18 such as plastic or paper is gasified while being moved in a surface layer of thesecond fluidization region 16. On the other hand, not-easily gasifiable waste such as a wood piece is partially gasified, but a large part thereof reaches thefirst fluidization region 15 without being gasified. In this manner, the easilygasifiable waste 18 is gasified under a mild condition in thesecond fluidization region 16 before it reaches the highly fluidized bed (first fluidization region 15). This makes it possible to suppress a fluctuation of generation of a combustible gas. The accumulatedwaste 18 is combusted by radiation heat within thefurnace body 20, as mentioned above. However, although the radiation heat has a temperature of 800 to 900°C which is greater than that of thefluidizable particles 12 forming thefluidized bed 14, a contact between thewaste 18 and air is not satisfactory. Thus, easily combustible trash, such as paper or sheet-shaped plastic, inwaste 18, is mainly gasified. In this process, thesecond fluidization region 16 has a relatively low temperature, and an amount of air (fluidizing gas) to be supplied to thesecond fluidization region 16 is relatively small, so that even the easily combustible trash will be gradually gasified. Further, thefluidizable particles 12 are gradually discharged through the non-combustiblesubstance discharge port 29, so that, according to the discharge of thefluidizable particles 12 and the fluidization of thefluidizable particles 12 by the fluidizing gas, a part of the accumulatedwaste 18 is moved or spread step-by-step in a left-to-right direction inFIG. 1 . Therefore, even ifwaste 18 is input in a massive form, and easily combustible papers are comprised therein, it can be expected to promote gasification of the papers based on a phenomenon that the papers are moved toward a surface of the massive waste during the spreading. As above, in thesecond fluidization region 16, rapid combustion of thewaste 18 is suppressed to prevent a rapid increase of combustible gas during introduction ofwaste 18. - Subsequently,
new waste 18 is pushed into thefurnace body 20 via thewaste introduction port 28 by thepusher 41. Thus, thewaste 18 accumulated on thesecond fluidization region 16 is pushed by thenew waste 18, and moved into thefirst fluidization region 15 step-by-step. Thefirst fluidization region 15 is actively fluidized and heated up to a high temperature by combustion of thewaste 18, so that thewaste 18 moved from a position on thesecond fluidization region 16 is mixed with thefluidizable particles 12 and sufficiently gasified. Consequently, a combustible gas is generated. More specifically, in thefluidized bed 14, a fluidized state gradually becomes more active in a direction from thefront wall 24 to the non-combustiblesubstance discharge port 29. Thus, when thewaste 18 is moved from a position on thesecond fluidization region 16 adjacent to thefront wall 24 to thefirst fluidization region 15 step-by-step, it will be gradually mixed with thefluidizable particles 12. Further, an amount of blowing air (fluidizing gas) is gradually increased in the direction from thefront wall 24 to the non-combustiblesubstance discharge port 29. Thus, when thewaste 18 is moved from thesecond fluidization region 16 to thefirst fluidization region 15 step-by-step, it will be gradually combusted, causing an increase in temperature of thefluidizable particles 12. In a region of this high-temperature fluidized bed 14 just above the non-combustiblesubstance discharge port 29 and the vicinity thereof, thewaste 18 is sufficiently mixed with thefluidizable particles 12. This allows theuncombusted waste 18 remaining after passing through thesecond fluidization region 16 to be sufficiently gasified in thefirst fluidization region 15. - On the other hand, the
waste 18 newly pushed onto thesecond fluidization region 16 by thepusher 41 is accumulated on thesecond fluidization region 16 almost without being mixed with thefluidizable particles 12 as mentioned above. Then, the accumulatedwaste 18 is gradually combusted under the condition that violent or rapid combustion is suppressed. - As above, under the condition that the
first fluidization region 15 and thesecond fluidization region 16 are formed in thefluidized bed 14,waste 18 is pushed in one after another by thepusher 41, which makes it possible to suppress intermittent and rapid generation of a combustible gas, thereby stabilizing the gas generation. - In advance of stopping the
fluidized bed furnace 10, the pushing ofwaste 18 into thefurnace body 20 by thepusher 41 is firstly stopped. Upon stopping the pushing ofwaste 18, thegas feeding unit 33 feeds a mixture formed by mixing an inert gas with air, as the fluidizing gas to be supplied to therespective gas boxes 32. In this process, thegas feeding unit 33 operates to gradually increase the inert gas in a ratio between air and the inert gas in the fluidizing gas, with time. In this manner, thegas feeding unit 33 restrains an oxygen concentration within thefurnace body 20 to suppress violent or rapid combustion of thewaste 18 remaining in thefluidized bed 14. - In this embodiment, during stop of the
fluidized bed furnace 10, violent or rapid combustion of thewaste 18 remaining in thefluidized bed 14 is suppressed by gradually increasing the ratio of the inert gas occupied in the fluidizing gas. Alternatively, during stop of thefluidized bed furnace 10, combustion of the remainingwaste 18 may be prevented by spraying water onto thefluidized bed 14. - As mentioned above, the
fluidized bed furnace 10 according to the above embodiment is capable of suppressing intermittent and rapid generation of a combustible gas to stabilize the gas generation, even in a situation where a large amount of easily combustible trash is comprised in waste. Specifically, in thefluidized bed 14, thefirst fluidization region 15 around the non-combustiblesubstance discharge port 29 and thesecond fluidization region 16 having a fluidization degree lower than that in thefirst fluidization region 15 are formed. In this state,new waste 18 is pushed onto thesecond fluidization region 16. The input of thenew waste 18 causes thewaste 18 accumulated on thesecond fluidization region 16 to be moved toward thefirst fluidization region 15 step-by-step. The above operation will be repeated. Thus, thefluidized bed furnace 10 can sufficiently gasify thewaste 18, while suppressing rapid fluctuation of generation of a combustible gas. Consequently, it becomes possible to stably generate a combustible gas from thewaste 18. In addition, just after input into thefurnace body 20, thewaste 18 is not exposed to the highly fluidized bed (the first fluidization region 15), so that it becomes possible to suppress a situation where a large amount of lightweight trash flies up inside thefurnace body 20 and undergoes rapid combustion in a free board section. - In the
furnace body 20, theupper surface 21a of thebottom wall 21 is inclined to become lower toward the non-combustiblesubstance discharge port 29. Thus, when non-combustible substances in thewaste 18 sinks down to thebottom wall 21 in thefluidized bed 14, they fall on theupper surface 21a of thebottom wall 21 toward the non-combustiblesubstance discharge port 29. In this manner, the non-combustible substances are discharged from the non-combustiblesubstance discharge port 29 together with a part of thefluidizable particles 12, so that it becomes possible to easily discharge non-combustible substances from thefurnace body 20. The non-combustible substances discharged from the non-combustiblesubstance discharge port 29 together with a part of thefluidizable particles 12 are separated from thefluidizable particles 12 in theseparation section 52 of thesand circulation device 50. - The
furnace body 20 has a shape in plan view, in which a dimension in the width direction thereof is equalized in a pushing direction ofwaste 18. Thus, when thewaste 18 on thesecond fluidization region 16 is pushed bywaste 18 newly pushed by thewaste supply section 40, and moved toward thefirst fluidization region 15, the movement of thewaste 18 is stabilized. In addition, a flow of thefluidizable particles 12 formed in a direction from thesecond fluidization region 16 to thefirst fluidization region 15 by thesand circulation device 50 is directionally the same as the movement of thewaste 18, so that the flow of thefluidizable particles 12 is also stabilized. - In the
waste supply section 40, thepusher 41 is adapted to be reciprocatingly moved in a direction parallel to the pushing direction (front-rear direction) to allow the pushingsurface 42 to pushwaste 18 onto thefluidized bed 14 simultaneously by the entire widthwise region of the pushingsurface 42. This allows the pushingsurface 42 to pushwaste 18 onto thefluidized bed 14 with an even force in the width direction. Thus, the movement of thewaste 18 from thesecond fluidization region 16 to thefirst fluidization region 15 is approximately equalized in the width direction, so that it becomes possible to prevent thewaste 18 from concentrating on a certain portion inside the furnace. - In the above embodiment, the
sidewall 22 stands upwardly and straight from thebottom wall 21 to the combustiblegas outlet portion 23. Alternatively, for example, as illustrated inFIG. 5 , the sidewall may comprise afront wall 24A having a reflectingportion 224 extending toward therear wall 25 to cover an upper side of thesecond fluidization region 16 at a predetermined height position. Thefront wall 24A allows thewaste 18 accumulated on thesecond fluidization region 16 to be heated by radiation heat from the reflectingportion 224. Consequently, it becomes possible to generate a combustible gas from thewaste 18 accumulated on thesecond fluidization region 16. In other words, gasification of thewaste 18 accumulated on thesecond fluidization region 16 is promoted. - Alternatively, as illustrated in
FIG. 6 , the sidewall may comprise arear wall 25A having aguide portion 225 extending toward thefront wall 24 to cover an upper side of thefirst fluidization region 15 at a predetermined height position. Theguide portion 225 is adapted to guide a high-temperature combustible gas generated from thewaste 18 in thefirst fluidization region 15 to allow the combustible gas to be brought into contact with thewaste 18 accumulated on thesecond fluidization region 16. In this way, theguide portion 225 allows the combustible gas to contribute to heating of thewaste 18 accumulated on thesecond fluidization region 16. Consequently, it becomes possible to promote gasification of thewaste 18 accumulated on thesecond fluidization region 16 without adding special heating means to thefurnace body 20. - Alternatively, as illustrated in
FIG. 7 , the sidewall may comprise afront wall 24B and arear wall 25B having, respectively, tworoof portions front wall 24B and therear wall 25B allow thewaste 18 accumulated on thesecond fluidization region 16 to be heated by radiation heat from theroof portion 324 of thefront wall 24B, so as to promote gasification thereof. In addition, a dimension of afurnace body 20B in the front-rear direction is reduced at a position lower than the combustiblegas outlet portion 23 at the upper end of thefurnace body 20B, so that it becomes possible to facilitate a reduction in size of thefurnace body 20B. - In the above embodiment, the
upper surface 21a of thebottom wall 21 has an inclination angle which is constant in the range from thefront wall 24 to the non-combustiblesubstance discharge port 29, the present invention is not limited thereto. Alternatively, for example, as illustrated inFIG. 8 , an inclination angle α of an upper surface 21d of abottom wall 21A on the side of thesecond fluidization region 16 with respect to a horizontal surface may be greater than an inclination angle β of an upper surface 21e of thebottom wall 21A on the side of thefirst fluidization region 15 with respect to the horizontal surface. When the upper surface 21d supporting thesecond fluidization region 16 restrained in fluidization, from therebelow, has a relatively large inclination angle in the above manner, non-combustible substances sinking down to thebottom wall 21A more reliably falls to the non-combustiblesubstance discharge port 29. Specifically, the inclination angle β of the upper surface 21e on the side of thefirst fluidization region 15 with respect to the horizontal surface is in the range of 15 degrees to 25 degrees, and the inclination angle α of the upper surface 21d on the side of thesecond fluidization region 16 with respect to the horizontal surface is in the range of 20 degrees to 75 degrees, preferably, in the range of 20 degrees to 30 degrees. - Alternatively, the
upper surface 21a of thebottom wall 21 may be curved from thefront wall 24 to the non-combustiblesubstance discharge port 29, instead of being inclined straight. - As illustrated in
FIG. 9 , and according to the present invention, a plurality of thermometers T are disposed just above thesecond fluidization region 16, and anair supply section 60 capable of supplying air onto thesecond fluidization region 16 is provided. In this fluidized bed furnace, an accumulated amount of thewaste 18 accumulated on thesecond fluidization region 16 can be estimated, so that it becomes possible to control the accumulated amount. Specifically, the accumulated amount of thewaste 18 on thesecond fluidization region 16 is estimated by utilizing a phenomenon that an indication value of the thermometer T embedded in thewaste 18 is lowered. When the accumulated amount is relatively large, i.e., the number of the thermometers T embedded in thewaste 18 is relatively large, theair supply section 60 is operable to supply air to increase an internal temperature of thefurnace body 20. Accordingly, gasification of thewaste 18 accumulated on thesecond fluidization region 16 is prompted, so that the accumulated amount of thewaste 18 is reduced. As another method, an amount of the air may be controlled based on determinations made as follows: when a temperature of a designated one of the thermometers T is equal to or greater than a threshold value, it is determined that there is no waste at a position of the designated thermometer T, and, when the temperature is less than the threshold value, it is determined that there is waste at the position of the designated thermometer T (the designated thermometer T is embedded in waste). - In the above embodiment, the
gas feeding unit 33 is configured to feed air and/or an inert gas as the fluidizing gas. Alternatively, for example, thegas feeding unit 33 may be configured to feed water vapor and/or oxygen as the fluidizing gas, depending on a combustion state within thefurnace body 20. Thefluidized bed furnace 10 may further comprise a second gas supply section provided in thesidewall 22 in addition to the firstgas supply section 30, wherein the second gas supply section may be configured to be capable of supplying air, oxygen, water vapor or the like into thefurnace body 20, depending on a combustion state in thefluidized bed 14 or of thewaste 18. - The fluidizing gas to be supplied to the
second fluidization region 16 may be a high-temperature fluidizing gas. In the case of supplying the high-temperature fluidizing gas, even in a situation where it is difficult to sufficiently keep a temperature of thesecond fluidization region 16 only by the circulation of thefluidizable particles 12, the temperature of thesecond fluidization region 16 can be maintained at a high value without increasing an amount of the fluidizing gas to be supplied. - In the above embodiment, the
waste introduction port 28 is provided at a height position partially overlapping with respect to thewaste 18 accumulated on thefluidized bed 14 in the up-down direction, so thatwaste 18 supplied from thewaste introduction port 28 positively moves thewaste 18 accumulated on the upper surface of thefluidized bed 14, generally horizontally (toward the first fluidization region 15). Alternatively, thefluidized bed furnace 10 may have any configuration capable of supplyingwaste 18 to a region on thefluidized bed 14 adjacent to the front wall (supply-side sidewall portion) 24. For example, as illustrated inFIG. 10A and FIG. 10B , thewaste introduction port 28 may be provided at a height position which is located adjacent to the upper surface of thefluidized bed 14, and free of contact withwaste 18 when it is newly supplied onto thewaste 18 accumulated (on the second fluidization region 16) in a region of the upper surface of thefluidized bed 14 adjacent to thefront wall 24.
In this case, as illustrated, for example, inFIG. 10A , thewaste introduction port 28 may be provided to allow new waste to be supplied generally horizontally from a height position above thewaste 18 accumulated on thefluidized bed 14. Alternatively, as illustrated inFIG. 10B , thewaste introduction port 28 may be provided to allow new waste to be supplied downwardly from a height position above thewaste 18 accumulated on thefluidized bed 14. Even ifwaste 18 is supplied into thefurnace body 20 in the above manner, when thenew waste 18 is supplied onto the accumulatedwaste 18, a pile ofwaste 18 is broken and spread, and thespread waste 18 is moved toward thefirst fluidization region 15. Further, according to the flow of thefluidizable particles 12 formed in thefluidized bed 14 in the direction from thefront wall 24 to the non-combustiblesubstance discharge port 29, thewaste 18 accumulated on thefluidized bed 14 is also moved toward thefirst fluidization region 15. Thus, gasification of thewaste 18 is sufficiently performed while suppressing rapid fluctuation of generation of a combustible gas to be collected from thefluidized bed furnace 10. Consequently, it becomes possible to stably generate a combustible gas from thewaste 18. - In the above embodiment, the fluidizing gas to be supplied to the
fluidized bed 14 is supplied in thesecond fluidization region 16 at a flow velocity satisfying the condition that Uo/Umf ranges from 1 to less than 2, and supplied in thefirst fluidization region 15 at a flow velocity satisfying a condition that Uo/Umf ranges from 2 to less than 5, as mentioned above. Alternatively, for example, in a situation where non-combustible substances are accumulated on a furnace floor (theupper surface 21a of the bottom wall 21) without being discharged to the outside, the fluidizing gas may also be supplied in thesecond fluidization region 16 at a flow velocity satisfying the condition that Uo/Umf ranges from 2 to less than 5, only for a certain period of time in order to discharge the accumulated non-combustible substances to the outside. In this case, preferably, an amount of the fluidizing gas to be supplied to each of thegas boxes 32 is increased step-by-step in a direction from the front wall 24 (left side inFIG. 1 ) to the rear wall 25 (right side inFIG. 1 ) of thefurnace body 20, instead of blowing the fluidizing gas evenly in the entiresecond fluidization region 16. Specifically, at a certain time t0, a flow volume of the fluidizing gas to be supplied to thegas box 32a becomes greater than that of the fluidizing gas to be supplied to each of the remaining gas boxes. Then, at a time t1 after an elapse of several seconds, the flow volume of the fluidizing gas to be supplied to thegas box 32a is returned to a value during a normal operation, and a flow volume of the fluidizing gas to be supplied to theadjacent gas box 32b becomes greater than that of the fluidizing gas to be supplied to each of the remaining gas boxes. Then, at a time t2 after a further elapse of several seconds, the flow volume of the fluidizing gas to be supplied to thegas box 32b is returned to an original value, and a flow volume of the fluidizing gas to be supplied to theadjacent gas box 32c becomes greater than that of the fluidizing gas to be supplied to each of the remaining gas boxes. Based on the above operation, even if non-combustible substances are accumulated on the furnace floor during the normal operation, it becomes possible to reliably discharge the non-combustible substances to the outside of thefurnace body 20. The above specific operation is performed only for a significantly short time, so that an influence on facilities in a subsequent stage can be minimized. - The fluidized bed furnace according to the above embodiment is designed to heat waste to extract a combustible gas from the waste. The fluidized bed furnace comprises the features of claim 1.
- In this fluidized bed furnace, the first fluidization region around the non-combustible substance discharge port and the second fluidization region having a fluidization degree lower than that in the first fluidization region are formed in the fluidized bed. In this state, the waste supply section supplies waste to a region on the fluidized bed adjacent to the supply-side sidewall portion to cause the waste to be accumulated on the second fluidization region while causing the waste accumulated on the second fluidization region to be moved into the first fluidization region step-by-step. Thus, gasification of the waste is sufficiently performed while suppressing rapid fluctuation of generation of a combustible gas to be collected from the fluidized bed furnace, so that it becomes possible to stably generate a combustible gas from the waste.
- Specifically, fluidization in the second fluidization region is restrained, so that the waste is accumulated on the second fluidization region without being mixed with the fluidizable particles, and easily combustible components of the waste are slowly gasified. Therefore, in the second fluidization region, rapid combustion of the waste is suppressed, and generation of a combustible gas caused by rapid gasification of the waste is minimized. When new waste is supplied into the furnace body by the waste supply section, the waste accumulated on the second fluidization region is moved into the first fluidization region step-by-step. In the first fluidization region, the fluidizable particles are actively fluidized and heated to a high temperature by combustion of the waste, so that the waste moved from a position on the second fluidization region is sufficiently mixed with the fluidizable particles, and thereby the waste is sufficiently gasified to generate a combustible gas. Consequently, it becomes possible to suppress intermittent and rapid generation of a combustible gas, thereby stabilizing the gas generation. A temperature of the second fluidization region is maintained by the sand circulation device which returns the high-temperature fluidizable particles discharged from the non-combustible substance discharge port, to the second fluidization region of the fluidized bed. However, during the period in which the fluidizable particles discharged from the non-combustible substance discharge port are returned to the fluidized bed by the sand circulation device, a temperature of the fluidizable particles is lowered, so that the second fluidization region has a temperature less than that of the first fluidization region.
- The upper surface of the bottom wall is inclined to become lower toward the non-combustible substance discharge port, so that, when non-combustible substances in the waste sinks down to the bottom wall in the fluidized bed, they fall on the upper surface of the bottom wall toward the non-combustible substance discharge port. In this manner, the non-combustible substances are discharged from the non-combustible substance discharge port together with a part of the fluidizable particles, so that it becomes possible to easily discharge non-combustible substances from the furnace body.
- Preferably, the waste supply section is adapted to push new waste generally horizontally from the supply-side sidewall portion toward the waste accumulated on the second fluidization region, thereby causing the waste accumulated on the second fluidization region to be moved into the first fluidization region step-by-step.
- According to this feature, new waste is pushed generally horizontally toward the waste accumulated on the second fluidization region. Thus, the waste accumulated on the second fluidization region is pushed by the new waste and reliably moved into the first fluidization region.
- Preferably, in the fluidized bed furnace of the present invention, the gas supply section is adapted to blow the fluidizing gas in the second fluidization region at a flow velocity satisfying a condition that Uo/Umf ranges from 1 to less than 2, and blow the fluidizing gas in the first fluidization region at a flow velocity satisfying a condition that Uo/Umf ranges from 2 to less than 5, where Umf is a minimum fluidization velocity which is a minimum flow velocity of the fluidizing gas to be blown so as to fluidize the fluidizable particles, and Uo is a cross-sectional average flow velocity of the fluidizing gas.
- The first fluidization region and the second fluidization region can be desirably formed by blowing the fluidizing gas at the above flow velocities. Consequently, it becomes possible to desirably gasify the waste while suppressing rapid combustion of the waste, thereby stably obtaining a combustible gas from the waste.
- Preferably, the furnace body has a shape in plan view, in which a dimension in a width direction perpendicular to a pushing direction along which waste is pushed by the waste supply section is equalized in the pushing direction.
- According to this feature, when the waste on the second fluidization region is pushed by waste newly pushed by the waste supply section, and moved toward the first fluidization region, the movement of the waste is stabilized, because the dimension of the furnace body in a direction perpendicular to the waste pushing direction (width direction) is equalized. In addition, the flow of the fluidizable particles formed in a direction from the second fluidization region to the first fluidization region by the sand circulation device is directionally the same as the movement of the waste, so that the flow of the fluidizable particles is also stabilized.
- Preferably, the waste supply section comprises a pusher having a pushing surface extending in the width direction, and a drive unit for reciprocatingly moving the pusher in a direction parallel to the pushing direction to allow the pushing surface of the pusher to push waste onto the fluidized bed simultaneously by the entire widthwise region of the pushing surface.
- According to this feature, waste is pushed onto the fluidized bed with an even force in the width direction, so that the movement of the waste from the second fluidization region to the first fluidization region is approximately equalized in the width direction. Thus, it becomes possible to prevent the waste from concentrating on a certain portion inside the furnace.
- The waste treatment method according to the above embodiment is designed to heat waste to extract a combustible gas from the waste. The method comprises the steps described in claim 6.
- In this waste treatment method, the first fluidization region around the non-combustible substance discharge port and the second fluidization region having a fluidization degree lower than that in the first fluidization region are formed in the fluidized bed. Then, the waste is accumulated on the second fluidization region, and the waste accumulated on the second fluidization region is moved into the first fluidization region step-by-step. Thus, gasification of the waste is sufficiently performed while suppressing rapid fluctuation of generation of a combustible gas to be collected from the fluidized bed furnace, so that it becomes possible to stably generate a combustible gas from the waste.
- The upper surface of the bottom wall is inclined to become lower toward the non-combustible substance discharge port, so that non-combustible substances in the waste fall on the upper surface of the bottom wall toward the non-combustible substance discharge port. In this manner, the non-combustible substances are discharged from the non-combustible substance discharge port together with a part of the fluidizable particles, so that it becomes possible to easily discharge non-combustible substances from the furnace body.
- Preferably, the gasification step includes pushing new waste generally horizontally from the supply-side sidewall portion toward the waste accumulated on the second fluidization region, thereby causing the waste accumulated on the second fluidization region to be moved into the first fluidization region step-by-step and gasified.
- According to this feature, new waste is pushed generally horizontally toward the waste accumulated on the second fluidization region. Thus, the waste accumulated on the second fluidization region is pushed by the new waste and reliably moved into the first fluidization region, and gasified.
- Preferably, in the waste treatment method, the fluidizing gas is blown in the second fluidization region at a flow velocity satisfying a condition that Uo/Umf ranges from 1 to less than 2, and blown in the first fluidization region at a flow velocity satisfying a condition that Uo/Umf ranges from 2 to less than 5, where Umf is a minimum fluidization velocity which is a minimum flow velocity of the fluidizing gas to be blown so as to fluidize the fluidizable particles, and Uo is a cross-sectional average flow velocity of the fluidizing gas.
- The first fluidization region and the second fluidization region can be desirably formed by blowing the fluidizing gas at the above flow velocities. Consequently, it becomes possible to desirably gasify the waste while suppressing rapid combustion of the waste, thereby stably obtaining a combustible gas from the waste.
- As above, the fluidized bed furnace and the waste treatment method of the present invention are useful in heating waste in a fluidized bed formed by fluidizing fluidizable particles, to extract a combustible gas from the waste, and suitable for stably obtaining a combustible gas even from waste comprising easily combustible trash.
Claims (8)
- A fluidized bed furnace (10) for heating waste (18) to extract a combustible gas from the waste (18), comprising:fluidizable particles (12) making up a fluidized bed (14) to heat the waste (18);a furnace body (20) having a bottom wall (21) supporting the fluidizable particles (12) from therebelow, and a sidewall (22) standing upwardly from the bottom wall (21), wherein the bottom wall (21) has a non-combustible substance discharge port (29) provided at a position offset from a center position of the bottom wall (21) in a specific direction to discharge non-combustible substances in the waste (18) together with a part of the fluidizable particles (12), and an upper surface (21a) of the bottom wall (21) is inclined to become lower toward the non-combustible substance discharge port (29) so as to cause the non-combustible substances to fall on the upper surface (21a) of the bottom wall (21) toward the non-combustible substance discharge port (29);a gas supply section (30) for blowing a fluidizing gas from the bottom wall (21) of the furnace body (20) toward the fluidizable particles (12) to fluidize the fluidizable particles (12);a waste supply section (40) for supplying waste (18) from a supply-side portion of the sidewall (22) located on a side opposite to the non-combustible substance discharge port (29) across the center position of the bottom wall (21), to a region on the fluidized bed (14) adjacent to the supply-side sidewall portion (24), thereby causing the waste (18) on the fluidized bed (14) to be moved toward the non-combustible substance discharge port (29);a sand circulation device (50) for returning the fluidizable particles (12) discharged from the non-combustible substance discharge port (29), to the fluidized bed (14) from the side of the waste supply section (40) to circulate the fluidizable particles (12), thereby forming a flow of the fluidizable particles (12) directed from the supply-side sidewall portion (24) located on the side opposite to the non-combustible substance discharge port (29), to the non-combustible substance discharge port (29);a plurality of thermometers (T) disposed above the fluidized bed (14); andan air supply section (60) for supplying air above the fluidized bed (14),
wherein:the gas supply section (30) is configured to blow the fluidizing gas from around the non-combustible substance discharge port (29) to form a first fluidization region (15) where the fluidizable particles (12) are moved in a convection-like pattern and mixed with the waste (18) to gasify the waste (18), while blowing the fluidizing gas between the first fluidization region (15) and the waste supply section (40) at a flow velocity less than that of the fluidizing gas to be blown in the first fluidization region (15), to form a second fluidization region (16) having a degree of fluidization of the fluidizable particles (12) lower than that in the first fluidization region (15);the waste supply section (40) is adapted to supply waste (18) from the supply-side sidewall portion (24) to the fluidized bed (14) to cause the waste (18) to be accumulated on the second fluidization region (16) while causing the accumulated waste (18) to be moved into the first fluidization region (15) step-by-step.; the plurality of thermometers (T) are disposed at different positions from each other above the second fluidization region (16); andthe air supply section (60) is configured to supply air above the second fluidization region (16) in accordance with an indication value of each of the plurality of thermometers (T) so that the furnace body (20) has a predetermined internal temperature. - The fluidized bed furnace (10) as defined in claim 1, wherein the waste supply section (40) is adapted to push new waste (18) generally horizontally from the supply-side sidewall portion (24) toward the waste (18) accumulated on the second fluidization region (16), thereby causing the waste (18) accumulated on the second fluidization region (16) to be moved into the first fluidization region (15) step-by-step.
- The fluidized bed furnace (10) as defined in claim 1 or 2, wherein the gas supply section (30) is configured to blow the fluidizing gas in the second fluidization region (16) at a flow velocity satisfying a condition that Uo/Umf ranges from 1 to less than 2, and blow the fluidizing gas in the first fluidization region (15) at a flow velocity satisfying a condition that Uo/Umf ranges from 2 to less than 5, where Umf is a minimum fluidization velocity which is a minimum flow velocity of the fluidizing gas to be blown so as to fluidize the fluidizable particles (12), and Uo is a cross-sectional average flow velocity of the fluidizing gas.
- The fluidized bed furnace (10) as defined in any one of claims 1 to 3, wherein the furnace body (20) has a shape in plan view, in which a dimension in a width direction perpendicular to a pushing direction along which waste (18) is pushed by the waste supply section (40) is equalized in the pushing direction.
- The fluidized bed furnace (10) as defined in claim 4, wherein the waste supply section (40) comprises a pusher (41) having a pushing surface (42) extending in the width direction, and a drive unit for reciprocatingly moving the pusher (41) in a direction parallel to the pushing direction to allow the pushing surface (42) of the pusher (41) to push waste (18) onto the fluidized bed (14) simultaneously by the entire widthwise region of the pushing surface (42).
- A waste treatment method for heating waste (18) to extract a combustible gas from the waste (18), comprising:a preparation step of preparing a fluidized bed furnace (10) comprising fluidizable particles (12) making up a fluidized bed (14) to heat the waste (18), a furnace body (20) having a bottom wall (21) supporting the fluidizable particles (12) from therebelow and a sidewall (22) standing upwardly from the bottom wall (21), wherein the bottom wall (21) has a non-combustible substance discharge port (29) provided at a position offset from a center position of the bottom wall (21) in a specific direction to discharge non-combustible substances in the waste (18) together with a part of the fluidizable particles (12), and an upper surface (21a) of the bottom wall (21) is inclined to become lower toward the non-combustible substance discharge port (29) so as to cause the non-combustible substances to fall on the upper surface (21a) of the bottom wall (21) toward the non-combustible substance discharge port (29);a fluidization-region formation step of blowing a fluidizing gas from a region of the bottom wall (21) of the furnace body (20) around the non-combustible substance discharge port (29) toward the fluidizable particles (12) to form a first fluidization region (15) where the fluidizable particles (12) are moved in a convection-like pattern, while blowing a fluidizing gas between the first fluidization region (15) and a supply-side portion of the sidewall (22) located on a side opposite to the non-combustible substance discharge port (29) across the center position of the bottom wall (21), at a flow velocity less than that of the fluidizing gas to be blown in the first fluidization region (15), to form a second fluidization region (16) having a degree of fluidization of the fluidizable particles (12) lower than that in the first fluidization region (15);a fluidizable-particle-flow formation step of returning the fluidizable particles (12) discharged from the non-combustible substance discharge port (29), to the fluidized bed (14) from the side of the supply-side sidewall portion (24) to circulate the fluidizable particles (12), thereby forming a flow of the fluidizable particles (12) directed from the supply-side sidewall portion (24) to the non-combustible substance discharge port (29);a gasification step of supplying waste (18) from the supply-side sidewall portion (24) to a region on the fluidized bed (14) adjacent to the supply-side sidewall portion (24), thereby causing the waste (18) to be accumulated on the second fluidization region (16), while causing the accumulated waste (18) to be moved into the first fluidization region (15) step-by-step and gasified; andan air supplying step of supplying air above the fluidized bed (14);
wherein:in the preparation step, the fluidized bed furnace (10) further including a plurality of thermometers (T) and an air supply section (60) is prepared, the plurality of thermometers (T) being disposed at different positions from each other above the second fluidization region (16), and the air supply section (60) supplying air above the second fluidization region (16); andin the air supplying step, the air supply section (60) supplies air above the second fluidization region (16) in accordance with an indication value of each of the plurality of thermometers (T) so that the furnace body (20) has a predetermined internal temperature . - The waste treatment method as defined in claim 6, wherein the gasification step includes pushing new waste (18) generally horizontally from the supply-side sidewall portion (24) toward the waste (18) accumulated on the second fluidization region (16), thereby causing the waste (18) accumulated on the second fluidization region (16) to be moved into the first fluidization region (15) step-by-step and gasified.
- The waste treatment method as defined in claim 6 or 7, wherein the fluidizing gas is blown in the second fluidization region (16) at a flow velocity satisfying a condition that Uo/Umf ranges from 1 to less than 2, and blown in the first fluidization region (15) at a flow velocity satisfying a condition that Uo/Umf ranges from 2 to less than 5, where Umf is a minimum fluidization velocity which is a minimum flow velocity of the fluidizing gas to be blown so as to fluidize the fluidizable particles (12), and Uo is a cross-sectional average flow velocity of the fluidizing gas.
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PL11797836T PL2587146T3 (en) | 2010-06-22 | 2011-06-21 | Fluidized bed furnace and waste treatment method |
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JP2010141830A JP5694690B2 (en) | 2010-06-22 | 2010-06-22 | Fluidized bed furnace and waste treatment method |
PCT/JP2011/003527 WO2011161947A1 (en) | 2010-06-22 | 2011-06-21 | Fluidized bed furnace and waste processing method |
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EP2587146A1 EP2587146A1 (en) | 2013-05-01 |
EP2587146A4 EP2587146A4 (en) | 2015-10-07 |
EP2587146B1 true EP2587146B1 (en) | 2017-11-29 |
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EP11797836.1A Not-in-force EP2587146B1 (en) | 2010-06-22 | 2011-06-21 | Fluidized bed furnace and waste treatment method |
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US (1) | US20130092064A1 (en) |
EP (1) | EP2587146B1 (en) |
JP (1) | JP5694690B2 (en) |
CN (1) | CN102947646A (en) |
PL (1) | PL2587146T3 (en) |
WO (1) | WO2011161947A1 (en) |
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JP2015010746A (en) * | 2013-06-27 | 2015-01-19 | 株式会社神鋼環境ソリューション | Particle supply device, cleaning method and cleaning device |
JP2015045422A (en) * | 2013-08-27 | 2015-03-12 | 株式会社Ihi | Fluidized-bed boiler |
JP6178352B2 (en) * | 2014-03-18 | 2017-08-09 | 株式会社神鋼環境ソリューション | Operating method of fluidized bed furnace and fluidized bed furnace |
JP2016000379A (en) * | 2014-06-11 | 2016-01-07 | 永田エンジニアリング株式会社 | Foreign matter separation device of fluidized bed incinerator |
JP6109400B1 (en) * | 2016-12-01 | 2017-04-05 | 建十 鳥居 | Refractories and incinerators |
Citations (1)
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JPH10318517A (en) * | 1997-05-20 | 1998-12-04 | Nkk Corp | Method of controlling combustion of fluidized bed incinerator and combustion controlling device |
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JP3153091B2 (en) * | 1994-03-10 | 2001-04-03 | 株式会社荏原製作所 | Waste treatment method and gasification and melting and combustion equipment |
JPS58108317A (en) * | 1981-12-21 | 1983-06-28 | Fuji Electric Co Ltd | Incinerating material supply device for fluidized bed type incinetrating furnace |
JPS61205720A (en) * | 1985-03-08 | 1986-09-11 | Kobe Steel Ltd | Lateral type fluidized bed type incinerator |
US4777889A (en) * | 1987-05-22 | 1988-10-18 | Smith Richard D | Fluidized bed mass burner for solid waste |
JPH07110122A (en) * | 1993-08-17 | 1995-04-25 | Mitsubishi Heavy Ind Ltd | Fluidized bed combustion apparatus |
JP2639885B2 (en) * | 1993-08-18 | 1997-08-13 | 株式会社タクマ | Waste incineration method and apparatus |
JP2727291B2 (en) * | 1993-11-22 | 1998-03-11 | 株式会社タクマ | Fluidized bed incinerator |
US5401130A (en) * | 1993-12-23 | 1995-03-28 | Combustion Engineering, Inc. | Internal circulation fluidized bed (ICFB) combustion system and method of operation thereof |
JP2991639B2 (en) * | 1995-06-14 | 1999-12-20 | 日本碍子株式会社 | Waste incineration equipment |
JP3037134B2 (en) * | 1996-04-26 | 2000-04-24 | 日立造船株式会社 | Fluid bed incinerator |
JPH109511A (en) * | 1996-06-21 | 1998-01-16 | Ebara Corp | Fluidized bed gasification and melting combustion method |
JP3259831B2 (en) * | 1997-12-01 | 2002-02-25 | 川崎重工業株式会社 | Method and apparatus for reburning unburned components in a gasifier |
AU2641999A (en) * | 1998-02-27 | 1999-09-15 | Ebara Corporation | Fluidized bed gasification furnace |
JP3542280B2 (en) * | 1998-08-19 | 2004-07-14 | 日立造船株式会社 | Fluid bed incinerator |
JP4295291B2 (en) * | 2006-03-31 | 2009-07-15 | 三菱重工環境エンジニアリング株式会社 | Fluidized bed gasifier and its fluidized bed monitoring and control method |
-
2010
- 2010-06-22 JP JP2010141830A patent/JP5694690B2/en active Active
-
2011
- 2011-06-21 CN CN2011800311217A patent/CN102947646A/en active Pending
- 2011-06-21 EP EP11797836.1A patent/EP2587146B1/en not_active Not-in-force
- 2011-06-21 PL PL11797836T patent/PL2587146T3/en unknown
- 2011-06-21 WO PCT/JP2011/003527 patent/WO2011161947A1/en active Application Filing
- 2011-06-21 US US13/805,858 patent/US20130092064A1/en not_active Abandoned
Patent Citations (1)
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JPH10318517A (en) * | 1997-05-20 | 1998-12-04 | Nkk Corp | Method of controlling combustion of fluidized bed incinerator and combustion controlling device |
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EP2587146A4 (en) | 2015-10-07 |
US20130092064A1 (en) | 2013-04-18 |
JP5694690B2 (en) | 2015-04-01 |
WO2011161947A1 (en) | 2011-12-29 |
PL2587146T3 (en) | 2018-04-30 |
CN102947646A (en) | 2013-02-27 |
JP2012007763A (en) | 2012-01-12 |
EP2587146A1 (en) | 2013-05-01 |
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