JP2014069182A - High efficiency pyrolytic furnace device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a high efficiency pyrolytic furnace device for removing toxic substances and malodors from smoke generated by pyrolysis by pyrolyzing waste.SOLUTION: The high efficiency pyrolytic furnace device 10 of the present invention comprises a pyrolytic furnace 11 for discharging the smoke by executing pyrolysis by supplying air to the waste 16 by superposing the waste 16 inputted to inputted ceramic powder and a kindling source and a showering tower 21 for storing oxide substance mixed water which has passed through an activated charcoal layer 23 in a storage tank 24 provided below, by passing and sending the smoke sent from the pyrolytic furnace 11 from below to the activated charcoal layer 23, by showering the oxide substance mixed water supplied from a bubble generator 30 from above the activated charcoal layer 23 formed inside.

Description

  The present invention relates to a high-efficiency pyrolysis furnace apparatus that thermally decomposes waste and removes harmful substances, malodors, and the like from soot generated by the pyrolysis.

  In general, in a pyrolysis furnace, organic matter is treated with the power of lateral heating that ceramics emits when waste such as organic matter enters the pyrolysis chamber from the inlet. The pyrolysis furnace uses other energy for ceramics and raises the temperature. However, if there is organic matter etc., the thermal radiation retained by the ceramics will be decomposed by continuously treating the organic matter without adding energy from others. (For example, refer to Patent Document 1).

  JP 2007-332220 A

However, the conventional pyrolysis furnace can pyrolyze the waste such as the input organic matter, but there is a problem that it is difficult to remove harmful substances and bad odors from the smoke generated by the pyrolysis.
The present invention has been made in view of the above, and an object of the present invention is to provide a high-efficiency pyrolysis furnace apparatus that thermally decomposes waste and removes harmful substances, malodors, and the like from smoke generated by the pyrolysis. To do.

In the high-efficiency pyrolysis furnace apparatus of the present invention, the thrown-in ceramic powder and the waste thrown into the fire type are stacked, air is supplied to the waste, and the waste is pyrolyzed to generate smoke. Showering from above the activated carbon layer formed inside the pyrolysis furnace to be discharged and the oxidant mixed water supplied from the bubble generator, and passing the smoke sent from the pyrolysis furnace to the activated carbon layer from below. And a showering tower that stores the oxidized substance-mixed water that has passed through the activated carbon layer in a storage tank provided below.
In addition, a pyrolysis furnace that stacks the thrown-in ceramic powder and the thrown-in waste into the fire type, supplies air to the waste, performs thermal decomposition of the waste, and discharges smoke, and bubble generation Showering from above the activated carbon layer formed inside with the oxidant mixed water supplied from the vessel, passing the smoke sent from the pyrolysis furnace through the activated carbon layer from below, and sending it through the activated carbon layer The oxidizing substance mixed water is stored in a storage tank provided below, and the oxidizing substance mixed water supplied from a bubble generator is showered from above the activated carbon layer formed inside, and the delivery of the activated carbon layer to the activated carbon layer is performed. It was decided to include a combined shower ring tower that sends out smoke from below and sends the oxidized substance-mixed water that has passed through the activated carbon layer in the storage tank.
In addition, a pyrolysis furnace that stacks the thrown-in ceramic powder and the thrown-in waste into the fire type, supplies air to the waste, performs thermal decomposition of the waste, and discharges smoke, and bubble generation Showering from above the activated carbon layer formed inside with the oxidant mixed water supplied from the vessel, passing the smoke sent from the pyrolysis furnace through the activated carbon layer from below, and sending it through the activated carbon layer The oxidizing substance mixed water is stored in a storage tank provided below, and the oxidizing substance mixed water supplied from a bubble generator is showered from above the activated carbon layer formed inside, and the delivery of the activated carbon layer to the activated carbon layer is performed. A combined shower ring tower that sends smoke smoke from below and sends the oxidized substance mixed water that has passed through the activated carbon layer in the storage tank, and a combined shower ring tower. The smoke sent out is mixed into the water from the storage tank provided below as a bubble by a bubble generator, and the bubble mixed water from the bubble generator passes through the activated carbon accumulated in the activated carbon accumulation tank and passes through the activated carbon. And a gas, the gas is discharged to the outside, and the liquid is returned to the storage tank.
The bubble generator is formed on a cylindrical case in which a gas fed from one side surface and a liquid fed from an outer peripheral surface flow along a central axis, and the one side surface. A circular flow passage formed in the cylindrical case with the circular opening formed as a bottom surface, and the gas supplied and the liquid supplied connected to the conical flow passage And a liquid flow fed from the outer peripheral surface side flows into the cylindrical flow passage and flows into the gas fed from the one side surface side. It was decided to use a bubble generator provided with a liquid mixing part to be mixed.
Furthermore, the activated carbon storage tank is provided with a cylindrical net that allows the bubble-mixed water from the bubble generator to enter the inside and send it to the outside.

In the high-efficiency pyrolysis furnace apparatus of the present invention, the thrown-in ceramic powder and the waste thrown into the fire type are stacked, air is supplied to the waste, and the waste is pyrolyzed to generate smoke. Showering from above the activated carbon layer formed inside the pyrolysis furnace to be discharged and the oxidant mixed water supplied from the bubble generator, and passing the smoke sent from the pyrolysis furnace to the activated carbon layer from below. And the showering tower that stores the oxidized material mixed water that has passed through the activated carbon layer in a storage tank provided below, so that the waste is thermally decomposed and harmful from the soot generated by the thermal decomposition. Substances, bad odors, etc. can be removed efficiently.
In addition, a pyrolysis furnace that stacks the thrown-in ceramic powder and the thrown-in waste into the fire type, supplies air to the waste, performs thermal decomposition of the waste, and discharges smoke, and bubble generation Showering from above the activated carbon layer formed inside with the oxidant mixed water supplied from the vessel, passing the smoke sent from the pyrolysis furnace through the activated carbon layer from below, and sending it through the activated carbon layer The oxidizing substance mixed water is stored in a storage tank provided below, and the oxidizing substance mixed water supplied from a bubble generator is showered from above the activated carbon layer formed inside, and the delivery of the activated carbon layer to the activated carbon layer is performed. Since it is provided with a composite type showering tower for storing smoked water passing through the activated carbon layer and storing the oxidized material mixed water stored in the storage tank, the waste is separated from the heat. And harmful substances from the smoke generated by the thermal decomposition, can be removed more efficiently and malodor.
In addition, a pyrolysis furnace that stacks the thrown-in ceramic powder and the thrown-in waste into the fire type, supplies air to the waste, performs thermal decomposition of the waste, and discharges smoke, and bubble generation Showering from above the activated carbon layer formed inside with the oxidant mixed water supplied from the vessel, passing the smoke sent from the pyrolysis furnace through the activated carbon layer from below, and sending it through the activated carbon layer The oxidizing substance mixed water is stored in a storage tank provided below, and the oxidizing substance mixed water supplied from a bubble generator is showered from above the activated carbon layer formed inside, and the delivery of the activated carbon layer to the activated carbon layer is performed. A combined shower ring tower for sending smoke smoke from below and sending it, and storing the oxidant mixed water that has passed through the activated carbon layer in the storage tank; and the combined shower ring tower The smoke sent out is mixed into the water from the storage tank provided below as a bubble by a bubble generator, and the bubble mixed water from the bubble generator passes through the activated carbon accumulated in the activated carbon accumulation tank. The liquid is separated into liquid and gas, the gas is discharged to the outside, and the liquid is provided with a smoke treatment device that is returned to the storage tank. Hazardous substances, odors, etc. can be removed more efficiently and reliably.
The bubble generator is formed on a cylindrical case in which a gas fed from one side surface and a liquid fed from an outer peripheral surface flow along a central axis, and the one side surface. A circular flow passage formed in the cylindrical case with the circular opening formed as a bottom surface, and the gas supplied and the liquid supplied connected to the conical flow passage And a liquid flow fed from the outer peripheral surface side flows into the cylindrical flow passage and flows into the gas fed from the one side surface side. Since the bubble generator provided with the liquid mixing portion to be mixed is used, it is possible to generate bubbles accurately.
Furthermore, since the activated carbon accumulation tank is provided with a cylindrical net that allows the bubble-mixed water from the bubble generator to enter the inside and send it to the outside, the harmful substances, bad odors, and the like are more accurately detected from the smoke. Can be removed.

  The block diagram of the high efficiency pyrolysis furnace apparatus of embodiment of this invention is shown.   The longitudinal cross-sectional view of the bubble generator installed in the high efficiency pyrolysis furnace apparatus of embodiment of this invention is shown.

  Hereinafter, a highly efficient pyrolysis furnace apparatus according to an embodiment of the present invention will be described.

FIG. 1 shows a block diagram of a high-efficiency pyrolysis furnace apparatus according to an embodiment of the present invention.
As shown in FIG. 1, a high-efficiency pyrolysis furnace apparatus 10 according to an embodiment of the present invention includes a pyrolysis furnace 11, a first shower ring tower 21, a second shower ring tower 41, and a soot treatment apparatus. 61.

  The pyrolysis furnace 11 blows air, a charging door 17 into which ceramic powder 15 and a fire type 19 such as charcoal and coke are charged, a waste charging unit 12 in which an opening / closing lid 14 is opened and waste 16 is charged, and air. The blower pump 13 that opens and the open / close lid 14 is opened, and the delivery pipe 18 that sends out the smoke K generated by the thermal decomposition of the waste 16 introduced from the waste input unit 12.

  In the pyrolysis furnace 11, the ceramic powder 15 is charged from the charging door 17 and dispersed on the lower surface, and a fire type 19 such as charcoal or coke is charged from the charging door 17 on the ceramic powder 15. It becomes. Waste 16 is input from the waste input unit 12 and stacked on the fire type 19. Air is poured into the waste 16 by the blower pump 13 and thermal decomposition starts. The soot K generated by the thermal decomposition is sent out from the delivery pipe 18.

  The first showering tower 21 includes an activated carbon layer 23 through which the smoke K sent from the pyrolysis furnace 11 passes from below, a bubble generator 30 that showers water in which an oxidized substance is mixed into the activated carbon layer 23, and a bubble The storage tank 24 is configured to store water that is showered from the generator 30 and passes through the activated carbon layer 23.

The bubble generator 30 mixes the oxidizing substance generated in the streamer generator 32 sent by the sending pipe 33 and the sent water, and showers the oxidized substance mixed water in which the oxidizing substance becomes a bubble into the activated carbon layer 23. To do. Oxidized substance-mixed water can be converted into a radical substance that decomposes harmful substances by passing through the activated carbon layer 23. Oxidized substance-mixed water passes through the activated carbon layer 23, and smoke K passes through the activated carbon layer 23 from below, so that harmful substances with bad odor can be decomposed. The water that has passed through the activated carbon layer 23 is stored in the storage tank 24.
The water stored in the storage tank 24 is sent to the bubble generator 30 through the delivery pipe 26 by the submersible pump 25 installed in the storage tank 24, circulates in the first showering tower 21, and further contains harmful substances. It can be disassembled.
Accordingly, the water stored in the storage tank 24 circulates in the first showering tower 21, and the smoke K sent from the delivery pipe 18 passes through the activated carbon layer 23 from below and is sent out from the connecting pipe 42. The effect can be further enhanced.
The soot K remaining in the first shower ring tower 21 is sent to the second shower ring tower 41 through the connecting pipe 42.

  The second shower ring tower 41 is supplied with the suction blower 45 for sucking the smoke K, the connecting pipe 42 to which the smoke K from the pyrolysis furnace 11 is sent, and the oxidizing substance sent by the sending pipe 33. Passes through the activated carbon layer 43, the bubble generator 50 that sends the water mixed with water to the second showering tower 41, the activated carbon layer 43 provided inside the water mixed with the oxidizing substance from the bubble generator 50, and the activated carbon layer 43 And a storage tank 24 for storing the collected water. The storage tank 24 stores water that passes through the activated carbon layer 23 and also stores water that passes through the activated carbon layer 43.

In the second shower ring tower 41, the smoke K sent from the connecting pipe 42 by the suction blower 45 passes through the slit 47 and is sent below the activated carbon layer 43 and passes above the lower activated carbon layer 43.
The water stored in the storage tank 24 is again sent to the bubble generator 30 through the delivery pipe 26 by the submersible pump 25 installed in the storage tank 24 and circulates in the first showering tower 21. 50 is also circulated through the second shower ring tower 41 to further enhance the harmful substance decomposition effect.

The soot treatment device 61 includes a storage tank portion 62 provided below and storing activated carbon 64 and the soot K sent from the second showering tower 41 into the water from the storage tank 62 as a bubble. The bubble generator 63, activated carbon accumulation tank 66 that passes through the activated carbon 65 that is bubbled water from the bubble generator 63 and is stored therein, and the oxidant generated in the streamer generator 32 are stored in the storage tank 62. A second bubble generator 67 mixed in the water as a bubble, and a pump 68 for sending water from the storage tank 62 to the first bubble generator 63 and the second bubble generator 67. .
In the soot treatment device 61, the soot K sent from the second showering tower 41 is mixed as bubbles into the water from the storage tank 62 provided by the bubble generator 63, and the bubble-mixed water from the bubble generator 63 is mixed. Passes through the activated carbon 65 accumulated in the activated carbon accumulation tank 66 and is separated into a liquid and a gas, the gas is discharged to the outside through the discharge pipe 71, and the liquid is returned to the storage tank 62 as indicated by an arrow H. Further, water mixed with bubbles from the second bubble generator 67 also passes through the activated carbon 65 accumulated in the activated carbon accumulation tank 66 to be separated into liquid and gas, the gas is discharged to the outside, and the liquid is stored in the storage tank. Return to 62.
The activated carbon storage tank 66 is provided with a cylindrical net 69 into which bubble-mixed water from the bubble generators 63 and 67 is sent to the inside and sent to the outside.

As described above, the high-efficiency pyrolysis furnace apparatus 10 according to the embodiment of the present invention generates toxic gas soot when the organic material is carbonized and burned by the radiant heat of ceramics, and the suction blower 45 sucks the first. The shower ring tower 21 and the second shower ring tower 41 are sent. In the first shower ring tower 21 and the second shower ring tower 41, water in which an oxidizing substance is mixed as bubbles on the activated carbon layers 23 and 43 is sprayed by the bubble generators 30 and 50.
Smoke is sucked by the suction blower 45, the smoke is directed upward, the sprayed water falls downward, the smoke smoke from below and the oxidized mixed water falling from above collide, and bubbling occurs on the upper surfaces of the activated carbon layers 23, 43. Occur. As a result, the smoke and the oxidizing substance are mixed, and a part flows through the activated carbon layers 23 and 43 downward. When passing through the activated carbon layers 23 and 43, the contained oxidizing substance is changed into a radical substance, and various substances contained in the smoke are rendered harmless.
Also in the soot treatment device 61, the soot K sent from the second showering tower 41 is mixed as bubbles into the water from the storage tank 62 provided below by the bubble generator 63, and the bubbles from the bubble generators 63 and 67 are mixed. The water passes through the activated carbon 65 accumulated in the activated carbon accumulation tank 66 and is separated into liquid and gas. The gas is discharged to the outside, and various substances are made harmless.

Therefore, the smoke K sent from the pyrolysis furnace 11 is bubbled on the upper surfaces of the activated carbon layers 23 and 43 in the process of the first shower ring tower 21 and the second shower ring tower 41, and the smoke K is activated. The carbon layers 23 and 43 are inserted from below to above.
Due to the occurrence of the bubbling, soot was mixed with the oxidant, and harmful substances and odors in the soot were removed and decolorized, enabling high-efficiency processing.
Further, in the soot treatment device 61, the soot from the second showering tower 41 is sent from the first bubble generator 63, and the oxidant from the streamer generator 32 is sent from the second bubble generator 67. In the activated carbon storage tank 66, soot and oxidants are mixed and discharged to the outside so that harmful substances and bad odors in the soot can be removed and decolorized.

In addition, the 1st shower ring tower 21 and the 2nd shower ring tower 41 share the storage tank 24, and are also a composite type shower ring tower.
In addition, the first showering tower 21 of the high-efficiency pyrolysis furnace apparatus 10 is provided with the activated carbon layer 23, but a plurality of the activated carbon layers 23 can be provided, and the second showering tower 41 is also provided with the activated carbon layer 43. However, a plurality can be provided.
In addition, a plurality of first shower ring towers 21 and second shower ring towers 41 may be provided in series as necessary. The first shower ring tower 21 and the second shower ring tower 41 may be provided. A plurality of composite shower ring towers can be provided in series.
In addition, although bubble generators 30 and 50 are used to generate bubbles, microbubble generators that generate microbubbles can also be used to more effectively remove harmful substances, bad odors, and the like. Can do.
Furthermore, the high-efficiency pyrolysis furnace apparatus 10 of the present invention can also be applied to the removal of waste from waste and the removal of various radioactivity.

FIG. 2 is a longitudinal sectional view of a bubble generator installed in the high efficiency pyrolysis furnace apparatus of the embodiment of the present invention.
As shown in FIG. 2, the bubble generator 30 is a cylindrical case in which the smoke K gas fed from one side surface and the liquid W fed from the outer peripheral surface flow along the central axis. 31, a circular opening 36 a formed on one side surface of which is a bottom surface, a conical flow passage 36 formed in the cylindrical case 31, and a conical flow passage 36 connected to and fed in. A cylindrical flow passage 37 in which the gas and the liquid W fed from the side surface flow and are sent out from the circular opening 37a on the other side surface, and a cylindrical flow passage in which the liquid W fed from the outer peripheral surface side flows. There is provided a liquid mixing part 35 that flows into the liquid 36 from the liquid mixing hole 35c and flows into the gas introduced from one side surface.
Since the bubble generator 30 sends in gas from one side surface and feeds in liquid from the outer peripheral surface side, it is possible to generate bubbles accurately.
The bubble generators 50, 63, and 67 have the same configuration.
In addition, although the bubble generators 30, 50, 63, and 67 are used to generate bubbles, microbubbles can also be generated.

  The present invention can be widely used for various types of waste and can also be widely used as a deodorizing apparatus.

DESCRIPTION OF SYMBOLS 10 High-efficiency pyrolysis furnace apparatus 11 Pyrolysis furnace 14 Opening / closing lid 16 Waste 21 First shower ring tower 23, 43 Activated carbon layer 24 Reservoir 30, 50 Bubble generator 41 Second shower ring tower 45 Suction blower 61 Smoke Treatment device 66 Activated carbon storage tank

Claims (5)

  From a bubble generator, a pyrolysis furnace that stacks the thrown-in ceramic powder and the thrown-in waste into the fire type, supplies air to the waste, pyrolyzes the waste, and discharges soot and smoke Shown from above the activated carbon layer formed inside the oxidant-containing water to be supplied, and sends the smoke sent from the pyrolysis furnace to the activated carbon layer from below, and sends it through the activated carbon layer. A high-efficiency pyrolysis furnace device comprising a shower ring tower for storing substance-mixed water in a storage tank provided below.   From a bubble generator, a pyrolysis furnace that stacks the thrown-in ceramic powder and the thrown-in waste into the fire type, supplies air to the waste, pyrolyzes the waste, and discharges soot and smoke Shown from above the activated carbon layer formed inside the oxidant mixed water to be supplied, and sends the smoke sent from the pyrolysis furnace through the activated carbon layer from below, and sends the oxidized smoke through the activated carbon layer. The substance-mixed water is stored in a storage tank provided below, and the oxidized substance-mixed water supplied from the bubble generator is showered from above the activated carbon layer formed therein, and the smoke sent out is sent to the activated carbon layer. A high-efficiency pyrolysis furnace apparatus comprising: a combined shower ring tower that passes through and is sent from below and stores the oxidized substance-mixed water that has passed through the activated carbon layer in the storage tank   From a bubble generator, a pyrolysis furnace that stacks the thrown-in ceramic powder and the thrown-in waste into the fire type, supplies air to the waste, pyrolyzes the waste, and discharges soot and smoke Shown from above the activated carbon layer formed inside the oxidant mixed water to be supplied, and sends the smoke sent from the pyrolysis furnace through the activated carbon layer from below, and sends the oxidized smoke through the activated carbon layer. The substance-mixed water is stored in a storage tank provided below, and the oxidized substance-mixed water supplied from the bubble generator is showered from above the activated carbon layer formed therein, and the smoke sent out is sent to the activated carbon layer. Passed from below and sent out, and sent from the combined shower ring tower that stores the oxidized material mixed water that has passed through the activated carbon layer in the storage tank, and the combined shower ring tower The soot is mixed as a bubble into water from a storage tank provided below by a bubble generator, and the bubble-mixed water from the bubble generator passes through activated carbon accumulated in an activated carbon accumulation tank to pass liquid and gas. A high-efficiency pyrolysis furnace device comprising: a smoke treatment device that is separated into a gas, the gas is discharged to the outside, and the liquid is returned to the storage tank.   The bubble generator is formed on a cylindrical case in which a gas fed from one side and a liquid fed from an outer peripheral surface flow along a central axis, and the one side. A conical flow passage formed in the cylindrical case with a circular opening serving as a bottom surface, and the fed gas and the fed liquid connected to the conical flow passage. A cylindrical flow passage that flows and is fed out from the other side surface, and a liquid fed from the outer peripheral surface side flows into the cylindrical flow passage and is mixed into the gas fed from the one side surface side. The sludge treatment apparatus according to any one of claims 1 to 3, wherein a bubble generator including a liquid mixing unit is used.   4. The sludge treatment apparatus according to claim 3, wherein the activated carbon storage tank is provided with a cylindrical net through which the bubble-mixed water from the bubble generator is sent to the inside and sent to the outside.

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