JP2000336378A - Method for treating waste and pyrolizer - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for treating waste, capable of making products harmless and further decreasing air leak amount and air amount carried by associated gas as much as possible when wastes containing various harmful substances are subjected to pyrolyzing treatment. SOLUTION: A waste treating system comprises a pretreating system 11, a pyrolyzing oven 12, a gas reformer 13, a gas-purifying device 14 and a gas reformer 13. This method for treating wastes comprises mixing an organic halogen compound into a pyrolyzed gas, reacting the halogen compound with NH3 and solidifying NH3 as halogen ammonium cyanide in a gas reforming step using the gas reformer 13 of the waste treating system.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to the treatment of unsorted or untreated solid or liquid domestic and special wastes (hereinafter referred to as general wastes) and industrial wastes containing various pollutants. The present invention relates to a waste treatment method and a pyrolysis apparatus used for obtaining a recyclable waste treatment product.

[0002]

2. Description of the Related Art Conventionally, as a system for treating various kinds of wastes such as general wastes or industrial wastes, for example, wastes contaminated with harmful substances as described in JP-B-8-24904, etc. 2. Description of the Related Art A system for thermally processing an object or the like is known. This method employs a process in which waste is pulverized with a shredder, pyrolyzed in a pyrolysis furnace under high heat, and then recovered by a gas reforming melting gasifier to recover metals, glassy substances, etc. are doing. The secondary substance discharged from this processing step is divided into a substance used as an energy source in the processing step and a substance discharged from the processing step. In this processing method, a processing method and apparatus capable of producing and processing a recyclable substance with minimum energy have been proposed.

[0003] In such a waste treatment system by thermal decomposition, an externally heated rotary kiln that heats a rotary drum from the outside is generally used as a thermal decomposition furnace. FIG. 9 shows an example of a pyrolysis furnace using this externally heated rotary kiln. The waste is continuously supplied into the rotary drum 2 by the waste supply mechanism 1. The rotating drum 2 is supported at two points by rollers 3, and is rotated at a low speed by a rotation driving mechanism 4. The central portion of the rotating drum 2 is installed inside the combustion chamber 5, and the waste in the rotating drum 2 is heated to a high temperature by the combustion gas from the burner 6 attached to the combustion chamber 5. Further, the exhaust gas generated in the combustion chamber 5 is discharged outside the combustion chamber through the exhaust gas duct 7.

The waste is thermally decomposed by being heated to a high temperature inside the rotating drum 2. At this time, a pyrolysis gas and a pyrolysis residue are generated. Thereafter, both are separated by a hood 8 which communicates with the outlet of the rotating drum 2, one as a gas and the other as a solid. A rotary seal device 9 is provided at the connection between the rotating part and the stationary part, and separates the inside and the outside of the rotating drum 2. The inside of the rotating drum 2 is usually set to a pressure lower than the atmospheric pressure, and the two rotating sealing devices 9 prevent the pyrolysis gas from flowing out.

[0005]

In the above-described processing step using the conventional gas reforming melting gasifier, NH ₃ unavoidably generated in the pyrolysis step reacts with the organic pyrolysis gas to produce highly toxic hydrogen cyanide. Generate. No specific method is disclosed for preventing or removing hydrogen cyanide in this step.

Further, the thermal decomposition reaction in this treatment step must be performed in an atmosphere from which oxygen has been completely removed, and the thermal decomposition furnace using a rotary kiln must be sufficiently shielded from air. This is because if the air is not sufficiently shut off, a combustion reaction may occur locally inside the rotating drum 2 due to oxygen contained in the air, resulting in insufficient thermal decomposition. For this reason, high performance is required for the rotary sealing device 9 of the rotary drum 2, but it is difficult to completely seal the rotary drum 2 having a large diameter and a large displacement due to thermal expansion. Is allowed.

[0007] The types of waste to be treated are extremely diverse, the heating temperature is not uniform, and it is generally difficult to quantitatively determine the upper limit of the allowable amount of leakage. It is a bottleneck in realizing the processing.

[0008] It is an object of the present invention to detoxify products when pyrolysis of waste containing various harmful substances, and to further reduce the amount of air leak and the amount of air carried by entrainment as much as possible. An object of the present invention is to provide a material processing method and a thermal decomposition device.

[0009]

In order to achieve the above object, a waste treatment method according to the present invention comprises the steps of: crushing waste to obtain a treated object having a uniform size; Pyrolyzing to generate a pyrolysis gas and a pyrolysis residue;
A step of reforming the obtained pyrolysis gas to a flammable gas, a step of gasifying and melting the obtained pyrolysis residue to produce a flammable gas and a molten slag, and a step of cleaning the obtained flammable gas. In a waste disposal method comprising a step of purifying into a combustible gas, an organic halogen compound is added to the pyrolysis gas in the step of reforming the pyrolysis gas, and simultaneously reacted.

In the above-mentioned waste treatment method, an ammonium halide salt and a radical are generated by adding an organic halogen compound to the pyrolysis gas and simultaneously reacting the same in the pyrolysis gas reforming step. As a result, NH ₃ is fixed as a salt, and it is possible to prevent the reaction with other organic compounds from proceeding to generate hydrogen cyanide. The radical generated by this reaction has the function of further promoting the reforming action.

The organic halogen compound is preferably a halogen-substituted product of a chain hydrocarbon, a fluorine-substituted product of a chain hydrocarbon, a fluorine-substituted product of an alkane, a fluorine-substituted product of methane or ethane, a fluorine-containing product of a chain hydrocarbon. It is any of chlorine substituted products, alkane fluorine and chlorine substituted products, and chlorofluorocarbons.

Preferably, the chlorofluorocarbon is CFC-11 (CCl ₃ F) or CFC-12 (CFC ₃ F).
Cl ₂ F _2), Freon -21 (CHCl ₂ F), Freon -
22 (CHClF ₂ ), Freon-112 (C ₂ Cl
₄ F ₂ ), CFC-113 (C ₂ Cl ₃ F ₃ ), CFC-1
_{14 (C 2 Cl 2 F 4} ), freon -115 (C ₂ ClF ₅₎
Is one of

In addition, the chlorofluorocarbon is preferably used as a refrigerant and is a recovered aerosol which is used as a propellant and is used as a propellant.

Further, the waste treatment method of the present invention comprises a step of crushing the waste to obtain a treated object having a uniform size, and a step of thermally decomposing the obtained treated object to generate a pyrolysis gas and a pyrolysis residue. And a step of reforming the obtained pyrolysis gas to a flammable gas, and a step of gasifying and melting the obtained pyrolysis residue to generate a flammable gas and molten slag, and A waste treatment method comprising a step of purifying a combustible gas into a clean combustible gas, characterized in that urethane foam foamed with an organic halogen compound is simultaneously decomposed in a thermal decomposition step of the object to be treated. is there.

In the above-mentioned waste treatment method, a gas of an organic halogen compound is generated by simultaneously decomposing urethane foam foamed with an organic halogen compound in a thermal decomposition step of an object to be treated, and a pyrolysis gas and this gas are generated. And mix. Then, in the next reforming step, NH ₃ reacts with the organic halogen compound to generate an ammonium halide salt and a radical. As a result, NH ₃ is fixed as a salt, and generation of hydrogen cyanide can be prevented.

The urethane foam desirably uses urethane foam insulation from a variety of products as waste.

Further, the pyrolysis apparatus of the present invention is provided so that the central region faces the combustion chamber, and a rotary drum rotatably supported by rollers near both ends, and is provided in communication with an inlet of the rotary drum, and is provided with a cover. A pyrolysis apparatus comprising: a waste supply mechanism that feeds a processed product to a rotary drum; and a hood provided in communication with an outlet of the rotary drum and that collects a pyrolysis gas and a pyrolysis residue generated in the rotary drum. And an exhaust gas supply device for supplying the exhaust gas from the combustion chamber as a seal gas to the seal device of the rotary drum.

In the pyrolysis apparatus having the above structure, the surrounding air can be prevented from flowing into the rotary drum from the rotary seal device, and the amount of oxygen increases due to air leak, and the local combustion in the rotary drum can be prevented. Can be avoided.

The pyrolysis apparatus of the present invention is provided with a rotating drum having a central region facing the combustion chamber and rotatably supported near both ends by rollers, and provided in communication with an inlet of the rotating drum. A pyrolysis apparatus comprising: a waste supply mechanism that feeds a processed product to a rotary drum; and a hood provided in communication with an outlet of the rotary drum and that collects a pyrolysis gas and a pyrolysis residue generated in the rotary drum. And an exhaust gas supply device for supplying exhaust gas from the combustion chamber to an inlet duct of a waste supply mechanism as a gas for replacing waste accompanying air.

In the pyrolysis apparatus having the above-described structure, when the object to be processed is sent to the rotating drum, air can be prevented from being carried along with the object to be processed at the same time, and the amount of air carried to the rotating drum can be reduced. The drastic reduction makes it possible to almost completely eliminate the occurrence of local combustion.

The exhaust gas supply device for supplying the exhaust gas has a nitrogen gas supply device for supplying nitrogen gas, a steam supply device for supplying steam, and an inert gas supply device for supplying an inert gas for the purpose of obtaining more desirable functions. It is possible to substitute

Further, desirably, nitrogen gas, water vapor,
In order to enhance the effect of the replacement with the inert gas, a vacuum pump connected to the inlet duct of the waste treatment mechanism is provided.

The pyrolysis apparatus of the present invention has a central region facing the combustion chamber, and has a rotary drum rotatably supported by rollers near both ends, and is provided in communication with an inlet of the rotary drum, and is provided with a cover. A pyrolysis apparatus comprising: a waste supply mechanism that feeds a processed product to a rotary drum; and a hood provided in communication with an outlet of the rotary drum and that collects a pyrolysis gas and a pyrolysis residue generated in the rotary drum. An oxygen concentration meter that detects the oxygen concentration in the rotating drum,
A monitoring device comprising an abnormality determination device that calculates a difference between the oxygen concentration based on the supplied oxygen concentration signal and the reference value and performs an abnormality determination by comparing the difference with an allowable value.

In the pyrolysis apparatus having the above structure, the specific gas concentration in the rotating drum is detected, and the presence or absence of an abnormality is determined based on the detected concentration. When there is an abnormality, the operator is notified of the abnormality of the gas concentration. It is possible to eliminate the danger of continued operation that impairs the soundness of the pyrolysis device.

This monitoring device may be provided with a nitrogen concentration meter for detecting a nitrogen concentration and a carbon dioxide concentration meter for detecting a carbon dioxide concentration, instead of the oximeter for detecting the oxygen concentration.

[0026]

DESCRIPTION OF THE PREFERRED EMBODIMENTS (First Embodiment) A first embodiment of the present invention will be described with reference to FIG. The waste treatment system to which the method of the present invention is applied includes a pretreatment system 11, a pyrolysis furnace 12, a gas reformer 13, a gas purifier 14, and a gasification and melting furnace 15. In the pretreatment step, waste is crushed into a uniform size suitable for treatment in the pretreatment system 11 and dried to remove water. In the thermal decomposition step, the object to be processed, which has been made uniform in shape through a pretreatment step in the thermal decomposition furnace 12, is heated to 450 to 650 ° C. and decomposed into a thermal decomposition gas and a thermal decomposition residue. In the pyrolysis process using the pyrolysis furnace 12, the inflow of air is shut off to prevent combustion.

Further, the gas reforming step is performed by the gas reforming device 13.
In the above, the pyrolysis gas is reformed to a flammable gas containing hydrogen, carbon monoxide, and hydrocarbon at a high temperature of 1000 ° C. or more. In the gas purification step in the gas purification device 14, impurities contained in the combustible gas are removed to purify the gas into a clean combustible gas. In the process for the pyrolysis residue, the pyrolysis residue is heated to 1300 ° C. or more in the gasification and melting furnace 15 and decomposed into combustible gas containing carbon monoxide and molten slag. The combustible gas generated here is purified together with the combustible gas from the gas reformer 13 into a clean combustible gas in a gas purification step by the gas purifier.

In the present embodiment, an organic halogen compound is mixed in a pyrolysis gas and reacted with NH _{3 in} a gas reforming step using the gas reformer 13 of the waste treatment system. At this time, when the reaction proceeds, NH ₃ is fixed as an ammonium halide salt. Thereby, NH
It is possible to suppress the reaction between ₃ and the hydrocarbon to generate hydrogen cyanide.

(Second to Eighth Embodiments) Second to eighth embodiments of the present invention will be described. In each embodiment, the same processes, that is, a pretreatment process, a pyrolysis process, a gas reforming process, a gas purification process, and a gasification melting process are performed using the same waste treatment system as in the first embodiment. In the gas reforming step using the gas reformer 13 among the above steps, the following organic halogen compound is mixed into the pyrolysis gas and reacted with NH ₃ .

Second Embodiment-Halogen Substituted Chain Hydrocarbon Third Embodiment-Fluorine Substituted Chain Hydrocarbon Fourth Embodiment-Fluorine Substituted Alkane Fifth Embodiment Form-Fluorine-substituted product of methane and ethane Sixth Embodiment-Substituted product of fluorine and chlorine of chain hydrocarbon Seventh Embodiment-Substituted product of fluorine and chlorine of alkane Eighth embodiment-chloro Fluorocarbons

As the reaction proceeds, NH ₃ is fixed as an ammonium halide salt, ammonium chloride or ammonium fluoride. As a result, it is possible to suppress the reaction between NH ₃ and the hydrocarbon to generate hydrogen cyanide.

(Ninth to Sixteenth Embodiments) Ninth to sixteenth embodiments of the present invention will be described. In each embodiment, the same processes, that is, a pretreatment process, a pyrolysis process, a gas reforming process, a gas purification process, and a gasification melting process are performed using the same waste treatment system as in the first embodiment. . In the gas reforming step using the gas reforming apparatus, the following chlorofluorocarbon is mixed into the pyrolysis gas and reacted with NH ₃ .

Ninth embodiment-Freon-11 (CCl ₃ F) Tenth embodiment-Freon-12 (CCl ₂ F ₂ ) Eleventh embodiment-Freon-21 (CHCl ₂ F) embodiment 12 - Freon -22 (CHClF ₂₎ thirteenth embodiment - Freon _{-112 (C 2 Cl 4 F 2} ) 14th embodiment - Freon _{-113 (C 2 Cl 3 F 3} ) the 15 embodiment of - chlorofluorocarbons _{-114 (C 2 Cl 2 F 4} ) 16th embodiment - Freon -115 (C ₂ ClF ₅₎

As the reaction proceeds, NH ₃ is fixed as ammonium chloride or ammonium fluoride. This makes it possible to suppress the reaction between NH ₃ and the hydrocarbon and the generation of hydrogen cyanide.

(Seventeenth and eighteenth embodiments) Seventeenth and eighteenth embodiments of the present invention will be described. In each embodiment, the same processes, that is, a pretreatment process, a pyrolysis process, a gas reforming process, a gas purification process, and a gasification melting process are performed using the same waste treatment system as in the first embodiment. . In the gas reforming step using the gas reformer 13 among the above steps, the following chlorofluorocarbon is mixed into the pyrolysis gas and reacted with NH ₃ .

Seventeenth Embodiment-Freon Used Once as Refrigerant and Recovered Afterwards Eighteenth Embodiment-Aerosol Used Once as Propellant in Spray Cans and Recovered Afterwards

As the reaction proceeds, NH ₃ is fixed as an ammonium halide salt. Thereby, it is possible to suppress the reaction between NH ₃ and the hydrocarbon to generate hydrogen cyanide.

(Nineteenth and Twentieth Embodiments) The nineteenth and twentieth embodiments of the present invention will be described with reference to FIGS.
This will be described with reference to FIG. In FIG. 2, a waste treatment system to which the method of the present invention is applied has the same configuration as that of the first embodiment. That is, it comprises a pretreatment system 11, a pyrolysis furnace 12, a gas reformer 13, a gas purifier 14, and a gasification and melting furnace 15.

In the nineteenth embodiment, urethane foam foamed with an organic halogen compound is simultaneously decomposed in a pyrolysis step using the pyrolysis furnace 12 of this waste treatment system.

As shown in FIG. 3, the twentieth embodiment is used as a heat insulating material for a product such as a refrigerator in a pyrolysis process using a pyrolysis furnace 12 of a waste treatment system, and thereafter recovered. At the same time, the urethane foam insulation is decomposed.

As the decomposition proceeds, a gas of an organic halogen compound is generated, and this gas is mixed with the pyrolysis gas. This pyrolysis gas flows into the gas reformer 13, where NH _{3 in} the gas reacts with the organic halogen compound and is fixed as an ammonium halide salt. This makes it possible to suppress the reaction between NH ₃ and the hydrocarbon and the generation of hydrogen cyanide.

(Twenty-First Embodiment) A twenty-first embodiment of the present invention will be described with reference to FIG. The pyrolysis device is composed of an externally heated rotary kiln. The main configuration of this device is the same as that described above. The exhaust gas duct 7 and the rotary sealing device 9 are respectively connected by an exhaust gas system 16. The exhaust gas system 16 is provided with an exhaust gas supply device 17. The exhaust gas supply device 17 extracts the exhaust gas flowing through the exhaust gas duct 7 and supplies it to the rotary seal device 9 while maintaining an appropriate temperature and pressure. In this figure, the gas cooling device,
It is equipped with a flow control device, a pressure control device, and a blower.

This embodiment has the above-described structure, and high-temperature exhaust gas flows in the exhaust gas duct 7 during operation. When the exhaust gas supply device 17 starts, the exhaust gas from the exhaust gas duct 7 flows to the exhaust gas supply device 17 and is cooled by the gas cooling device. The pressure of the exhaust gas is adjusted by a pressure adjusting device, and the exhaust gas is sent to the rotary seal device 9 as a seal gas by a blower. The sealing gas seals a small gap between the rotating part and the stationary part. Thereby, it is possible to prevent the surrounding air from flowing into the rotary drum 2 from the rotary seal device 9. Since the exhaust gas contains almost no oxygen, it does not have any effect even if it flows into the rotating drum 2.

As described above, in this embodiment, it is possible to avoid the occurrence of local combustion due to an increase in the amount of oxygen in the rotating drum 2 due to air leakage.

(Twenty-second Embodiment) A twenty-second embodiment of the present invention will be described with reference to FIG. The waste supply mechanism 1 is provided with two gate valves 18 at the inlet duct.
An exhaust gas system 19 that connects the other end to the exhaust gas duct 7 is connected to the inlet duct between the two gate valves 18, and an exhaust gas supply device 20 is provided on this path. This exhaust gas supply device 20 is provided with a gas cooling device, a flow control device, a pressure control device, and a blower similar to those of the twenty-first embodiment.

This embodiment has the above-described configuration, and high-temperature exhaust gas flows through the exhaust gas duct 7 during operation. When the exhaust gas supply device 20 starts, the exhaust gas from the exhaust gas duct 7 flows into the exhaust gas supply device 20, is cooled by the gas cooling device, and is adjusted in pressure by the pressure adjusting device. This exhaust gas is pressurized by the blower and blows out into the inlet duct of the waste supply mechanism 1. At this time, two gate valves 18
Is closed, the air is replaced by the exhaust gas around the workpiece in the inlet duct.

Thus, when the object to be processed is sent to the rotary drum 2, it is possible to prevent air from being simultaneously carried along with the object to be processed. The amount of oxygen contained in the exhaust gas is extremely small, and the amount of oxygen does not increase even if the exhaust gas is sent to the rotary drum 2 accompanying the processing object.

As described above, in the present embodiment, the amount of air carried along with the rotating drum 2 can be drastically reduced, and the occurrence of local combustion in the rotating drum 2 can be substantially eliminated. Will be possible.

(Twenty-third Embodiment) A twenty-third embodiment of the present invention will be described with reference to FIG. This pyrolysis device includes a nitrogen gas supply device 21. This nitrogen gas supply device 21 is provided with two gate valves 18 of the waste supply mechanism 1.
Is connected to the inlet duct by a gas system 22.

The present embodiment has the above-described structure, and when introducing an object to be treated into a thermal decomposition apparatus, two gate valves 1
8 is fully opened. The workpiece enters the inlet duct by opening the valve 18. Thereafter, both valves 18 are fully closed. Thereafter, the nitrogen gas supply main valve (not shown) of the nitrogen gas supply device 21 is fully opened. At this time, the nitrogen gas kept at a constant pressure is blown into the inlet duct, and the air around the workpiece is replaced with the nitrogen gas. Thus, when the object to be processed is sent to the rotating drum, it is possible to prevent air from being simultaneously carried along with the object to be processed.

In this embodiment, steam may be used instead of nitrogen gas as the replacement gas. Further, an inert gas containing no oxygen or a mixed gas thereof may be used. In this case, the thermal decomposition device includes a steam supply device and an inert gas supply device instead of the nitrogen gas supply device 21.

As described above, in this embodiment, the amount of air conveyed to the rotary drum 2 can be drastically reduced, and the occurrence of local combustion in the rotary drum 2 can be substantially eliminated. Will be possible.

(24th Embodiment) A 24th embodiment of the present invention will be described with reference to FIG. As in the case of the twenty-third embodiment, this thermal decomposition device includes a nitrogen gas supply device 21. The nitrogen gas supply device 21 is connected to an inlet duct between the two gate valves 18 of the waste supply mechanism 1 by a gas system 22. Furthermore, the vacuum pump 2 communicating with the inlet duct between the two gated valves 18
3

The present embodiment has the above-described structure, and when introducing an object to be treated into a thermal decomposition apparatus, two gate valves 1
8 is fully opened. The workpiece enters the inlet duct by opening the valve 18. Thereafter, both valves 18 are fully closed. After the introduction of the object to be processed, the vacuum pump 23 is started to extract the air in the inlet duct. When the degree of vacuum rises, the operation of the vacuum pump 23 is stopped. Thereafter, the nitrogen gas supply main valve of the nitrogen gas supply device 21 is fully opened. At this time, the nitrogen gas kept at a constant pressure is blown into the inlet duct, and the air around the workpiece is replaced with the nitrogen gas. Thus, when the object to be processed is sent to the rotating drum, it is possible to prevent air from being simultaneously carried along with the object to be processed.

In the present embodiment, an inert gas containing no water vapor or oxygen or a mixed gas of an inert gas may be used instead of the nitrogen gas as the replacement gas. In this case, the thermal decomposition device includes a steam supply device and an inert gas supply device instead of the nitrogen gas supply device 21.

As described above, in this embodiment, the amount of air conveyed to the rotating drum 2 can be reduced to almost zero, and local combustion in the rotating drum 2 can be eliminated. Can be.

(Twenty-Fifth Embodiment) A twenty-fifth embodiment of the present invention will be described with reference to FIG. This pyrolysis device includes a monitoring device 24 that determines the presence or absence of an abnormality based on the oxygen concentration in the rotating drum 2. The monitoring device 24 includes an oxygen concentration meter 25 for detecting the oxygen concentration in the rotating drum 2.
And an abnormality determination device 26 that determines whether or not it is normal based on the detected oxygen concentration. Oxygen concentration meter 25
Consists of, for example, a zirconia oxygen analyzer that can be inserted directly into a high-temperature gas. The zirconia oxygen analyzer has electrodes attached to both sides of a zirconia element to detect the generation of electromotive force due to oxygen ion conduction, and uses an oxygen analyzer used for combustion control.

The present embodiment has the above-described configuration. During operation, for example, if the amount of leaked air increases for some reason and the oxygen concentration in the rotating drum 2 increases significantly, the oxygen concentration meter 25 detects the oxygen concentration at this time. I do. The oxygen concentration signal obtained by this detection is transmitted to the abnormality determination device 26, and the difference from the reference value is calculated according to an algorithm. The increased oxygen concentration has a large difference from the reference value, and is determined to be abnormal by comparison with the allowable value. At this time, the abnormality determination device 26 outputs a warning notifying the oxygen concentration abnormality.

On the other hand, when the amount of air flowing in decreases, an oxygen concentration signal indicating a sufficiently reduced oxygen concentration is given to the abnormality determination device 26, and the difference from the reference value is calculated by calculation. As the oxygen concentration decreases, the difference from the reference value decreases, and the oxygen concentration falls within the allowable range. At this time, no warning command is output from the abnormality determination device 26 due to the normality determination.

Thus, by detecting an abnormal increase in the oxygen concentration in the rotary drum 2 and performing an abnormality determination based on the detected abnormality to notify the abnormality, it is possible to immediately take measures such as stopping the thermal decomposition apparatus. . This makes it possible to avoid a situation in which the operation that impairs the soundness continues for a long time, such as the occurrence of local combustion, without noticing the abnormality in the oxygen concentration.

The rotary drum 2 according to the present embodiment
The concentration value detected by the monitoring device 24 may be a nitrogen concentration instead of oxygen. Alternatively, the concentration of carbon dioxide may be detected. In this case, the monitoring device 24 includes a nitrogen concentration meter and a carbon gas concentration meter instead of the oxygen concentration meter 25.

As described above, in this embodiment, the specific gas concentration in the rotating drum 2 is detected, and based on the detected gas concentration, the presence or absence of an abnormality is determined. When there is an abnormality, the operator is notified of the abnormality of the gas concentration. It is possible to eliminate the danger of continued operation that impairs the soundness of the pyrolysis device.

[0063]

According to the waste treatment method of the present invention, NH ₃ is fixed as a salt in the step of reforming the pyrolysis gas.
The generation of hydrogen cyanide can be prevented, and the detoxification of the product makes it possible to enhance safety in waste treatment.

Further, in the thermal decomposition apparatus of the present invention, it is possible to avoid an increase in the amount of oxygen due to air leakage, or to prevent air from being carried along with the object to be processed. Therefore, it is possible to reliably suppress the occurrence of local combustion in the rotating drum.

[Brief description of the drawings]

FIG. 1 is a configuration diagram showing a waste treatment system used in first to eighteenth embodiments of the present invention.

FIG. 2 is a configuration diagram showing a waste treatment system used in a nineteenth embodiment of the present invention.

FIG. 3 is a configuration diagram showing a waste treatment system used in a twentieth embodiment of the present invention.

FIG. 4 is a configuration diagram showing a thermal decomposition apparatus according to a twenty-first embodiment of the present invention.

FIG. 5 is a configuration diagram showing a thermal decomposition device according to a twenty-second embodiment of the present invention.

FIG. 6 is a configuration diagram showing a thermal decomposition device according to a twenty-third embodiment of the present invention.

FIG. 7 is a configuration diagram showing a thermal decomposition device according to a twenty-fourth embodiment of the present invention.

FIG. 8 is a configuration diagram showing a thermal decomposition device according to a twenty-fifth embodiment of the present invention.

FIG. 9 is a configuration diagram showing an example of a conventional thermal decomposition apparatus.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Waste supply mechanism 2 Rotary drum 5 Combustion chamber 11 Pretreatment system 12 Pyrolysis furnace 13 Gas reformer 14 Gas purification device 15 Gasification and melting furnace 17, 20 Exhaust gas supply device 21 Nitrogen gas supply device

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) F23G 5/033 ZAB F23G 5/44 ZABZ 5/20 ZAB B01J 19/00 301E 5/44 ZAB B09B 3/00 ZAB // B01J 19/00 301 302E 302F (72) Inventor Tomohiro Todoroki 8 Shinsugita-cho, Isogo-ku, Yokohama-shi, Kanagawa Prefecture F-term in Toshiba Yokohama Office 3K061 GA05 KA02 KA12 KA15 3K065 AA07 AB03 AC01 AC05 BA05 CA02 CA11 HA02 4D004 AA09 AA46 AB05 BA03 CA04 CA27 CA29 CB09 CC01 CC15 DA01 DA10 4G075 AA03 BA05 CA02 CA57 DA01 4H060 AA01 AA02 BB03 BB21 CC18 DD21 FF18

Claims (29)

[Claims] 1. A step of crushing waste to obtain a treated object having a uniform size, a step of thermally decomposing the obtained treated object to generate a pyrolysis gas and a pyrolysis residue. Reforming the pyrolysis gas into flammable gas, gasifying and melting the obtained pyrolysis residue to produce flammable gas and molten slag, and converting the obtained flammable gas to clean flammable gas. 1. A waste treatment method comprising the step of purifying a gas into a gas, wherein an organic halogen compound is added to the pyrolysis gas in the step of reforming the pyrolysis gas and reacted at the same time. 2. The method according to claim 1, wherein the organic halogen compound is a halogenated product of a chain hydrocarbon. 3. The method according to claim 1, wherein the organic halogen compound is a fluorine-substituted product of a chain hydrocarbon. 4. The method according to claim 1, wherein the organic halogen compound is a fluorine-substituted alkane. 5. The waste disposal method according to claim 1, wherein the organic halogen compound is a fluorine-substituted methane and ethane. 6. The method according to claim 1, wherein the organic halogen compound is a substituted product of a chain hydrocarbon with fluorine and chlorine.
Waste treatment method as described. 7. The method for treating waste according to claim 1, wherein the organic halogen compound is a substituted product of alkane with fluorine and chlorine. 8. The method according to claim 1, wherein the organic halogen compound is a chlorofluorocarbon. 9. The method according to claim 8, wherein the chlorofluorocarbon is CFC-
9. The method for treating waste according to claim 8, wherein the method is 11 (CCl ₃ F). 10. The method according to claim 8, wherein the chlorofluorocarbon is Freon-12 (CCl ₂ F ₂ ). 11. The method according to claim 8, wherein the chlorofluorocarbon is Freon-21 (CHCl ₂ F). 12. The method according to claim 12, wherein the chlorofluorocarbon is Freon.
-22 (CHClF _Two9. The method according to claim 8, wherein
Waste treatment method. 13. The method according to claim 8, wherein the chlorofluorocarbon is Freon-112 (C ₂ Cl ₄ F ₂ ). 14. The method according to claim 8, wherein the chlorofluorocarbon is Freon-113 (C ₂ Cl ₃ F ₃ ). 15. The method according to claim 8, wherein the chlorofluorocarbon is Freon-114 (C ₂ Cl ₂ F ₄ ). 16. The method according to claim 8, wherein the chlorofluorocarbon is Freon-115 (C ₂ ClF ₅ ). 17. The waste disposal method according to claim 8, wherein the chlorofluorocarbon is used as a refrigerant, and is a collected chlorofluorocarbon. 18. The method according to claim 8, wherein the chlorofluorocarbon is used as a propellant, and is a collected aerosol. 19. A step of crushing waste to obtain a treatment object having a uniform size, a step of thermally decomposing the treatment object to produce a pyrolysis gas and a pyrolysis residue. Reforming the pyrolysis gas into flammable gas, gasifying and melting the obtained pyrolysis residue to produce flammable gas and molten slag, and converting the obtained flammable gas to clean flammable gas. A waste treatment method comprising the step of purifying into a gas, wherein urethane foam foamed with an organic halogen compound is simultaneously decomposed in a step of thermally decomposing an object to be treated. 20. The waste disposal method according to claim 19, wherein the urethane foam is used as a product, and is used as a heat insulating material of the urethane foam collected thereafter. 21. A rotating drum having a central region facing the combustion chamber, and rotatably supported near both ends by rollers, and provided in communication with an inlet of the rotating drum, and an object to be treated is provided on the rotating drum. A pyrolysis apparatus comprising: a waste supply mechanism that feeds in; and a hood that is provided in communication with an outlet of the rotary drum and that collects a pyrolysis gas and a pyrolysis residue generated in the rotary drum. A pyrolysis apparatus, comprising: an exhaust gas supply device that supplies exhaust gas from the device as a sealing gas to a sealing device of the rotary drum. 22. A rotating drum having a central region facing the combustion chamber, and rotatably supported near both ends by rollers, and a rotating drum provided in communication with an inlet of the rotating drum. A pyrolysis apparatus comprising: a waste supply mechanism that feeds in; and a hood that is provided in communication with an outlet of the rotary drum and that collects a pyrolysis gas and a pyrolysis residue generated in the rotary drum. A pyrolysis apparatus, comprising: an exhaust gas supply device for supplying exhaust gas from a waste gas to an inlet duct of the waste supply mechanism as a replacement gas for waste accompanying air. 23. The thermal decomposition apparatus according to claim 22, wherein a nitrogen gas supply device for supplying nitrogen gas as a replacement gas is provided instead of the exhaust gas supply device. 24. The thermal decomposition apparatus according to claim 22, further comprising a steam supply device for supplying steam as a replacement gas instead of the exhaust gas supply device. 25. The thermal decomposition apparatus according to claim 22, further comprising an inert gas supply device that supplies an inert gas as a replacement gas in place of the exhaust gas supply device. 26. The apparatus according to claim 23, further comprising a vacuum pump communicating with an inlet duct of the waste treatment mechanism.
Or the thermal decomposition apparatus according to 24 or 25. 27. A rotating drum having a central region facing the combustion chamber and rotatably supported near both ends by rollers, and provided in communication with an inlet of the rotating drum. A pyrolysis apparatus comprising: a waste supply mechanism for feeding in; and a hood provided in communication with an outlet of the rotary drum, and configured to collect a pyrolysis gas and a pyrolysis residue generated in the rotary drum. An oxygen concentration meter that detects the oxygen concentration in the chamber, and a monitoring device that includes a malfunction determination device that calculates the difference between the oxygen concentration and the reference value based on the given oxygen concentration signal and performs a malfunction determination by comparing the difference with an allowable value. A pyrolysis apparatus, characterized in that 28. The thermal decomposition apparatus according to claim 27, wherein the monitoring device includes a nitrogen concentration meter for detecting a nitrogen concentration instead of the oxygen concentration meter. 29. The thermal decomposition apparatus according to claim 27, wherein the monitoring device includes a carbon dioxide gas concentration meter for detecting a carbon dioxide gas concentration instead of the oxygen concentration meter.