JP2940659B2 - Method and apparatus for treating incinerator exhaust gas - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for thermally decomposing waste gas from a furnace for incinerating waste such as garbage and sewage sludge containing chlorine-based compounds into solid fuel such as coal, dry sludge, bark and wood chips. The present invention relates to a method and an apparatus for performing processing efficiently and at low cost by utilizing the method.

[0002]

2. Description of the Related Art Conventionally, waste incinerators, steam turbines,
A system that improves the overall power generation efficiency by forming a combined cycle by combining power generation and the like, a so-called spar refuse incineration power generation system is known (for example,
See "Fuel and Combustion," Vol. 61, No. 3, pages 3 to 11.

As shown in FIG. 6, a conventional high-efficiency (super) refuse incineration power generation system incinerates waste such as refuse containing chlorine-based compounds in an incinerator 10 and discharges exhaust gas into a boiler 12.
To generate steam and recover heat, then spraying water into the exhaust gas and introducing the exhaust gas into the reactor 14,
HCl in the exhaust gas is removed by reacting with slaked lime or quick lime added to the exhaust gas.
NOx, SOx, dioxin and / or mercury in the exhaust gas are adsorbed by an adsorbent or a catalyst or decomposed and removed, and then the exhaust gas is introduced into a dust collector 18 to capture dust such as fly ash. The steam generated in the boiler 12 is introduced into a heater 20 and heated by burning fuel to produce heated steam, the combustion gas from the heater 20 is supplied to the incinerator 10, and the heated steam is supplied to a steam turbine 22. The waste steam is condensed by a condenser 24 and circulated to the boiler 12.

As a heat source of the heater 20, gas fuel or liquid fuel is used, and these are burned by a combustor to indirectly heat the steam from the boiler 12. The adsorber 16 is loaded with an adsorbent such as activated carbon or activated coke from outside the system.

[0005]

The conventional incinerator exhaust gas treatment system shown in FIG. 6 uses gaseous fuels such as LNG and LPG or liquid fuels such as kerosene, light oil and heavy oil, so that the fuel cost is high. However, there is a problem that the power generation cost increases. In addition, activated carbon or activated coke, which is expensive to manufacture, is used as the adsorbent for the adsorber. However, if it is disposable, the running cost will increase, and if a regenerator is installed, the construction cost will increase, and maintenance and management will be required. There are problems such as high costs. Further, since a granular material is used as the adsorbent and the adsorber is a filling type, there is a problem that the pressure loss increases.

The present invention has been made in view of the above points, and an object of the present invention is to use a solid fuel such as coal as a fuel and partially burn the solid fuel together with steam and air having a theoretical combustion air amount or less. The present invention provides a method and an apparatus for treating incinerator exhaust gas in which a solid fuel is thermally decomposed and the pyrolysis residue (undecomposed residue) is used as activated carbon or activated coke to reduce adsorbent costs. is there. It is another object of the present invention to provide a method and an apparatus for treating incinerator exhaust gas, in which a pyrolysis gas is supplied as fuel to a steam heater or an incinerator to further reduce fuel cost. .

[0007]

In order to achieve the above object, an apparatus for treating incinerator exhaust gas according to the present invention comprises, as shown in FIG. 5, an incinerator for incinerating waste, and an incinerator for incinerator. Boiler that generates steam by introducing exhaust gas from the plant and HC in the exhaust gas by introducing exhaust gas from the boiler
a reactor that reacts and removes l with slaked lime or / and quicklime in flue gas, and introduces flue gas from this reactor to adsorb NOx, SOx, dioxin or / and mercury in flue gas onto activated carbon or activated coke. In an incinerator exhaust gas treatment device comprising an adsorber that decomposes or decomposes and a dust collector that introduces exhaust gas from the adsorber and captures dust such as fly ash, solid fuel, part of steam from the boiler And a pyrolysis furnace for partial combustion by supplying air less than the theoretical combustion air amount, and burning the pyrolysis gas from the pyrolysis furnace
And said thermal decomposition furnace incinerator connected via the pyrolysis gas supply line in order to provide the fuel for却炉, non from the pyrolysis furnace
The decomposition residue is converted to NOx, SOx, dioxin and mercury.
Adsorbent or catalyst to remove at least one
The pyrolysis furnace and the adsorber are connected via an undecomposed residue supply line for use as a fuel cell. The steam generated by the boiler is used as steam for drying or the like.

Further, as shown in FIG. 1, FIG. 3, and FIG. 4, the incinerator exhaust gas treatment apparatus of the present invention includes an incinerator for incinerating waste and an exhaust gas from the incinerator for introducing steam. A boiler to be generated, a reactor for introducing flue gas from the boiler and reacting and removing HCl in flue gas with slaked lime or / and quick lime in flue gas, and a flue gas from this reactor for introducing flue gas from An adsorber that adsorbs or decomposes NOx, SOx, dioxin, and / or mercury on activated carbon or activated coke, a dust collector that introduces exhaust gas from the adsorber to capture dust such as fly ash, and the boiler. A heater configured to heat the generated steam by burning the fuel and to introduce the combustion gas into the incinerator. The pyrolysis furnace for partially and partially by supplying combustion theoretical combustion air amount less air vapor is provided,
To provide pyrolysis gas from pyrolysis furnace as fuel for heater
And a pyrolysis furnace wherein the heater is connected via a pyrolysis gas supply line, NOx undecomposed residue from the pyrolysis furnace, S
Excluding at least one of Ox, dioxin and mercury
A pyrolysis furnace and the adsorber are connected via an undecomposed residue supply line for use as an adsorbent or catalyst for removal .

In the above apparatus, a steam turbine is connected to the heater via a heated steam supply line, a condenser is connected to the steam turbine via a waste steam line, and the condenser is connected to a condensate supply line. Connected to the boiler via
It is preferable to be configured to generate power. It is also possible to use the heated steam for drying and the like without using it for power generation.

In the apparatus configured as shown in FIG. 5, after exhaust gas from the incinerator is introduced into a boiler to generate steam and recover heat, water is sprayed into the exhaust gas and the exhaust gas is introduced into a reactor. HCl in the exhaust gas is removed by reacting with slaked lime or quick lime added to the exhaust gas, and then the exhaust gas is introduced into an adsorber to adsorb NOx, SOx, dioxin or / and mercury in the exhaust gas onto an adsorbent or a catalyst. In the method of treating incinerator exhaust gas that captures dust such as fly ash by introducing the exhaust gas into a dust collector after or after decomposition and removal, the solid fuel selected from the group of coal, dry sludge, bark and wood chips is used. , The solid fuel is thermally decomposed by partial combustion with steam and air below the theoretical combustion air amount, and the pyrolysis gas is supplied to the incinerator as fuel.
The undecomposed residue is supplied to the adsorber as an adsorbent or a catalyst for removing at least one of NOx, SOx, dioxin and mercury. Thus, it supplied as auxiliary fuel pyrolysis gas incinerators. Further, it is preferable to use a part of the steam generated in the boiler as the steam supplied to the pyrolysis furnace.

In the apparatus constructed as shown in FIGS. 1, 3 and 4, after incinerator exhaust gas is introduced into a boiler to generate steam and recover heat, water is sprayed into the exhaust gas and the exhaust gas is discharged. HCl in the exhaust gas
Reacting with slaked lime or quick lime added to the exhaust gas to remove it, and then introducing the exhaust gas into an adsorber to adsorb NOx, SOx, dioxin or / and mercury in the exhaust gas onto an adsorbent or a catalyst, or After being decomposed and removed, the exhaust gas is introduced into a dust collector to capture dust such as fly ash, steam generated in the boiler is introduced into a heater, and the fuel is burned to be heated to form heated steam. In the method for treating incinerator exhaust gas supplying combustion gas from the incinerator to the incinerator, a solid fuel selected from the group of coal, dry sludge, bark and wood chips is partially burned together with steam and air having a theoretical combustion air amount or less. Then the solid fuel is pyrolyzed and the pyrolysis gas is supplied to the heater as fuel.
In addition, the undecomposed residue is passed through the adsorber to form NOx, SOx,
It is supplied as an adsorbent or a catalyst for removing at least one of dioxin and mercury. Thus, it supplied as fuel pyrolysis gas heater. Further, it is preferable to use a part of the steam generated in the boiler as the steam supplied to the pyrolysis furnace.

In the above method, it is preferable to use the heated steam from the heater for power generation, but there are also cases where the heated steam from the heater is used for drying or the like. Also,
The reactor is supplied with slaked lime or quick lime, but it can also be configured to feed limestone, dolomite, slaked lime or quick lime to the incinerator. It is preferable to use a powder as a solid fuel.

[0013]

EXAMPLES Hereinafter, the present invention will be described in more detail with reference to examples, but the present invention is not limited to the following examples, and can be implemented with appropriate modifications. Embodiment 1 FIG. 1 shows an incinerator exhaust gas treatment apparatus according to Embodiment 1. Wastes, for example, refuse containing chlorine compounds are burned in the incinerator 10. The incinerator may be a fluidized bed type or a combustion furnace type such as a stoker furnace.

The exhaust gas from the incinerator 10 is introduced into the boiler 12 to generate steam and recover heat, and then water is supplied into the exhaust gas and the exhaust gas is introduced into the reactor 14. Slaked lime or quick lime is supplied as a desalinating agent in the reactor 14 or on the upstream side of the reactor 14. HCl in the exhaust gas reacts with slaked lime or quick lime and is removed as CaCl ₂ .
Next, the exhaust gas is introduced into the adsorber 16. This adsorber 1
Activated carbon or activated coke, which is a pyrolysis residue from the pyrolysis furnace 30, is supplied and filled through an undecomposed residue supply line 32. When the main purpose is denitration, an adsorber is used. A reducing agent such as ammonia is supplied to 16 or upstream thereof. NOx, SOx, dioxin, mercury and the like in the exhaust gas introduced into the adsorber 16
Adsorbed within or decomposed by the catalysis of activated carbon or activated coke. Exhaust gas from the adsorber 16 is introduced into the dust collector 18 and dust such as fly ash is captured. Then, dust such as fly ash is subjected to stabilization processing.

The steam generated by the boiler 12 is supplied to a heater 20
To the pyrolysis gas supply line 3 from the pyrolysis furnace 30
After the steam is further heated by burning the pyrolysis gas supplied through the steam turbine 4, the steam is introduced into the steam turbine 22 through the heated steam supply line 36 and used for power generation. The water is sent to the condenser 24 via the steam line 38, condensed by the condenser 24, and circulated to the boiler 12 via the condensate supply line 40. Pyrolysis furnace 30
As an example, as shown in FIG. 2, an inexpensive solid fuel such as coal, dry sludge, bark, and wood chips is supplied, and at the same time, a part of steam from the boiler 12 and a theoretical combustion air ratio of 1 to 0.3 are supplied. Is supplied and partially combusted at 500 to 1000 ° C., preferably 600 to 900 ° C. to pyrolyze the coal to perform dry distillation, activate carbon with steam, and generate pyrolysis gas and pyrolysis. And residue. Since the pyrolysis gas contains a large amount of combustibles, it is supplied to the heater 20 as fuel. Since the pyrolysis residue is an undecomposed residue close to activated carbon or activated coke, it is supplied to the adsorber 16 as an adsorbent or a catalyst. Is done.

Since the pyrolysis gas has a low oxygen concentration, NOx can be reduced when it is burned in the heater 20. Further, since activated carbon or activated coke remains in dust such as fly ash captured by the dust collector 18, it is possible to reduce the amount of chelating agent for stabilizing treatment. Furthermore, since activated carbon or activated coke remains in dust such as fly ash, when melting dust such as fly ash,
Fuel costs can be reduced.

Embodiment 2 In this embodiment, as shown in FIG. 3, the heated steam from the heater 20 is used as steam for drying or the like without being used for power generation. Other configurations and operations are the same as those of the first embodiment.

Embodiment 3 In this embodiment, as shown in FIG. 4, instead of supplying slaked lime or quick lime to the reactor 14, limestone, dolomite, slaked lime or quick lime is supplied to the incinerator 10. It is. The supplied limestone and dolomite are thermally decomposed into quicklime and carbon dioxide in the furnace, and the quicklime is entrained in the exhaust gas and reacts with HCl in the exhaust gas in the reactor 14. Other configurations and operations are the same as those of the first embodiment.

Embodiment 4 In the first to third embodiments, a steam heater is provided. In the fourth embodiment, as shown in FIG. 5, a heater for heating steam generated in the boiler 12 is provided. , And the steam extracted through the steam line 37 is used as it is for drying or the like. Therefore, no steam turbine, condenser, etc. are installed. And
The pyrolysis gas generated in the pyrolysis furnace 30 is supplied to the incinerator 10 or the like.
It is supplied as fuel for other combustion devices. Other configurations and operations are the same as those in the first to third embodiments.

[0020]

As described above, the present invention has the following effects. (1) Pyrolysis of inexpensive fuel such as coal with steam to generate pyrolysis gas and undecomposed residue, and convert the undecomposed residue into activated carbon or activated coke to NOx in exhaust gas,
Since it is used as an adsorbent or a catalyst such as SOx, dioxin, and mercury, the cost of the adsorbent (or catalyst) can be reduced. Further, since the use of pyrolysis gas as fuel for heating, or auxiliary fuel such incinerator boiler generating steam,
The fuel cost is reduced, and the cost of the entire system can be further reduced. (2) Since the fuel cost is low and economical for the reason (1), there is no need to install an adsorbent regenerating device as in the related art. (3) When powdered solid fuel is used, powdered activated carbon or powdered activated course can be manufactured, and a dust collector such as a flue and a bag filter can be used as an adsorber, and the flue and a bag filter become an adsorbing portion. Therefore, it is not necessary to provide a special adsorber. Also, since the pressure loss is extremely small, it is easy to modify existing equipment.

[Brief description of the drawings]

FIG. 1 is a system diagram showing an embodiment of an incinerator exhaust gas treatment apparatus according to the present invention.

FIG. 2 is an explanatory view showing an example around a pyrolysis furnace in FIG. 1;

FIG. 3 is a system diagram showing another embodiment of the device of the present invention.

FIG. 4 is a system diagram showing another embodiment of the device of the present invention.

FIG. 5 is a system diagram showing still another embodiment of the device of the present invention.

FIG. 6 is a system diagram showing an example of a conventional device.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 10 Incinerator 12 Boiler 14 Reactor 16 Adsorber 18 Dust collector 20 Heater 22 Steam turbine 24 Condenser 30 Pyrolysis furnace 32 Undecomposed residue supply line 34 Pyrolysis gas supply line 36 Heated steam supply line 37 Steam line 38 Waste Steam line 40 Condensate supply line

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁶ Identification code FI B01D 53/70 B01D 53/34 136A 53/81 53/36 D 53/86 Z 53/94 102F F23J 15/04 F23J 15/00 BDHJ (58) Field surveyed (Int. Cl. ⁶ , DB name) F23J 15/00 B01D 53/50 B01D 53/56 B01D 53/64 B01D 53/68 B01D 53/70 B01D 53/81 B01D 53 / 86 B01D 53/94 F23J 15/04

Claims (11)

(57) [Claims] 1. An incinerator exhaust gas is introduced into a boiler to generate steam and recover heat, then water is sprayed into the exhaust gas and the exhaust gas is introduced into a reactor, and HCl in the exhaust gas is added to the exhaust gas. By reacting with slaked lime or quick lime, and then introducing the exhaust gas into the adsorber to remove NO in the exhaust gas.
x, SOx, dioxin or / and mercury are adsorbed on an adsorbent or a catalyst or decomposed and removed, and then the exhaust gas is introduced into a dust collector to capture dust such as fly ash. coal, dry sludge, the solid fuel selected from the group consisting of bark and wood chips, solid fuel is thermally decomposed by partial combustion with steam and theoretical combustion air amount less air, pyrolytic
The decomposed gas is supplied to the incinerator as fuel, and the undecomposed residue is supplied to the adsorber as an adsorbent or a catalyst for removing at least one of NOx, SOx, dioxin and mercury. How to treat incinerator exhaust gas . 2. The exhaust gas from the incinerator is introduced into a boiler to generate steam and heat is recovered. Then, water is sprayed into the exhaust gas and the exhaust gas is introduced into a reactor, and HCl in the exhaust gas is added to the exhaust gas. By reacting with slaked lime or quick lime, and then introducing the exhaust gas into the adsorber to remove NO in the exhaust gas.
After adsorbing x, SOx, dioxin or / and mercury on an adsorbent or a catalyst or decomposing and removing the same, exhaust gas is introduced into a dust collector to capture dust such as fly ash, and steam generated in the boiler is removed. In the method of treating incinerator exhaust gas, which is heated by heating the fuel by introducing it into a heater and burning it, and supplying combustion gas from the heater to the incinerator, a method of treating coal, dry sludge, bark, and wood chips the chosen solid fuel, the solid fuel is thermally decomposed by partial combustion with steam and theoretical combustion air amount less air, pyrolytic
The decomposed gas is supplied to the heater as fuel, and the undecomposed residue is supplied to the adsorber as an adsorbent or a catalyst for removing at least one of NOx, SOx, dioxin and mercury. How to treat incinerator exhaust gas . 3. A steam supplied to the pyrolysis furnace, the processing method of the incinerator exhaust gas according to claim 1 or 2, wherein a part of the steam generated in the boiler. 4. The method according to claim 2 , wherein the heated steam from the heater is used for power generation. 5. The method for treating incinerator exhaust gas according to claim 2 , wherein the heated steam from the heater is used for drying. 6. A method of treating incinerator waste gas according to any one of the reactor slaked or quick lime according to supplied claim 1-5. 7. The method for treating incinerator exhaust gas according to any one of 1 to 5 , wherein limestone, dolomite, slaked lime or quick lime is supplied to the incinerator. 8. use of powder body as a solid fuel according to claim 1
8. The method for treating incinerator exhaust gas according to any one of claims 1 to 7 . 9. An incinerator for incinerating waste, a boiler for introducing exhaust gas from the incinerator to generate steam,
A reactor for introducing the exhaust gas from the boiler to react HCl in the exhaust gas with slaked lime and / or quick lime in the exhaust gas to remove the NOx, SOx, dioxin in the exhaust gas by introducing the exhaust gas from the reactor And / or and in an incinerator exhaust gas treatment device comprising an adsorber that adsorbs or decomposes mercury to activated carbon or activated coke, and a dust collector that introduces exhaust gas from this adsorber and captures dust such as fly ash. To provide a pyrolysis furnace for partially burning by supplying solid fuel, a part of steam from the boiler and air less than the theoretical combustion air amount, and supplying pyrolysis gas from the pyrolysis furnace to fuel for the incinerator. The pyrolysis furnace and the incinerator are connected via a pyrolysis gas supply line, and the undecomposed residue from the pyrolysis furnace is
incineration characterized in that a pyrolysis furnace and said adsorber are connected via an undecomposed residue supply line for use as an adsorbent or a catalyst for removing at least one of x, SOx, dioxin and mercury. Furnace exhaust gas treatment equipment. 10. An incinerator for incinerating waste, a boiler for introducing exhaust gas from the incinerator to generate steam, and an HC for exhaust gas from the boiler for introducing exhaust gas from the boiler.
a reactor for reacting and removing lime with slaked lime and / or quick lime in exhaust gas, and introducing exhaust gas from this reactor to adsorb NOx, SOx, dioxin or / and mercury in the exhaust gas onto activated carbon or activated coke. An adsorber that decomposes or decomposes, a dust collector that introduces exhaust gas from the adsorber to capture dust such as fly ash, and heats steam generated by the boiler by burning fuel to burn the combustion gas. An incinerator exhaust gas treatment device comprising a heater adapted to be introduced into a furnace, wherein a pyrolysis furnace for partially burning by supplying solid fuel, a portion of steam from the boiler and air less than the theoretical combustion air amount is provided. A pyrolysis furnace and the heater are connected via a pyrolysis gas supply line to supply pyrolysis gas from the pyrolysis furnace to fuel of the heater, and the undecomposed residue from the pyrolysis furnace is provided. NO
incineration characterized in that a pyrolysis furnace and said adsorber are connected via an undecomposed residue supply line for use as an adsorbent or a catalyst for removing at least one of x, SOx, dioxin and mercury. Furnace exhaust gas treatment equipment. 11. A steam turbine is connected to the heater via a heated steam supply line, a condenser is connected to the steam turbine via a waste steam line, and the condenser is connected to the heater via a condensate supply line. The incinerator exhaust gas treatment device according to claim 10 connected to the boiler.