JP2000065328A - Processing method and apparatus for refuse incinerator waste gas - Google Patents

Abstract

PROBLEM TO BE SOLVED: To effectually utilize heat recovered by a temperature lowering processing, improve efficiency of a dust collector and protect the same, and further prevent dioxin in waste gas from being again synthesized by rapidly lowering temperature of the waste gas and performing a scavenging processing for the same. SOLUTION: In a waste gas processing apparatus which includes a waste heat boiler 2 disposed downstream a refuse incinerator 1 for recovering heat from waste gas, and a dust collector 4 for removing dust from waste gas disposed downstream the waste heat boiler 2, there is disposed a rotary regenerating heat exchanger 14 between the waste heat boiler 2 and the dust removal apparatus 4 for heat exchange between the waste gas and air.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

The present invention relates to a method and an apparatus for treating exhaust gas discharged from a refuse incinerator.

[0002]

2. Description of the Related Art Generally, high-temperature (about 700 ° C.) exhaust gas discharged from a refuse incinerator is recovered by a waste heat boiler 2 installed downstream of the refuse incinerator 1 as shown in FIG. To 280-300 ° C. Further, this exhaust gas is passed through a wet cooling tower 3 installed on the downstream side of the waste heat boiler 2 to be cooled down to 180 to 190 ° C., and flows into a dust collector 4 installed on the downstream side. Has become. In FIG. 6, 5 is a gas / air heater, 6 is a suction fan, 7 is a dechlorination device, 8 is a steam heat exchanger, 9
Is a chimney, 10 is a push-in fan, 11 is a steam heat exchanger, 12 is a push-in fan, and 13 is a steam heat exchanger, which indicates the temperature of exhaust gas or air at each position.

[0003]

However, the above-mentioned conventional exhaust gas treatment method and apparatus not only do not effectively utilize the recovered heat due to the temperature reduction of the exhaust gas, but also reduce the efficiency of the dust collector. And dioxin is resynthesized.

The present invention has been made in order to solve the above-mentioned conventional problems, and an object of the present invention is to make it possible to effectively use heat recovered by a temperature reduction process.
A refuse incinerator that can improve the efficiency of the dust collector and protect it, and can suppress the re-synthesis of dioxin in the exhaust gas by rapidly reducing the temperature of the exhaust gas and performing scavenging treatment. An object of the present invention is to provide a method and an apparatus for treating exhaust gas.

[0005]

SUMMARY OF THE INVENTION According to the present invention, there is provided a method for treating exhaust gas from a refuse incinerator, wherein the exhaust gas from the refuse incinerator is heat-recovered by an exhaust gas cooling device, and the exhaust gas is removed by a dust collector installed downstream of the device. , Wherein heat is exchanged between the exhaust gas and air by a rotary regeneration type heat exchanger installed between the exhaust gas cooling device and the dust collecting device. The heat-exchanged air is used, for example, as high-temperature air for burning a refuse incinerator, high-temperature air for preventing white smoke, high-temperature air for pre-drying refuse, or high-temperature air combining these airs. The exhaust gas cooling device is, for example, a waste heat boiler or a wet cooling tower. Further, in the above method, it is also characterized in that the leaked exhaust gas from the vicinity of the sector plate on the air outflow side and on the upstream side in the rotor rotation direction is sucked and introduced into the exhaust gas discharged from the rotary regeneration type heat exchanger.
Further, in the above method, it is characterized in that air is pushed into the vicinity of the sector plate on the exhaust gas inflow side and on the downstream side in the rotor rotation direction. Still further, in the above method, it is characterized in that air is taken in from the vicinity of the sector plate on the air outflow side and downstream in the direction of rotor rotation, and is introduced into exhaust gas exiting from the rotary regeneration type heat exchanger. Exhaust gas and air flowing in the rotor of the rotary regenerative heat exchanger flow as countercurrent or parallel flow.

[0006] Further, the waste gas incinerator exhaust gas treatment apparatus of the present invention is installed downstream of the waste incinerator and recovers heat from the exhaust gas, and installed downstream of the exhaust gas cooling apparatus. An exhaust gas treatment device comprising a dust collector for removing dust from the exhaust gas cooling device and the dust collector, wherein a rotary regenerative heat exchanger that performs heat exchange between the exhaust gas and air is installed. I do. The exhaust gas cooling device is, for example, a waste heat boiler or a wet cooling tower. Further, in the above apparatus, suction means for sucking leaked exhaust gas from the vicinity of the sector plate on the air outflow side and upstream of the rotor rotation direction is provided, and the sucked leaked exhaust gas is exhausted from the rotary regenerative heat exchanger. It is also characterized by the provision of means for introducing into the. Further, the above apparatus is characterized in that a pushing means for pushing air is provided near the sector plate on the exhaust gas inflow side and on the downstream side in the rotor rotation direction. Further, in the above apparatus, air intake means for taking in air from near the sector plate on the air outflow side and downstream in the direction of rotor rotation is provided, and the taken air is introduced into exhaust gas exiting from the rotary regenerative heat exchanger. It is also characterized by the provision of means for performing this. Exhaust gas and air flowing in the rotor of the rotary regenerative heat exchanger flow as countercurrent or parallel flow.

[0007]

Embodiments of the present invention will be described below with reference to the drawings. In FIG. 1, reference numeral 14 denotes a rotary regenerative heat exchanger, which mainly includes a rotor 14a having a plurality of heat transfer elements loaded therein, and a rotor 14a.
a rotatably supporting the rotor post 14b.
The passage of the fluid passing through the rotor 14a is divided into two by the sector plates 14c and 14d, and the respective passages are configured so that the waste gas incinerator exhaust gas G1 and the air G2 flow. In addition, the rotary regeneration type heat exchanger 14 is usually provided with a soot blowing device using air or steam as a medium in order to prevent the heat transfer element from being clogged by incineration ash.

The rotary regenerative heat exchanger 14 is installed between the waste heat boiler 2 and the dust collector 4, and converts the high temperature (about 700 ° C.) exhaust gas G1 discharged from the refuse incinerator 1 to the rotary regenerative heat exchanger 14. It is led to one passage of the heat exchanger 14 and
By rapidly decreasing the temperature to 80 ° C., re-synthesis of dioxin in exhaust gas is suppressed.

Further, air G2 (outside air temperature of about 20 ° C.) taken in by a push-in fan 15 is guided to the other passage of the rotary regenerative heat exchanger 14, and heat is exchanged with the exhaust gas G1. It is exchanged and supplied to the incinerator 1, for example, as high-temperature air for incinerator combustion. In addition,
The air G2 is supplied by the steam heat exchanger 16 to 60-80.
Since it is guided to the rotary regenerative heat exchanger 14 after being heated to about ° C., low-temperature corrosion in the rotary regenerative heat exchanger 14 is prevented.

The heat is exchanged with the air G2 with the rotation of the rotor of the rotary regenerative heat exchanger 14, and the heat is exchanged for 180 to 190.
The exhaust gas G1 whose temperature has been reduced to 0 ° C. is subjected to dust collection by a dust collector 4 such as an electric dust collector or a bag filter, sent to a dechlorinator 7 by a suction fan 6, and finally passed through a chimney 9 to the atmosphere. Will be released.

On the other hand, 200 to 250 obtained by heat exchange with the waste gas from the waste incinerator by the rotary regeneration type heat exchanger 14.
° C air G2 is mixed not only with the high temperature air for combustion of the above-mentioned refuse incinerator 1 but also with the exhaust gas discharged from the dechlorination device 7 and used as high temperature air for preventing white smoke, It is also used as high-temperature air for pre-drying of refuse (not shown) charged into the furnace.

In the above embodiment, a waste heat boiler is used as the exhaust gas cooling device of the present invention, but a wet cooling tower may be used depending on the properties of the exhaust gas (for example, when high temperature corrosion occurs). Further, the flow directions of the exhaust gas G1 and the air G2 passing through the rotor 14a of the rotary regeneration type heat exchanger 14 are opposite to each other, but the present invention is not limited to this. As shown in FIG. 2A, the flow directions of the exhaust gas G1 and the air G2 may be the same, that is, a parallel flow.

The rotary regeneration type heat exchanger 14
2B, the passage between the high-temperature exhaust gas G1 and the low-temperature air G2 passing through the rotor 14a is formed by the sector plate 14 on the exhaust gas inflow side (air inflow side).
c and the sector plate 14d on the exhaust gas outflow side (air outflow side). As shown in FIG. 2B, in the vicinity of the sector plate 14d on the air outflow side and on the upstream side in the rotor rotation direction, a part of the exhaust gas G1 leaks to the air G2 side, that is, a so-called entrained leak. Is generated. When a part of the exhaust gas G1 is mixed into the air G2, the emission of dioxin becomes a problem particularly when the air G2 is used as high temperature air for preventing white smoke.

Therefore, a so-called scavenging device is required to prevent the above-mentioned entrained leak.
FIG. 3 shows an example of a scavenging device. A suction device 14e is provided near the sector plate 14d on the air outflow side and on the upstream side in the direction of rotor rotation to suck the exhaust gas G1 that has undergone the entrained leak. And the exhaust gas G1 from the regenerative heat exchanger 14 is eliminated. The suction operation by the suction device 14e may be performed not only by forced suction but also by a simple pressure difference.

FIG. 4 shows another example of the scavenging device. Part of the air G2 is used as scavenging gas near the sector plate 14c on the exhaust gas inflow side and downstream in the rotor rotation direction. Pushing device 14
The provision of f prevents an exhaust leak of the exhaust gas G1 to the air G2 side.

FIG. 5 shows still another embodiment.
An air outlet 1 for preventing white smoke is provided near the sector plate 14d on the air outflow side and on the downstream side in the rotor rotation direction.
4 g, take in air G2 without entrained leak and exhaust gas G1 exiting from rotary regeneration type heat exchanger 14
To reduce dioxin emissions from chimneys.

The above-described scavenging process is particularly effective in the case of a parallel flow. However, as shown in FIG. 1, the flow directions of the exhaust gas G1 and the air G2 flowing in the rotor 14a of the rotary regenerative heat exchanger 14 are shown. May be carried out to a device in which the flow is countercurrent.

[0018]

According to the conventional method, 1) In the conventional method, high-temperature air for burning a refuse incinerator, high-temperature air for preventing white smoke, and high-temperature air for pre-drying refuse, which are separately obtained by a steam heat exchanger, are also regenerated by rotation. The heat can be obtained in parallel with the temperature reduction of the exhaust gas by the heat exchanger, and the recovered heat can be used effectively. 2) The regenerative heat exchanger installed between the exhaust gas cooling device and the dust collector effectively reduces the temperature of the exhaust gas from the refuse incinerator, improving the dust collection efficiency of the dust collector and improving the dust collection device. Can be protected. 3) The time required for the exhaust gas to pass through the rotor of the rotary regenerative heat exchanger is 1 second or less (further, it can be up to 0.2 to 0.3 seconds)
Therefore, by rapidly decreasing the temperature of the waste gas from the incinerator to 300 ° C. from 180 ° C., there is an effect of suppressing the resynthesis of dioxin in the waste gas. 4) Since the scavenging treatment means is provided in the rotary regenerative heat exchanger, the emission of dioxin from the chimney is further reduced. 5) By taking in high-temperature air for preventing white smoke from the vicinity of the sector plate on the air outflow side and downstream in the direction of rotor rotation, the emission of dioxin from the chimney is further reduced. 6) By flowing the exhaust gas and air flowing in the rotor of the rotary regenerative heat exchanger as a parallel flow, the temperature of the heat storage material such as the heat transfer element loaded in the rotor is made almost the same high from the exhaust gas inlet to the exhaust gas. Since the heat storage material can be maintained, corrosion and blockage of the heat storage material can be avoided. Further, the exhaust gas passage time through the rotor can be maintained at 1 second or less.

[Brief description of the drawings]

FIG. 1 is a flow chart showing one embodiment of a waste incinerator exhaust gas treatment apparatus of the present invention.

FIG. 2 is an explanatory diagram of an entrained leak in a rotary regenerative heat exchanger.

FIG. 3 is an explanatory diagram showing one embodiment of a scavenging device.

FIG. 4 is an explanatory view showing another embodiment of the scavenging device.

FIG. 5 is an explanatory view showing an embodiment of a hot-air outlet for preventing white smoke.

FIG. 6 is a flowchart of a conventional waste gas incinerator exhaust gas treatment apparatus.

[Explanation of symbols]

 Reference Signs List 1 refuse incinerator 2 waste heat boiler 3 wet cooling tower 4 dust collector 5 gas / air heater 6 suction fan 7 dechlorination device 8 steam heat exchanger 9 chimney 10 push-in fan 11 steam heat exchanger 12 push-in fan 13 steam-type Heat exchanger 14 Rotary regeneration heat exchanger 14a Rotor 14b Rotor post 14c Sector plate 14d Sector plate 14e Suction device 14f Push-in device 14g Air outlet 15 Push-in fan 16 Steam heat exchanger G1 Exhaust gas G2 Air

Claims (14)

[Claims] An exhaust gas treatment method for recovering heat from a waste incinerator exhaust gas using an exhaust gas cooling device and removing the dust using a dust collector installed downstream of the waste incinerator. A method for treating waste gas from a refuse incinerator, wherein heat is exchanged between the exhaust gas and air by a regenerative heat exchanger. 2. The method for treating exhaust gas from a refuse incinerator according to claim 1, wherein said exhaust gas cooling device is a waste heat boiler. 3. The method for treating exhaust gas from a refuse incinerator according to claim 1, wherein said exhaust gas cooling device is a wet cooling tower. 4. A suction exhaust gas leaking from the vicinity of the sector plate on the air outflow side and on the upstream side in the rotor rotation direction,
4. A method for treating waste gas from a refuse incinerator according to claim 1, wherein the waste gas is introduced into exhaust gas discharged from the rotary regeneration heat exchanger. 5. The method for treating exhaust gas from a refuse incinerator according to claim 1, wherein air is pushed into the vicinity of the sector plate on the exhaust gas inflow side and on the downstream side in the rotor rotation direction. 6. A method according to claim 1, wherein air is taken in from the vicinity of the sector plate on the air outflow side and on the downstream side in the direction of rotation of the rotor, and is introduced into exhaust gas exiting from the rotary regenerative heat exchanger. 3. The method for treating waste gas from a refuse incinerator according to 3, 4, or 5. 7. The refuse incineration as claimed in claim 1, wherein the exhaust gas and air flowing in the rotor of the rotary regenerative heat exchanger are caused to flow in countercurrent or parallel flow. Furnace exhaust gas treatment method. 8. An exhaust gas treatment device comprising: an exhaust gas cooling device installed downstream of a waste incinerator for recovering heat from exhaust gas; and a dust collecting device installed downstream of the exhaust gas cooling device to remove dust from the exhaust gas. A regenerative heat exchanger for exchanging heat between the exhaust gas and the air between the exhaust gas cooling device and the dust collecting device. 9. The waste gas incinerator exhaust gas treatment device according to claim 8, wherein said exhaust gas cooling device is a waste heat boiler. 10. The waste gas incinerator exhaust gas treatment device according to claim 8, wherein said exhaust gas cooling device is a wet cooling tower. 11. A suction means for sucking leaked exhaust gas from the vicinity of the sector plate on the air outflow side and upstream of the rotor in the direction of rotation of the rotor, and converts the sucked leaked exhaust gas to exhaust gas discharged from the rotary regeneration type heat exchanger. The waste gas incinerator exhaust gas treatment apparatus according to claim 8, 9 or 10, further comprising means for introducing. 12. The waste gas incinerator exhaust gas treatment apparatus according to claim 8, 9 or 10, further comprising a pushing means for pushing air in the vicinity of the sector plate on the exhaust gas inflow side and on the downstream side in the rotor rotation direction. 13. An air intake means for taking in air from the vicinity of the sector plate on the air outflow side and downstream of the rotor in the rotational direction, and means for introducing the taken air into exhaust gas discharged from the rotary regenerative heat exchanger. The waste gas incinerator exhaust gas treatment apparatus according to claim 8, 9, 10, 11, or 12, wherein: 14. An apparatus according to claim 8, wherein the exhaust gas and the air flowing in the rotor of the rotary regenerative heat exchanger are caused to flow as a counter flow or a parallel flow.
14. The waste incinerator exhaust gas treatment apparatus according to 1, 12, or 13.