JP6026614B1 - Waste incinerator exhaust gas treatment equipment - Google Patents

Abstract

[PROBLEMS] To compare the purification capacity of a waste incinerator exhaust gas treatment facility configured to purify exhaust gas discharged from a waste incinerator 1 with a filter-type dust collector 4 and then exhaust it into the atmosphere through a chimney. It is possible to improve as much as possible with a simple configuration. A waste incinerator exhaust gas treatment facility is a first denitration system for reducing and removing nitrogen oxides generated by combustion of waste in the waste incinerator 1 by supplying ammonia water into the waste incinerator 1. In addition, by supplying ammonia gas into the denitration reaction tower 5 disposed between the dust collector 4 and the chimney 7, nitrogen oxides contained in the exhaust gas passing through the denitration reaction tower 5 are reduced and removed. 2 denitration system. The second denitration system includes a tank 11 in which ammonia water is stored, and a vaporization tower 12 that vaporizes ammonia water supplied from the tank 11 using the exhaust gas discharged from the waste incinerator 1 as a heat source. [Selection] Figure 1

Description

  The present invention relates to a waste incinerator exhaust gas treatment facility configured to purify exhaust gas discharged from a waste incinerator with a filter-type dust collector and then discharge it into the atmosphere through a chimney.

  For example, Patent Document 1 discloses that in a denitration reaction tower installed in a chimney disposed at the most downstream side in the flow direction of a gas to be treated (or exhaust gas) discharged from a waste incineration facility, the gas to be treated is ammonia gas. It describes that nitrogen oxides in the gas to be treated are reduced and removed by contact reaction with the catalyst.

  For example, in Patent Document 2, the vaporized ammonia is evaporated in a chimney after evaporating ammonia water using steam and the heat of exhaust gas discharged from a gas turbine, diesel engine or boiler in a volatilizer. It is described that nitrogen oxides in exhaust gas are reduced and removed in the denitration reaction tower by supplying the denitration reaction tower to the exhaust gas inlet side.

  For example, in Patent Document 3, a denitration agent (urea water) is supplied to a waste incinerator, nitrogen oxides in exhaust gas in the waste incinerator are reduced, and generated from the remaining nitrogen oxides and denitration agent in the exhaust gas. It is described that ammonia is introduced into a bag filter and nitrogen oxide is further reduced and removed by a catalyst layer in the bag filter.

  For example, in Patent Document 4, ammonia water is supplied to a vaporizing tower, the ammonia water is evaporated by flowing air preheated by an air heater, and the generated ammonia gas is mixed with the air in a gas conduit. Is sent to the reaction tower via

JP 2002-355530 A Japanese Patent Laid-Open No. 3-86212 JP-A-8-332349 JP-A-7-96141

  In Patent Document 1, nitrogen gas contained in the gas to be treated is reduced and removed only by the denitration reaction tower in the chimney using ammonia gas. In Patent Document 2, ammonia water is removed. The nitrogen gas contained in the exhaust gas is reduced and removed only by the denitration reaction tower in the chimney using the ammonia gas obtained by vaporization, and the denitration reaction tower is downsized (reduction of catalyst), There is a demand for further improvement in purification capacity.

  In Patent Document 3, denitration treatment is performed in two stages, but ammonia gas is not introduced into the catalyst layer through a route different from the exhaust gas introduction route.

  Moreover, in the said patent document 4, since the heat source for evaporating ammonia water is made into the preheated air, the dedicated air heater for preheating the said air is needed, and also the amount of exhaust gas increases. There are concerns that initial costs and running costs will increase.

  In view of such circumstances, the present invention is a waste incinerator exhaust gas treatment facility configured to purify exhaust gas discharged from a waste incinerator with a filter-type dust collector and then discharge it into the atmosphere through a chimney. The purpose of the invention is to improve the purification capacity as much as possible with a relatively simple configuration.

The present invention is a waste incinerator exhaust gas treatment facility configured to purify exhaust gas discharged from a waste incinerator with a filter-type dust collector and then discharge it into the atmosphere through a chimney. A first denitration system that reduces and removes nitrogen oxides generated by combustion of waste in the refuse incinerator by supplying ammonia water into the furnace, and is disposed between the dust collector and the chimney. And a second denitration system for reducing and removing nitrogen oxides contained in the exhaust gas passing through the denitration reaction tower by supplying ammonia gas into the denitration reaction tower. having a tank is stored, a space to enable storing the ammonia water to be supplied from the tank to the bottom, and vaporizing the pre Symbol bottom of ammonia water gas which has passed through the dust collector as a heat source at the top A denitration reaction from the ammonia gas supply path, the ammonia gas supply path communicating with the vaporization tower and the exhaust gas inlet side of the denitration reaction tower, and the ammonia gas vaporized in the vaporization tower as a denitration reducing agent An ammonia water supply path having a power source for sending to the tower and a control unit for controlling the operation of the power source, wherein the first denitration system communicates and connects the bottom of the vaporizing tower and the waste incinerator And a power source for sending ammonia water stored at the bottom of the vaporization tower from the ammonia water supply path to the waste incinerator, and a part of the ammonia water sent from the ammonia water supply path to the waste incinerator. A reflux path for reflux spraying into the space of the vaporization tower, a control valve for adjusting the amount of aqueous ammonia to be refluxed and sprayed from the reflux path to the vaporization tower, and the operation of the power source and the control valve. And a Gosuru controller is characterized by.

  In this configuration, nitrogen oxides generated by combustion of waste in the waste incinerator are reduced and removed with ammonia water, and then in a denitration reaction tower disposed downstream of the waste incinerator. Nitrogen oxides contained in the exhaust gas discharged from the waste incinerator are reduced and removed with ammonia gas. Since denitration is performed in two stages in this way, the exhaust gas purification capacity is improved.

  And, because ammonia gas as a denitration reducing agent is obtained by vaporizing ammonia water that is not subject to the High Pressure Gas Safety Law, there are no strict restrictions on the installation location, reducing initial costs and running costs It becomes advantageous in doing.

  Moreover, since the exhaust gas discharged from the waste incinerator is effectively used as a heat source for vaporizing the ammonia water, the configuration becomes simple compared to the case of using a dedicated heat source as in the conventional example, etc. The initial cost and running cost can be reduced.

  According to the present invention, in a waste incinerator exhaust gas treatment facility configured to purify exhaust gas discharged from a waste incinerator with a filtration dust collector and then discharge it into the atmosphere through a chimney, it is relatively simple. With a simple configuration, the purification capacity can be improved as much as possible.

It is a figure which shows typically the structure of one Embodiment of the waste incinerator waste gas processing equipment which concerns on this invention.

  BEST MODE FOR CARRYING OUT THE INVENTION Best modes for carrying out the present invention will be described in detail below with reference to the accompanying drawings.

  FIG. 1 shows an embodiment of the present invention. The waste incinerator exhaust gas treatment facility in the illustrated example includes a waste incinerator 1, a boiler type cooling device 2, a temperature reducing tower 3, a filtration type dust collecting device 4 such as a bag filter, a denitration reaction tower 5, an induction fan 6, A chimney 7 and a denitration reducing agent supply device 8 are provided.

  The garbage incinerator 1 burns garbage such as industrial waste (not shown) or infectious medical waste put in a predetermined package, and the type of the incinerator is not limited.

  The cooling device 2 lowers the temperature of high-temperature exhaust gas discharged from the waste incinerator 1 to about 220 ° C., for example.

  The temperature reducing tower 3 further reduces the temperature of the exhaust gas lowered by the cooling device 2 to approximately 200 ° C. or less. The dust collector 4 neutralizes, filters, and purifies the dust and harmful gas components in the exhaust gas cooled by the temperature reducing tower 3.

  The denitration reaction tower 5 uses ammonia gas to reduce and remove nitrogen oxides contained in the exhaust gas. The induction ventilator 6 sucks the treated gas in the denitration reaction tower 5 and releases it from the chimney 7 to the atmosphere.

  The denitration reducing agent supply device 8 includes a first denitration system (reference numeral omitted) and a second denitration system (reference numeral omitted).

  The first denitration system removes nitrogen oxides generated by combustion of waste in the waste incinerator 1 by supplying ammonia water as a denitration reducing agent to the waste incinerator 1.

  The second denitration system supplies nitrogen gas to the denitration reaction tower 5 as a denitration reducing agent, thereby removing nitrogen oxides remaining in the exhaust gas that has passed through the dust collector 4 and introduced into the denitration reaction tower 5. Reduce and remove.

  Specifically, the denitration reducing agent supply apparatus 8 includes a tank 11, a vaporization tower 12 as a vaporization element, an ammonia water supply path 13, a pump 14, an ammonia gas supply path 15, a fan 16, a control unit 17, and the like.

  The tank 11 stores ammonia water. The vaporization tower 12 vaporizes ammonia water supplied from the tank 11 via the communication path 18 using the exhaust gas (for example, about 160 to 200 ° C.) introduced from the dust collector 4 via the exhaust gas introduction path 19 as a heat source. This is a container having a space for making ammonia gas. The vaporization tower 12 shown in this embodiment is a container capable of storing ammonia water that cannot be completely vaporized at the bottom.

  A float valve 20 is provided in the communication path 18. The float valve 20 opens when the amount of ammonia water stored in the vaporization tower 12 is less than a predetermined amount, thereby enabling the ammonia water in the tank 11 to be introduced into the vaporization tower 12. When the stored amount of the water reaches a predetermined amount or more, it is closed to make it impossible to introduce the ammonia water in the tank 11 into the vaporization tower 12.

  The ammonia water supply path 13 is connected so as to connect the bottom of the vaporization tower 12 and the waste incinerator 1 in communication. A pump 14 is provided in the middle of the ammonia water supply path 13. The pump 14 is a power source for sending ammonia water stored at the bottom of the vaporizing tower 12 to the waste incinerator 1 through the ammonia water supply path 13.

  In the ammonia water supply path 13, the downstream side of the pump 14 and the upper part of the vaporization tower 12 are connected by a reflux path 21. The reflux path 21 is provided for refluxing and spraying ammonia water stored at the bottom of the vaporization tower 12 from the upper part of the vaporization tower 12.

  A control valve 22 is provided in the reflux path 21. This control valve 22 is in a state where ammonia water stored at the bottom of the vaporizing tower 12 can be refluxed and sprayed to the vaporizing tower 12 to generate ammonia gas to be supplied to the denitration reaction tower 5 when opened by the control unit 17 described below. On the other hand, ammonia water stored at the bottom of the vaporizing tower 12 when blocked by the control unit 17 described below is brought into a state in which the vaporizing tower 12 cannot be refluxed and sprayed.

  The ammonia gas supply path 15 is connected so as to communicate and connect the vaporization tower 12 and the exhaust gas inlet side of the denitration reaction tower 5. A fan 16 is provided in the middle of the ammonia gas supply path 15. The fan 16 sucks the ammonia gas generated in the vaporization tower 12 using the exhaust gas extracted from the outlet of the dust collector 4 as a transport medium and sends it to the denitration reaction tower 5 through the ammonia gas supply path 15. It is.

  The operations of the pump 14, the control valve 22 and the fan 16 are controlled by the control unit 17. That is, the control unit 17 performs an operation related to the supply of ammonia water stored at the bottom of the vaporization tower 12 and an operation related to the supply of ammonia gas generated in the vaporization tower 12.

  The waste incinerator 1, the tank 11, the vaporizer 12, the pump 14, the ammonia water supply path 13, and the control unit 17 constitute the first denitration system. In this first denitration system, a so-called “non-catalytic reduction method” or “non-catalytic denitration” is performed.

  In addition, the denitration reaction tower 5, the tank 11, the vaporization tower 12, the pump 14, the ammonia gas supply path 15, the fan 16, the reflux path 21, the control valve 22, and the control unit 17 constitute the second denitration system. . In this second denitration system, denitration in a form called “catalytic reduction using a catalyst” or “catalytic denitration” is performed.

  Next, the operation of the denitration reducing agent supply device 8 will be described.

  First, the control unit 17 sets the detection value from the sensor 23 for detecting the concentration of nitrogen oxides on the outlet side of the denitration reaction tower 5 and the amount of exhaust gas introduced from the dust collector 4 into the vaporization tower 12. Based on this, the amount of ammonia water to be sprayed on the vaporizing tower 12 is calculated. Based on the calculation result, the opening degree and opening time of the control valve 22 are controlled, and the fan 16 is operated.

  Thereby, the ammonia water sprayed in the vaporization tower 12 is volatilized by the heat of the exhaust gas supplied to the vaporization tower 12 to be ammonia gas. The ammonia gas is sucked by the fan 16 using the exhaust gas extracted from the outlet of the dust collector 4 as a transport medium and introduced into the denitration reaction tower 5 through the ammonia gas supply path 15.

  By the way, ammonia water composed of droplets that have not been volatilized in the vaporization tower 12 is stored at the bottom of the vaporization tower 12.

  Ammonia water stored at the bottom of the vaporizing tower 12 is sucked by operating the pump 14 and sprayed to the waste incinerator 1 through the ammonia water supply passage 13.

  Next, the operation of the waste incinerator exhaust gas treatment facility will be described.

  The waste introduced in the waste incinerator 1 is combusted, and the high-temperature exhaust gas discharged from the waste incinerator 1 is cooled to about 220 ° C. by the cooling device 2 and further lowered to about 200 ° C. or less by the temperature reducing tower 3. After the temperature is lowered, it is sent to a filtration type dust collector 4 such as a bag filter.

  Here, ammonia water is sprayed from the first denitration system of the denitration reducing agent supply device 8 to the waste incinerator 1, and is generated along with the combustion of waste in the waste incinerator 1. Nitrogen oxides are reduced and removed.

  The temperature reducing tower 3 further cools the exhaust gas cooled by the cooling device 2 to approximately 200 ° C. or less, and the dust collecting device 4 neutralizes and filters out dust and harmful gas components in the exhaust gas. To the denitration reaction tower 5.

  In this denitration reaction tower 5, the unreacted ammonia gas discharged from the waste incinerator 1 and the ammonia gas supplied from the second denitration system of the denitration reducing agent supply device 8 are used. Nitrogen oxides contained in the exhaust gas that has passed through are reduced and removed.

  The gas after being treated in the denitration reaction tower 5 in this way is sucked by the induction fan 6 and released from the chimney 7 into the atmosphere.

  As described above, according to the embodiment to which the present invention is applied, nitrogen oxides generated by combustion of waste in the waste incinerator 1 are reduced and removed with ammonia water, and then the waste incinerator. 1, nitrogen oxides contained in the exhaust gas from the waste incinerator 1 are reduced and removed by unreacted ammonia gas and ammonia gas generated in the vaporization tower 12 in the denitration reaction tower 5 arranged on the downstream side of 1. Yes. Since denitration is performed in two stages in this way, the exhaust gas purification capacity is improved.

  The ammonia gas as the denitration reducing agent of the second denitration system is obtained by vaporizing ammonia water that is not subject to the high-pressure gas safety law. This is advantageous in reducing costs and running costs.

  Moreover, since the exhaust gas discharged from the waste incinerator 1 is effectively used as a heat source for vaporizing the ammonia water, the configuration becomes simple compared to the case where a dedicated heat source is used as in the conventional example. The initial cost and running cost can be reduced.

  In addition, this invention is not limited only to the said embodiment, It can change suitably in the range equivalent to the claim and the said range.

  (1) In the above embodiment, an example is given in which exhaust gas discharged from the dust collector 4 is used as a heat source for vaporizing ammonia water in the vaporization tower 12, but the present invention is not limited to this. Absent.

  For example, although not shown, as the heat source, exhaust gas discharged from any one of the waste incinerator 1, the cooling device 2, and the temperature-decreasing tower 3 can be used.

  In this case, the vaporization tower 12 is enlarged so that the ammonia water is completely vaporized, and since the transport medium (heat source) contains dust, it is necessary to recirculate to the inlet of the dust collector 4. Is more advantageous.

  (2) In the above embodiment, an example is given in which ammonia water that cannot be completely vaporized in the vaporization tower 12 and is collected at the bottom is supplied to the waste incinerator 1, but the present invention is not limited to this. Absent.

  For example, although not shown, it is possible to supply the ammonia water in the tank 11 to the waste incinerator 1 for the ammonia water introduced into the waste incinerator 1 in the first denitration system.

  However, in that case, a system for returning to the tank 11 by the overflow method is required so that the amount of ammonia water that cannot be completely vaporized in the vaporization tower 12 and remains in the bottom is constant.

  The present invention can be suitably used for a waste incinerator exhaust gas treatment facility configured to purify exhaust gas discharged from a waste incinerator with a filtration dust collector and then discharge it into the atmosphere through a chimney. Is possible.

1 Waste incinerator
2 Boiler type cooling system
3 Temperature reduction tower
4 Filtration type dust collector
5 Denitration reaction tower
6 induction fan
7 Chimney
8 Reducing agent supply device for denitration
11 tanks
12 Evaporation tower
13 Ammonia water supply channel
14 Pump
15 Ammonia gas supply path
16 fans
17 Control unit
18 passage
19 Exhaust gas introduction path
20 Float valve
21 Return route
22 Control valve
23 Sensor

Claims (1)

A waste incinerator exhaust gas treatment facility configured to purify exhaust gas discharged from a waste incinerator with a filter-type dust collector and then discharge it into the atmosphere through a chimney,
A first denitration system for reducing and removing nitrogen oxides generated by combustion of waste in the waste incinerator by supplying ammonia water into the waste incinerator;
A second denitration system for reducing and removing nitrogen oxides contained in the exhaust gas passing through the denitration reaction tower by supplying ammonia gas into the denitration reaction tower disposed between the dust collector and the chimney; With
The second denitration system includes a tank ammonia water is stored, and can store ammonia water supplied from the tank to the bottom, and the SL before the exhaust gas having passed through the dust collector as a heat source the bottom of the ammonia water A vaporization tower having a space for vaporizing at the top, an ammonia gas supply path that connects the vaporization tower and an exhaust gas inlet side of the denitration reaction tower, and ammonia gas vaporized in the vaporization tower as a reducing agent for denitration. A power source for sending from the ammonia gas supply path to the denitration reaction tower, and a controller for controlling the operation of the power source;
The first denitration system includes an ammonia water supply path that connects the bottom of the vaporization tower and the waste incinerator, and ammonia water stored in the bottom of the vaporization tower from the ammonia water supply path to the waste incinerator. A power source for sending to the waste incinerator, a reflux path for refluxing and spraying a part of the ammonia water sent to the waste incinerator from the ammonia water supply path to the space of the vaporization tower, A waste incinerator exhaust gas treatment facility , comprising: a control valve for adjusting an amount of ammonia water to be sprayed; and a control unit for controlling operations of the power source and the control valve .

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