JPH0619819U - Dry acidic exhaust gas treatment device - Google Patents

Abstract

(57) [Summary] [Object] The present invention provides a dry acidic exhaust gas treatment apparatus that reduces the amount of alkaline chemicals used to remove acidic components contained in exhaust gas. [Structure] In this dry acidic exhaust gas treatment apparatus, a spray nozzle 1 is attached to a flue 9 connecting an air preheater 5 and a bag filter 6.
3 is provided, the alkaline agent is sprayed from the spray nozzle 13,
The baggage filter 6 collects the acidic components in the exhaust gas after neutralizing them. The collected matter containing the unreacted alkaline agent collected by the bag filter 6 was introduced to the inlet of the air preheater 5 by the transfer means 11, and the unreacted alkaline agent was reused for the neutralization reaction. Therefore, the spray amount of the alkaline agent can be reduced. The dust in the air preheater 5 is discharged from the discharge means 12 provided on the upstream side of the spray nozzle 13.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 The present invention relates to a dry acidic exhaust gas treatment apparatus for removing acidic components contained in exhaust gas discharged from various boilers, heating furnaces, incinerators and the like.

[0002]

[Prior art]

Exhaust gas discharged from various boilers, heating furnaces, incinerators, etc. contains a large amount of acidic components such as soot and dust, hydrogen chloride (HCl), sulfur oxides (SO _x ), and other harmful substances. Therefore, while it is required to develop an exhaust gas treatment device that can remove these substances efficiently and effectively, the emission concentrations of these substances are strictly regulated as a measure to prevent air pollution.

Generally, the removal treatment of the acidic components such as hydrogen chloride (HCl) and sulfur oxides (SO _x ) contained in the exhaust gas is carried out by bringing these acidic components into contact with an alkaline chemical. As the alkaline chemical, a chemical consisting of alkaline earth metal represented by slaked lime [Ca (OH) ₂ ] is used. The method for treating acidic exhaust gas, that is, the method for removing acidic exhaust gas, can be broadly divided into two types: a dry treatment method and a wet treatment method. The dry treatment method is a method of supplying the drug in the form of particles or powder, and the wet treatment method is a method of supplying the drug in the form of slurry or liquid.

Exhaust gas treatment by a conventional dry treatment method will be described with reference to FIG. 2 in an example of a waste incineration facility. As shown in FIG. 2, refuse, which is an incineration product, is put into the incinerator 2 through the inlet 1, and is burned on the stoker 3 provided below the incinerator 2. The generated high-temperature combustion gas is cooled in a gas cooling chamber 4 provided on the downstream side of the incinerator 2 and further cooled by passing through an air preheater 5 provided on the downstream side of the gas cooling chamber 4. . The cooled exhaust gas is cleaned by the dust collector 6 and then sucked by the attracting fan 7 and exhausted from the chimney 8 into the atmosphere.

The removal of acidic components such as hydrogen chloride and sulfur oxides contained in the exhaust gas is removed through two steps. First, as a first step, an alkaline chemical is sprayed from a chemical supply means 10 such as a spray nozzle provided in the flue 9 immediately before the dust collector 6, and the alkaline chemical is suspended and diffused in the exhaust gas, whereby the exhaust gas is discharged. Neutralize the acidic components contained in it. Then, in the next step, the neutralized reaction products such as CaCl ₂ and CaSO ₄ are removed by the dust collector 6.

In this dry treatment method, when an electrostatic precipitator is used, for example, the HCl removal rate is usually 50 to 60%, and although the removal rate improves depending on the amount of the alkaline chemical sprayed, it is economical. In consideration of the characteristics, in many cases, the HCl discharge concentration at the outlet of the electrostatic precipitator is often adjusted to be about 200 to 430 ppm. Further, when using a filter-type dust collector in which an alkaline powder layer is formed on a filter cloth, it is possible to remove HCl by 95% or more.

[0007]

[Problems to be solved by the device]

 By the way, comparing the dry processing method and the wet processing method as described above, the dry processing method has the following advantages over the wet processing method. That is, since the dry treatment method does not require wastewater treatment, it is not necessary to install a waste liquid treatment facility, and also as a reactor for neutralizing the acid gas, another exhaust gas such as a flue or a dust collector is used. Since the equipment can be used, it is necessary to add a drug storage / supply device, but there is an advantage that a special reactor is not required. Therefore, the refuse incineration facility as a whole can be made compact. Further, the dry treatment method has the advantage that the temperature of the exhaust gas at the outlet of the exhaust gas treatment device can be maintained at a high temperature, so that white smoke is less likely to occur and it is easy to take measures against corrosion of the device itself. It is an excellent processing method.

However, the dry treatment method has a drawback in that a larger amount of the medicine is used as compared with the wet treatment method, because a part of the supplied medicine is discharged without reaction. Therefore, in the dry treatment method, as long as the amount of unreacted drug can be reduced, it is a very suitable treatment method. Therefore, how to reduce the amount of unreacted drug is an important issue.

[0009] Therefore, an object of the present invention is to solve the above-mentioned problems, and an alkaline chemical for removing an acidic component contained in exhaust gas is not discharged from a filter type dust collector, It is to provide a dry acidic exhaust gas treatment device capable of significantly reducing the amount of alkaline chemicals used by feeding back to the preheater to react the residual amount of alkaline chemicals again.

[0010]

[Means for Solving the Problems]

 In order to achieve the above-mentioned object, this invention is configured as follows. That is, the present invention relates to an air preheater for heating air with high-temperature exhaust gas, a filter-type dust collector disposed on the downstream side of the air preheater for removing harmful substances in the exhaust gas, and the air preheater. A flue connecting the filter dust collector, a chemical supply means for supplying an alkaline chemical into the flue, and a transfer means for feeding back the collected matter collected by the filter dust collector to the air preheater. The present invention also relates to a dry acidic exhaust gas treatment device having a discharge means for discharging dust in the air preheater provided on the upstream side of the chemical supply means of the flue.

In this dry acidic exhaust gas treatment apparatus, the filter type dust collector is preferably a bag filter having an alkaline powder layer formed on a filter cloth. As the transfer means, it is preferable to use a gas transfer means for feedback. Furthermore, it is necessary to arrange a soot blower or the like in the air preheater to avoid dust accumulation.

[0012]

[Action]

 Since the present invention is configured as described above, it works as follows. That is, the high temperature exhaust gas containing a large amount of acidic substances is cooled by the air preheater and sent to the filter type dust collector. Immediately before the filter dust collector, the alkaline chemical is supplied into the flue, and the exhaust gas containing the acidic substance undergoes a gas-solid reaction with the alkaline chemical to neutralize it. The neutralized reaction product is sent to a filter type dust collector together with unreacted alkaline chemicals, and is collected by the filter type dust collector. Since a large amount of unreacted alkaline chemicals is contained in the collected collected matter, by guiding this collected matter to the inlet of the air preheater through the transfer means, the unreacted alkaline chemical is not reacted. The alkaline agent causes a gas-solid reaction with the acidic substances in the exhaust gas in the air preheater.

As described above, since the gas-solid reaction is performed not only in the flue but also in the air preheater, it is possible to prolong the actual reaction time, and to reheat the unreacted alkaline chemicals to the air preheater. Since the reaction is carried out with the acid gas having a high concentration and a high temperature in the vessel, the gas-solid reaction efficiency is considerably improved. In addition, since the amount of acidic substances in the exhaust gas is considerably reduced by the gas-solid reaction in the first stage that occurs in the air preheater, the amount of new alkaline chemicals to be sprayed into the flue gas for the gas-solid reaction in the second stage is reduced. The quantity is small. Therefore, it is possible to greatly reduce the amount of the alkaline chemical used to remove the acidic substances contained in the exhaust gas.

Further, since the dust is configured to be discharged from the discharge means provided on the upstream side of the supply means, the dust in the air preheater can be discharged to the outside. For this reason, the load on the bag filter in the subsequent stage is reduced in combination with the reduction in both the amount of alkali agent used.

[0015]

【Example】

 An embodiment of the dry acidic exhaust gas treatment apparatus according to the present invention will be described below with reference to the drawings. Of course, the present invention is not limited to this embodiment, and the embodiment is not limited to this embodiment. FIG. 1 is a schematic explanatory view showing a dry acidic exhaust gas treatment device in a refuse incineration facility or the like. This dry-type acidic exhaust gas treatment device has a gas cooling chamber 4, an air preheater 5, a bag filter 6 as a filter type dust collector, a flue 9 connecting the air preheater 5 and the bag filter 6, and an alkaline in the flue 9. A chemical supply means 10 for supplying slaked lime which is a chemical, a transfer means 11 for feeding back the collected matter collected by the bag filter 6 to the inlet of the air preheater 5, and an air preheater provided on the upstream side of the chemical supply means 10. 5 comprises a discharging means 12 for discharging dust.

The gas cooling chamber 4 cools high-temperature exhaust gas (about 750 to 950 ° C.) generated by combustion, and is provided to protect the filter cloth of the bag filter 6 from damage due to high temperature. The exhaust gas introduced into the gas cooling chamber 4 is cooled by exchanging heat energy with water.

The air preheater 5 is a device that heats air by using heat of exhaust gas, and is arranged on the downstream side of the gas cooling chamber 4. The air heated by the air preheater 5 is mainly used as combustion air in the incinerator 2.

The flue 9 is provided with a supply means 10 for supplying slaked lime. The supply means 10 has a spray nozzle 13 arranged in the flue 9, and slaked lime stored in a hopper (not shown) is opened from the spray nozzle 13 to the inside of the flue 9 by opening a ball valve 14. Is sprayed towards.

The bag filter 6 is connected to the downstream side of the air preheater 5 via a flue 9 and is a device having both a dust collecting function and a harmful substance removing function. The harmful substances contained in the exhaust gas are removed in two steps. That is, hydrogen chloride and sulfur oxide, which are acidic components in the exhaust gas, are neutralized by the slaked lime sprayed in the flue 9 communicating with the bag filter 6, and then the reaction generated by the neutralization reaction. The product is collected on the surface of a tubular filter cloth mounted in the bag filter 6. In addition to the reaction products, unreacted acidic components and unreacted slaked lime are collected by the filter cloth of the bag filter 6, and a part of the acidic components is on the thin film of unreacted slaked lime formed on the filter. React with. Further, the filter cloth of the bag filter 6 also collects soot dust, dioxins, and heavy metals.

These dusts adhering to the surface of the filter cloth are sometimes brushed off. This dust removal is usually performed by a method called an air pulse method or a pulse jet method. That is, although not shown, the air pipe extends from the air tank through the pulse valve into the tubular filter cloth, and the air pulsation generated by the pulse valve vibrates from the inside of the filter cloth to the filter cloth. And dust off the dust on the surface of the filter cloth. The dust removed is stored in the hopper 15 provided below the bag filter 6. A rotary valve 16 is provided below the hopper 15. The rotary valve 16 and the air preheater 5 are connected by a transfer means 11, and the collected matter collected by the bag filter 6 is guided to the inlet of the air preheater 5 by the transfer means 11. Since the collected material is powder, it is preferable to use, as the transfer means 11, a gas conveyor configured to transfer the powder by the air blown by the blower 21. The collected matter is sprayed from the spray nozzle 20 toward the inlet of the air preheater 5 by opening the ball valve 19.

A hopper 17 as a discharging means 12 and a rotary valve 18 are provided on the upstream side of the spray nozzle 13 provided in the flue 9. Dust such as soot dust accumulated in the hopper 17 is discharged to the outside by opening the rotary valve 18. The dust stored in the hopper 17 contains almost no unreacted acidic component or unreacted slaked lime. This is because the collected matter collected by the bag filter 6 contains unreacted slaked lime, but the unreacted slaked lime is returned to the inlet of the air preheater 5 through the transfer means 11. A neutralization reaction takes place between the air preheater 5 and the hopper 17 to form a reaction product. Therefore, the gas-solid reaction between the acid gas and slaked lime, which has conventionally been performed mainly in the flue 9, further proceeds in the air preheater 5. It should be noted that the air preheater 5 needs to be provided with a soot blower or the like to prevent dust from being accumulated in the air preheater 5. Further, since the exhaust gas is cooled by mixing the gas from the gas conveyor or the soot blower, the heat load on the bag filter 6 is reduced.

Next, the operation of this dry acidic exhaust gas treatment apparatus will be described. The waste that is brought in by the garbage truck is temporarily stored in the waste pit, and from there it is thrown into the input port 1 of the incinerator 2 one by one with a garbage crane. At the lower part of the charging port 1, there is a dust supply device for pushing in the dust, and by operating this dust is quantitatively supplied to the incinerator 2. The waste moves on the stoker 3 while burning in the incinerator 2 and becomes incinerated ash, which is discharged from the discharge port 22 in the lower part of the incinerator 2. Also, when the refuse burns in the incinerator 2, a very high temperature exhaust gas is generated, and this high temperature exhaust gas is sent to the gas cooling chamber 4 and cooled. The cooled exhaust gas is further cooled by heating the air in the air preheater 5.

The flue 9 leading from the air preheater 5 to the bag filter 6 is provided with a spray nozzle 13 that constitutes the drug supply means 10, and slaked lime is sprayed from the spray nozzle 13. The sprayed slaked lime neutralizes acidic components such as hydrogen chloride and sulfur oxides contained in the exhaust gas. The reaction product obtained by the neutralization reaction is collected on the surface of the filter cloth of the bag filter 6 together with unreacted acidic components, unreacted slaked lime, soot, dioxins, heavy metals and the like. Then, only the purified exhaust gas is exhausted into the atmosphere from a stack (not shown). On the other hand, the collected matter collected by the filter cloth is wiped off from the surface of the filter cloth by the air pulsation that is periodically supplied to vibrate the filter cloth from the inside of the filter cloth. In this way, the collected matter containing unreacted slaked lime is stored in the hopper 15 below the bag filter 6.

The collected matter stored in the hopper 15 is fed back by the transfer means 11 by opening the rotary valve 16 and supplied to the inlet of the air preheater 5. The slaked lime contained in the collected substance causes a neutralization reaction with the acidic components in the exhaust gas over a period of time from the inlet of the air preheater 5 to the flue 9 through the air preheater 5. . In this way, since a part of the exhaust gas undergoes a neutralization reaction in the first step to reduce the acidic components, the amount of slaked lime to be sprayed from the spray nozzle 13 in the second step can be considerably small. Further, since the part where the first step is performed is the air preheater 5, that is, the external gas heat exchanger directly connected to the incinerator 2, the neutralization reaction occurs under high concentration and high temperature acidic gas. The efficiency of gas-solid reaction is good. The mixture of the gas used for the transfer means 11 promotes the heat reduction of the exhaust gas. Further, in the bag filter 6, the amount of collected dust is reduced due to the improvement of the treatment efficiency in the preceding stage, the heat load due to the exhaust gas is reduced, and the life of the bag filter 6 is extended.

The dust circulates in the circulation path formed by the air preheater 5, the flue 9, the bag filter 6, and the transfer means 11, but the heavy substance accumulates in the hopper 17. Then, the substance accumulated in the hopper 17 is discharged to the outside by opening the rotary valve 18.

The dry acidic exhaust gas treatment apparatus according to the present invention shown in FIG. 1 and the conventional dry acidic exhaust gas treatment apparatus shown in FIG. 2 were used to compare their processing capacities. The results are shown in Tables 1 and 2. Table 1 compares the treatment capacities when the amount of chemicals used is the same (when the same amount of alkali agent is used). As can be seen from Table 1, the dry acidic exhaust gas treatment device of the present invention can treat exhaust gas at an equivalent ratio (gas / chemicals used) that is about three times that of conventional exhaust gas. The reaction efficiency at this time was 90% in the device of the present invention, compared with 80% in the conventional device.

[Table 1]

Table 2 compares the amounts of chemicals used at the maximum reaction efficiency. The maximum reaction efficiency is 95%, which is equivalent to that of the conventional equipment, and even under this condition, the processing capacity is about 2% of that of the conventional equipment. You can expect double.

[Table 2]

[0028]

[Effect of device]

 Since the dry acidic exhaust gas treatment device according to the present invention is configured as described above, it has the following effects. Since the unreacted alkaline chemicals collected by the filter type dust collector are introduced into the air preheater and supplied again into the high-concentration acidic gas, it is possible to take a long reaction time substantially. As a result, the gas-solid reaction efficiency is improved.

Further, since the gas-solid reaction between the acidic component in the exhaust gas and the alkaline chemical agent is carried out in two steps, that is, as the first step, the unreacted alkaline chemical agent collected by the filter type dust collector is reused. The air preheater is used to perform a gas-solid reaction, and the alkaline chemical is sprayed into the flue immediately before the filtration dust collector in the latter step, so the amount of new alkaline agent added in the latter step Is less.

Furthermore, since the amount of dust collected by the filtration type dust collector is reduced by improving the treatment efficiency in the previous stage, the dust load on the filtration type dust collector is reduced. If a gas conveyor is used as the transfer means or a soot blower is installed in the air preheater, the exhaust gas in the air preheater is cooled by the gas mixture, so the heat of the filter dust collector is reduced. The load is reduced. Therefore, there is an advantage that the service life of the filter cloth and the like equipped in the filter type dust collector is extended.

Further, since it is not necessary to add a large-scale device such as a special storage tank or a separating device, and only the installation of piping as a transfer means is required, which is space-saving and economical.

[Brief description of drawings]

FIG. 1 is a schematic view showing an embodiment of a dry acidic exhaust gas treatment apparatus according to the present invention.

FIG. 2 is a schematic diagram showing an example of a conventional dry acidic exhaust gas treatment apparatus.

[Explanation of symbols]

 2 incinerator 5 air preheater 6 bag filter (filter type dust collector) 9 flue 10 chemical supply means 11 transfer means 12 discharge means 13 spray nozzle

Claims (1)

[Scope of utility model registration request] 1. An air preheater for heating air with high-temperature exhaust gas, a filter type dust collector disposed downstream of the air preheater for removing harmful substances in the exhaust gas, the air preheater and the filtration type dust collector. A flue connecting the dust collector, a chemical supply means for supplying an alkaline chemical into the flue, a transfer means for feeding back the collected matter collected by the filtration type dust collector to the air preheater, and the flue. The dry acidic exhaust gas treatment apparatus having a discharge means for discharging dust in the air preheater provided on the upstream side of the chemical supply means.