JPH09141050A - Method for washing inside of gas absorber of smoke desulfirization plant and device therefor - Google Patents

Abstract

PROBLEM TO BE SOLVED: To wash a solid retaining part without changing a water balance of the whole device, to perform stable operation for a long time and to improve reliability. SOLUTION: When washing a solid retaining part inside a gas absorber 21 of a smoke desulfurization plant, a liquid absorbent gypsum slurry in a liquid storage part 24 is separated into a clarified liquid of <=10wt.% gypsum concentration and the other concentrate by a solid-liquid separating means 61, and the solid retaining part inside the gas absorber 21 is washed with the clarified liquid. The liquid after washing is returned again into the liquid absorbent, and also the concentrate is returned again into the liquid absorbent in the liquid storage part 24 at the same time.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a flue gas desulfurization plant for contacting exhaust gas with a limestone slurry absorption liquid by a gas absorption device, and further introducing air into the absorption liquid to remove sulfurous acid gas in the exhaust gas as gypsum. More specifically, the present invention relates to a method of cleaning the inside of a gas absorption device and a cleaning device. More specifically, the gas absorption loss pressure does not increase with time as compared with a conventional gas absorption device, and thus reliability can be improved. The present invention relates to a method for cleaning the inside of an apparatus and a cleaning apparatus.

[0002]

2. Description of the Related Art Wet gas treatment methods are widely used to remove harmful substances such as sulfurous acid gas from exhaust gas. Here, the wet exhaust gas treatment method is a method in which the exhaust gas and the absorbent are brought into gas-liquid contact to immobilize and remove harmful substances in the exhaust gas, for example, sulfurous acid gas in the exhaust gas as a sulfate.
The absorbing liquid used at this time is a slurry-like aqueous solution (hereinafter, abbreviated as absorbing liquid) containing an absorbing agent that fixes sulfurous acid gas as a sulfate, for example, one in which limestone is dissolved and / or suspended in water. Is.

Conventionally, the wet flue gas desulfurization method is mainly shown in FIG.
The absorption tower type wet flue gas desulfurization apparatus (flue gas desulfurization plant) as shown in FIG. This absorption tower type wet flue gas desulfurization apparatus includes a spray type absorption tower (gas absorption apparatus) 2, a limestone slurry tank 3, and a gypsum dehydrator 4. The exhaust gas is introduced into the absorption tower 2 from the absorption tower inlet duct 1. On the other hand, the absorption liquid stored in the liquid storage section 5 below the absorption tower 2 is pressurized by the slurry pump 6 and sprayed from the top of the absorption tower 2. The exhaust gas comes into gas-liquid contact with the absorbing liquid sprayed in the absorption tower 2, and the sulfur oxide in the exhaust gas,
Hazardous substances such as soot and dust are removed. Here, as the absorbing liquid, for example, limestone slurry is used as described above. This limestone slurry is adjusted to a predetermined concentration in the limestone slurry tank 3 and is supplied to the absorption tower 2 by a predetermined amount by the slurry supply pump 7.

The sulfurous acid gas in the exhaust gas is absorbed by the absorbing liquid and reacts with it, and is converted into calcium sulfite as a reaction product. This calcium sulfite is oxidized by surplus oxygen in the exhaust gas and oxygen in the air blown from the air supply pipe 8 into the absorption liquid layer of the liquid storage section 5 below the absorption tower 2 to become gypsum. The slurry containing the gypsum and the unreacted limestone thus generated is extracted from the absorption tower liquid storage section 5 by the slurry pump 6, a part of the slurry is sprayed as an absorption liquid from the top of the absorption tower, and the rest is in the tank 9 The concentrated slurry is extracted from the bottom by the transfer pump 10 and sent to the dehydrator 4, where it is dehydrated and recovered as powdered gypsum. On the other hand, a part of the filtrate after dehydration is temporarily stored in the dehydrator drainage tank 11, further pressurized by the dehydrator drainage pump 12, and reused as makeup water for the limestone slurry tank 3. The remaining portion of the filtrate after dehydration is sent to the wastewater treatment device 13 as wastewater. The exhaust gas treated in the absorption tower 2 is discharged into the atmosphere after the absorbing liquid mist entrained by the mist eliminator 14 is removed.

[0005]

In recent years, the demand for environmental protection has increased more and more, and the reliability of flue gas desulfurization equipment has been required, and the exhaust gas which can be continuously operated for a long period of one year or even two years or more. Smoke desulfurization equipment is required. However, in a flue gas desulfurization device using a limestone slurry as an absorbent, since limestone as an absorbent and gypsum as a by-product are solids, they are inherently poor in fluidity, and are uncontrolled in a vessel wall of a gas absorption device, particularly Mist eliminator,
Occurrence, accumulation, or sticking may occur in the downstream portion and / or upstream portion of the absorption zone, a pocket portion, etc. (hereinafter, staying, depositing, or sticking is collectively referred to as staying).

[0006] Such a solid retention portion is a portion to which the mist eliminator on the downstream side of the exhaust gas commonly applies in various flue gas desulfurization plants regardless of the type of absorption mechanism, for example, in a spray tower. In the exhaust gas treatment tower of the so-called packing packing method, in which the exhaust gas is dispersed in the absorption liquid through the packing, the solid part is clogged in the upper space of the packing. Is applicable. Further, in the jet pubbling method described later, such a place is limited, but solid matter may be deposited in a horizontal part such as a lower deck of the gas dispersion space or an upper deck of the gas collecting space. In any case, in this type of flue gas desulfurization plant, there is a common problem that a solid substance generated due to the removal of sulfurous acid gas has a common problem. It is desired to realize a low flue gas desulfurization absorption tank.

For this reason, conventionally, fluidization, that is, cleaning has been performed by applying a liquid to these solid retention portions at an appropriate flow rate (slurrying). However, when a sufficient amount of water is used as the liquid for the cleaning, the flue gas desulfurization device is operated with a water balance determined by the process, so that there is a problem that the amount of drainage increases as much as the cleaning. Therefore, in parallel with the operation of the flue gas desulfurization apparatus, make-up water from a make-up water supply line (not shown) for supplying make-up water to the limestone slurry tank 3 and a dehydrator drain tank 11 obtained by dehydration of gypsum slurry are provided. It is also possible to wash the solid stagnation site by supplying the mother liquor therein to the solid stagnation site via the discharge side branch pipe of the dehydrator drainage pump 12, but regarding the makeup water from the makeup water supply line Is used for cooling water for cooling the exhaust gas, and is not shown as a detailed line in FIG. 5, but is used for humidifying the oxidizing air supplied from the air supply pipe 8 or for various rotary machines. There are various uses such as sealing liquids, and since the flue gas desulfurization equipment as a whole is operated on a certain water balance, it is sufficient for cleaning the solid retention part mentioned above. There is a problem that it is difficult to secure the amount.

On the other hand, the mother liquor obtained by dehydration of the gypsum slurry has the following problems in addition to being used as a liquid which is supplied to the limestone slurry tank 3 to make limestone powder into a slurry. That is, for example, when the SO ₂ concentration in the exhaust gas is low, the amount of the absorbed liquid gypsum slurry taken out from the liquid storage section 5 of the absorption tower 2 decreases, so the amount of mother liquor separated in the gypsum dehydrator 4 also decreases. As a result, it becomes difficult to secure a sufficient amount of the cleaning liquid for cleaning the solid retention portion.

The present invention has been made to effectively solve the problems of the above-mentioned various conventional flue gas desulfurization plants, and it is possible to wash the solid retention portion without changing the water balance of the entire apparatus, Therefore, the amount of desulfurizable exhaust gas does not decrease over time due to the deposition of gypsum due to the dry-up of the absorption liquid, and stable operation can be performed for a long period of time, and the smoke emission has improved reliability. An object of the present invention is to provide a cleaning method and a cleaning device inside a gas absorption device of a flue gas desulfurization plant that can obtain a desulfurization plant.

[0010]

In order to achieve the above object, a method for cleaning the inside of a gas absorption device of a flue gas desulfurization plant according to the present invention according to claim 1 is a gas absorption device circulated and supplied with exhaust gas. In contact with the limestone slurry absorption liquid of the liquid storage portion, to further remove the sulfurous acid gas in the exhaust gas as gypsum slurry by introducing air into the absorption liquid, the slurry gypsum slurry generated in the liquid storage portion When the inside of the gas absorption device of the flue gas desulfurization plant that returns the mother liquor obtained as the absorption liquid after the pumping out and solid-liquid separation in a gypsum dewatering machine is recovered as gypsum, the absorption in the liquid storage part The liquid gypsum slurry is separated into a clear liquid having a gypsum concentration of 10 wt% or less and other concentrated liquid by a solid-liquid separating means, and the clear liquid is used for the gas absorbing device. Characterized in that the solid retention part of the part is washed and the liquid after washing is returned to the absorbing liquid again, and at the same time, the concentrated liquid is returned to the absorbing liquid in the liquid storing part again. Is. In addition, the gypsum concentration of the cleaning liquid is preferably 3 wt% by the solid-liquid separator.
It is more preferable to use an absorption liquid gypsum slurry that is a clear liquid of not more than 10%.

Here, the invention according to claim 2 is characterized in that the solid retention portion according to claim 1 is an upstream portion, an intermediate portion, or a downstream portion of the mist eliminator, Further, the invention according to claim 3 is characterized in that the gas absorption device is a jet bubbling type absorption reaction tank. Further, the invention according to claim 4 is the above solid when the gas absorption device according to claim 1 is a packing and filling type exhaust gas treatment tower in which exhaust gas is dispersed in an absorbing liquid through a packing. It is characterized in that the retention part is at least one of the upstream part and the downstream part of the gas absorption zone.

Next, the cleaning device inside the gas absorption device of the flue gas desulfurization plant according to the fifth aspect of the present invention collects the exhaust gas and the limestone slurry absorption liquid in the liquid storage part in the gas absorption device which is circulated and supplied. Contact and further introduce air into the absorption liquid to remove the sulfurous acid gas in the exhaust gas as a gypsum slurry, extract the gypsum slurry generated in the liquid storage section with a slurry pump, and perform solid-liquid separation in a gypsum dehydrator. A device for cleaning the inside of the gas absorption device of a flue gas desulfurization plant that returns the obtained mother liquor as the absorption liquid after recovering it as gypsum, wherein the absorption liquid gypsum slurry has a gypsum concentration of 10 wt% or less. With clearing fluid,
A solid-liquid separation device that solid-liquid separates into other concentrated liquid and supplies the clarified liquid as a cleaning liquid through a cleaning liquid supply pipe, and the above-mentioned cleaning liquid provided at the tip of the cleaning liquid supply pipe of this solid-liquid separation device. And a cleaning means for spraying the gas toward a solid retention portion inside the gas absorption device.

[0013] According to a sixth aspect of the invention, in the solid-liquid separation device according to the fifth aspect, a pump for sucking the absorbent gypsum slurry in the liquid storage section, and the absorbent taken out by the pump. A liquid cyclone for solid-liquid separation of the gypsum slurry, and a return pipe for returning the concentrated liquid separated by the liquid cyclone into the liquid storage section of the gas absorption device, on the other hand, Claim 7
The invention described in claim 5, wherein the solid-liquid separation device according to claim 5 is a pump for sucking the absorbent gypsum slurry in the liquid storage part, and a thickener for solid-liquid separating the absorbent gypsum slurry taken out by the pump. And a return pipe for returning the concentrated liquid separated by the thickener into the liquid storage portion of the gas absorption device.
Further, the invention according to claim 8 is characterized in that the pump according to claim 6 or 7 also serves as the slurry pump.

According to a ninth aspect of the present invention, the solid-liquid separation device according to the fifth aspect is integrally provided on the side wall of the liquid storage portion of the gas absorption device, and the clarified liquid is gravity-fed. It is characterized by comprising a solid-liquid separator to be obtained and a transfer pump for supplying the clarified liquid obtained by the solid-liquid separator to the washing device. The invention according to claim 10 is characterized in that the gas absorption device according to any one of claims 5 to 9 is a jet bubbling type absorption reaction tank.

According to the cleaning method of the present invention as defined in claim 1 and the cleaning device as defined in claim 5, a clarified liquid obtained by solid-liquid separation of the absorbent gypsum slurry produced in the liquid storage section. To the solid retention part of the gas absorption tower and its related equipment to eliminate the solid retention part by the cleaning action, preventing the gas passage loss pressure from increasing over time, and increasing the long-term flue gas desulfurization equipment. Stable operability can be ensured, and thus a flue gas desulfurization plant with improved reliability can be obtained. At this time, as the cleaning liquid, the absorption liquid gypsum slurry, which is a clarified liquid having a gypsum concentration of 10 wt% or less, preferably 3 wt% or less, is supplied by the solid-liquid separator. There is no need to consider erosion countermeasures separately. In addition, by the solid-liquid separation device, the absorption liquid gypsum slurry generated in the liquid storage part as a cleaning liquid is supplied, and the liquid after cleaning the solid retention part is the liquid storage part in the gas absorption tower. Since the cleaning liquid is sent into the absorbing liquid, the cleaning liquid is eventually recycled in the gas supply tower, and therefore does not affect the water balance of the entire apparatus.

Here, as the solid retention portion, as in the preferred embodiment of the present invention described in claim 2, the mist eliminator at the latter stage of the absorption zone is the most solid common to various flue gas desulfurization plants. It is a site that is easily attached, deposited, or fixed. In particular, in a spray type absorption tower, fine mist is separated along with solid matter at this portion, so that retention of solid matter is unavoidable. Therefore, by applying the method of the present invention to this portion, the solid matter is prevented from accumulating and the gas pressure loss of the flue gas is prevented from increasing. In addition, it is preferable to apply the liquid to the upstream side of the mist eliminator, and when the mist eliminator is installed in two stages, it is also effective to uniformly wash the mist eliminator by using a spraying means therebetween. Although it may be used sometimes downstream thereof, it is preferable to optimally distribute the cleaning liquid in consideration of the overall effect.

Further, at this time, it is desirable that the cleaning liquid contains a small amount of solids. In this respect, as in the invention described in claim 3 or 10, the cleaning liquid is applied to a jet bubbling type absorption reaction tank as the gas absorption device. In this case, the gypsum obtained has a large particle size, and thus the liquid after being separated in the solid-liquid separation device is extremely clear, which is preferable. In addition, after cleaning the solid retention part with the clarified liquid separated from the absorbent gypsum slurry in the liquid storage part, since it is returned to the liquid storage part again, fluctuations in the absorption liquid level in the liquid storage part occur. There is no inconvenience of giving.

Further, as the solid retention part different from the mist eliminator, for example, in an exhaust gas treatment tower of the packing filling type as in the invention of claim 4, it is an upstream part and a downstream part of the gas absorption zone, Therefore, by applying the cleaning method according to the present invention to at least one of these locations, it is possible to prevent solids from remaining and prevent the gas pressure loss of flue gas from increasing. Furthermore, as the solid retention site other than the above, in the liquid distribution header of the spray tower, the liquid distribution plate of the packed tower, or the jet bubbling type absorption reaction tank, the upper and / or lower deck, and generally, Is a position in a horizontal position in the gas phase constituent parts in the absorption tower, and even if it is a vertical or inclined part, the part where solid matter is likely to stay for some reason is the cleaning in the present invention. Is the target location of.

Here, according to the invention of claim 6,
Since the liquid cyclone excellent in the separation performance of the above-mentioned clear liquid is used as the solid-liquid separation device, the gypsum concentration is 10
It is possible to easily obtain a clarified liquid of wt% or less, more preferably 3 wt% or less, and supply it as the cleaning liquid.
Further, the concentrated liquid separated by the liquid cyclone is returned to the absorbing liquid in the gas absorbing device again via the return pipe, so that the recycling of the absorbing liquid is not disturbed. Further, as in the invention described in claim 7, a thickener may be used instead of the liquid cyclone. In these cases, according to the invention as set forth in claim 8, a pump for sending the absorbent gypsum slurry taken out from the gas absorption device to a liquid cyclone or thickener is a slurry pump for sending the absorbent gypsum slurry to a gypsum dewatering machine. It is also economical because it does not require a separate pump.

By the way, although it is possible to employ a solid-liquid separator such as a thickener in place of the liquid cyclone as in the invention described in claim 7, a solid-liquid separator is separately used. In that case, in addition to the solid-liquid separator, an intermediate tank for storing the clear liquid is required separately. However, in the invention described in claim 9, since the solid-liquid separator integrally provided on the side wall of the liquid storage part of the gas absorption device is used as the solid-liquid separation device, the absorption in the liquid storage part is performed. In the liquid-gypsum slurry, gypsum particles are separated by gravity in this solid-liquid separator into a clarified liquid, and the clarified liquid is supplied to the cleaning liquid supply pipe by a direct transfer pump. As a result, the above-mentioned intermediate tank is not required, which is economical and maintenance is easy.

[0021]

First Embodiment FIG. 1 shows a first embodiment in which a cleaning device inside a gas absorption device of a flue gas desulfurization plant according to the present invention is applied to the absorption tower type wet flue gas desulfurization plant shown in FIG. The same components as those shown in FIG. 5 are designated by the same reference numerals and the description thereof will be omitted. In this absorption tower type wet flue gas desulfurization plant in FIG. 1, an absorption gypsum slurry composed of a slurry containing gypsum produced in the absorption tower (gas absorption device) 2 and unreacted limestone is clarified with other liquids. A solid-liquid separation device 16 for performing solid-liquid separation into a concentrated liquid and supplying the obtained clear liquid as a cleaning liquid to the mist eliminator 14 via a cleaning liquid supply pipe 15, and a cleaning liquid supply pipe 15 of the solid-liquid separation device 16. A cleaning device is provided at the tip of the nozzle and has a spray nozzle (cleaning means) (not shown) that sprays the cleaning liquid toward the mist eliminator 14.

Here, the solid-liquid separation device 16 uses the slurry pump (pump) 6 for sucking the absorbing liquid gypsum slurry in the liquid storing portion 5 and the absorbing liquid gypsum slurry taken out by the slurry pump 6. A pipeline 17 that is branched to the line 9a that is transferred to the tank 9, and the pipeline 17
A liquid cyclone 18 disposed at the tip of the liquid cyclone 18 for solid-liquid separation of the absorption gypsum slurry, and a return from the bottom of the liquid cyclone 18 into the liquid storage part 5 of the absorption tower (gas absorption device) 2. The absorption liquid gypsum slurry, which is composed of a pipe 19 and is continuously or intermittently transferred from the slurry pump 6 to the liquid cyclone 18 via the pipe 17, has a gypsum concentration of 10 in the liquid cyclone 18.
The liquid is separated into a clear liquid of less than wt%, preferably 3 wt% and another concentrated liquid, and the concentrated liquid is directly returned to the absorption tower 2 through the return pipe 19.

As a result, in the flue gas desulfurization plant, the mist eliminator 14 is intermittently or continuously supplied with the cleaning liquid supplied from the cleaning liquid supply pipe 15 in parallel with the operation of the flue gas desulfurization device. Since solid matter such as gypsum and dust ash that has accumulated or deposited can be dissolved and washed, there is no risk of the amount of desulfurizable exhaust gas decreasing with time due to the solid matter of gypsum, etc. You can drive your car. Moreover, as the cleaning liquid, the clear liquid separated from the absorbent gypsum slurry generated in the liquid storage portion 5 is supplied, and the liquid that has washed the mist eliminator 14 is returned to the absorption liquid in the liquid storage portion 5 again. Therefore, the cleaning liquid is eventually recycled in the absorption tower 2, and therefore does not affect the water balance of the entire apparatus. In addition, since the liquid cyclone 18 uses a clarified liquid having a gypsum concentration of 10 wt% or less, more preferably 3 wt% or less, the mist eliminator 14 needs to separately take measures against erosion caused by gypsum particles. There is no.

[0024]

[Embodiment 2] FIG. 2 shows a second embodiment in which the cleaning device inside the gas absorption device of the flue gas desulfurization plant according to the present invention is applied to the jet bubbling type absorption reaction tank of the flue gas desulfurization plant. Since the configuration of the plant other than the reaction tank is substantially the same as that shown in FIGS. 1 and 5, the same components are designated by the same reference numerals to simplify the description. In FIG. 2, the inside of the reaction tank (gas absorber) 21 is formed by a disk-shaped lower deck 22 and an upper deck 23 that serve as partition walls.
A liquid storage part 24 for storing an absorption liquid composed of an aqueous solution in which CO ₃ ) is dissolved or suspended at a constant liquid level, and an inlet plenum 26 connected between the upper and lower decks 22, 23 and an exhaust gas inlet duct 25. And an outlet plenum 28 above the upper deck 23 and communicating with the exhaust gas outlet duct 27.
It is defined as The lower deck 22 is provided with a large number of openings, and sparger pipes 29 are vertically provided in the openings. Here, each sparger pipe 29 is set to have a length dimension such that its lower end opening is located below the initial absorption liquid surface, and exhaust gas ejection holes are formed in the lower outer peripheral wall in the absorption liquid. Has been drilled. On the other hand, between the lower deck 22 and the upper deck 23, there are arranged gas risers 30 for communicating the space on the liquid absorption surface of the liquid storage portion 24 to the outlet plenum 28 side, and the outlet duct 27. A mist eliminator 31 is provided inside.

Also in this flue gas desulfurization plant, an absorption liquid gypsum slurry composed of a slurry containing gypsum produced in the reaction tank (gas absorption device) 21 and unreacted limestone was obtained by solid-liquid separation. A solid-liquid separation device 61 for supplying the above-mentioned clarified liquid as a cleaning liquid to the mist eliminator 31, which is a solid retention site, through the cleaning liquid supply pipe 60, and a tip portion of the cleaning liquid supply pipe 60 of this solid-liquid separation device 61. A spray nozzle (cleaning means), not shown, for spraying the cleaning liquid toward the mist eliminator 31.
And a cleaning device is provided. As shown in FIG. 2, the cleaning liquid supply device 61 includes the above-described slurry pump (pump) 6 for sucking the absorbing liquid gypsum slurry in the liquid storing section 24, and the absorbing liquid gypsum slurry taken out by the slurry pump 6. A discharge pipe 62 branching to a discharge pipe 9a for sending the water to the gypsum dewatering machine 4 via the tank 9, and a liquid cyclone 63 for solid-liquid separation of the absorbing liquid gypsum slurry by connecting the tip end of the discharge pipe 62 to the liquid. And a return pipe 64 for returning the concentrated liquid separated by the liquid cyclone 63 into the liquid storage section 24 of the reaction tank 21.

In the above flue gas desulfurization plant,
If necessary, the cleaning solution may be added to the upper and lower decks 2 of the reaction tank 21.
The upper and lower decks 22 and 23 may be cleaned by spraying the upper and lower decks 22 and 23. In order to remove, for example, sulfur dioxide (SO ₂ ) contained in the exhaust gas of the boiler by the flue gas desulfurization plant using the reaction tank 21 having the above-mentioned configuration, the exhaust gas was previously provided in the preceding stage of the reaction tank 21. In the cooler, a part of the absorbing liquid is humidified and cooled by the cooling water used as the circulating water, and then the air is sent from the inlet duct 25 to the inlet plenum 26.
Then, the exhaust gas is horizontally ejected from the lower end ejection holes of each sparger pipe 29 and vigorously mixed with the absorbing liquid to form a liquid-phase continuous jet bubbling layer. Then, highly efficient gas-liquid contact is performed in this jet bubbling layer, and SO ₂ is absorbed. In this way, the desulfurized exhaust gas is collected in the outlet plenum 28 via the gas riser 30 and discharged from the outlet duct 27 to the outside via the mist eliminator 31.

In parallel with this, by oxidizing and neutralizing SO ₂ , gypsum is produced in the absorbing solution, and the crystal grows into coarse particles to form an absorbing solution gypsum slurry. Then, the absorbent gypsum slurry is extracted from the liquid storage section 24 of the reaction tank 21 by the slurry pump 6 and sent to the liquid cyclone 63 from the discharge pipe 62. Then, the absorbing liquid gypsum slurry is subjected to solid-liquid separation in the liquid cyclone 63, and separated into a clear liquid having a gypsum concentration of 3 wt% or less and other concentrated liquid, and the concentrated liquid is returned from the return pipe 64 to the reaction tank again. It is returned to the liquid storage part 24 in 21. On the other hand, the clarified liquid is sent to the cleaning liquid supply pipe 60,
The gypsum component deposited on the mist eliminator 31 is washed by being sprayed from the spray nozzle. Then, the liquid after cleaning is returned to the absorbing liquid in the liquid storage portion 24 of the reaction tank 21 again.

Therefore, the flue gas desulfurization apparatus can also dissolve and wash the solid stagnation portion in the mist eliminator 31 in parallel with the operation of the flue gas desulfurization apparatus. Since there is no possibility that the amount of exhaust gas that can be desulfurized is reduced, stable operation can be performed for a long period of time, and the washed liquid is returned to the absorption liquid in the liquid storage section 24 again, so Since the cleaning liquid is recycled in the reaction tank 24, it does not affect the water balance of the entire apparatus. At this time, particularly in the jet bubbling type absorption reaction tank 21, the obtained gypsum had a large particle size, and the filtrate or mother liquor after dehydration was extremely clear, so that it was superior to that shown in FIG. A cleaning effect can be obtained. In addition, after cleaning the mist eliminator 31 with the clarified liquid separated from the absorbent gypsum slurry in the liquid storage section 24, the mist eliminator 31 is washed again.
Since it is returned to the inside, there is no inconvenience that the absorption liquid surface in the liquid storage portion 24 is changed.

[0029]

[Third Embodiment] FIG. 3 shows a third embodiment of the cleaning device inside the gas absorption device of the flue gas desulfurization plant according to the present invention. The same components as those shown in FIG. The same reference numerals are given and the description thereof is omitted. In FIG. 3, in the flue gas deplantation plant of this example, a cleaning device using a solid-liquid separation device 70 is provided in place of the solid-liquid separation device 61. This solid-liquid separator 70 is a thickener (solid-liquid separator) 71 integrally provided on the side wall of the liquid storage section 24 of the reaction tank 21, and a clarifier stored in a clarified liquid tank 71 a of the thickener 71. It comprises a transfer pump 72 for transferring the liquid, and a cleaning liquid supply pipe 73 led from the discharge side of the transfer pump 72 to the mist eliminator 31. Here, inside the thickener 71, a partition plate 74 for performing solid-liquid separation of the absorbing liquid gypsum slurry, which hangs from the ceiling portion to below the absorbing liquid surface, and a standing plate from the bottom surface side to the vicinity of the absorbing liquid surface. The provided partition plates 75 are alternately arranged.

In the flue gas desulfurization plant having the above structure, the transfer pump 72 sends the clarified liquid stored in the clarified liquid tank 71a of the thickener 71 to the spray nozzle at the tip thereof through the cleaning liquid supply pipe 73. The solid-liquid retention part in the mist eliminator 31 is washed. On the other hand, as the clearing liquid in the clearing liquid tank 71a of the thickener 71 is sucked by the transfer pump 72,
The new absorption gypsum slurry is supplied into the thickener 71, and is separated into solid and liquid by gravity as it passes through the partition plate 74, and the clear liquid is further stored in the clear liquid tank 71a. In parallel with this, the gypsum particle component separated by the thickener 71 is returned as it is to the absorbing liquid in the liquid storage section 24.

Therefore, even in the flue gas desulfurization apparatus of this example, it is possible to obtain the same operation and effect as those in the second embodiment, and further, as the solid-liquid separation apparatus 70, the reaction tank 21 Since the thickener 71 integrally arranged on the side wall of the liquid storage portion 24 is used, the absorbent gypsum slurry in the liquid storage portion 24 is subjected to solid-liquid separation by gravity in the thickener 71, and the obtained clear liquid is directly The transfer pump 72 can supply the solids to be washed to the accumulated portion, which is economical without the need for an intermediate tank or the like for storing the clarifying liquid, and has an effect of facilitating maintenance management. .

Instead of the thickener 71 shown in FIG. 3, for example, as shown in FIG. 4, a thickener (solid) having a plurality of inclined plates 80 ... A liquid separator) 81 is provided, and the clearing liquid stored in the clearing liquid tank 81a of the thickener 81 is transferred to the pump 7
Alternatively, the water may be supplied as cleaning water. Further, in the description of the above embodiment, the cleaning device inside the gas absorption device of the flue gas desulfurization plant according to the present invention is a flue gas desulfurization system using an absorption tower type wet flue gas desulfurization plant and a jet publing reaction tank. Although the case where it is applied to the plant has been described, the present invention is not limited to this, and the exhaust gas absorption tower in the flue gas desulfurization plant using the exhaust gas treatment tower of the packing filling method in which the exhaust gas is dispersed in the absorption liquid through the filling material Even if it is applied to the cleaning of at least one of the upstream part and the downstream part of the gas absorption zone, the same effect can be obtained.

[0033]

As described above, according to the method of cleaning the inside of the gas absorption device of the flue gas desulfurization plant and the cleaning device according to the present invention, the required water balance of the flue gas desulfurization plant is not impaired and the conventional method is used. It is possible to obtain a gas absorption device having improved reliability, in which the gas passage loss pressure does not increase with time as compared with the gas absorption device described in (1). In particular, when the present invention is applied to a plant for treating flue gas using a jet bubbling type gas-liquid contact mechanism as in the invention described in claim 3 or 7, since the particle size of the gypsum produced is large, it is clear. A mother liquor can be obtained, and therefore, by using this as a cleaning liquid, an excellent cleaning effect can be obtained.

[Brief description of the drawings]

FIG. 1 is a schematic system diagram showing a first embodiment of a cleaning device according to the present invention.

FIG. 2 is a schematic system diagram showing a second embodiment of a cleaning device according to the present invention.

FIG. 3 is a schematic system diagram showing a third embodiment of a cleaning device according to the present invention.

FIG. 4 is a schematic configuration diagram of a main part showing a modified example of the solid-liquid separation device of FIG.

FIG. 5 is a schematic system diagram of a conventional spray tower type wet flue gas desulfurization plant.

[Explanation of symbols]

2 Absorption tower (gas absorption device) 4 Gypsum dehydrator 5, 24 Liquid storage part 6 Slurry pump 8 Air supply pipe 14, 31 Mist eliminator 15, 60, 73 Cleaning liquid supply pipe 16, 61, 70 Solid-liquid separation device (solid-liquid separation device Separation means) 18, 63 Liquid cyclone 19, 64 Return pipe 21 Jet bubbling type absorption reaction tank (gas absorption device) 71, 81 Thickener (solid-liquid separator) 72 Transfer pump

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁶ Identification code Internal reference number FI Technical display location B01D 53/34 ZAB B01D 47/00 Z B04C 9/00 53/34 ZAB // B01D 47/00 125E

Claims (10)

[Claims] 1. Exhaust gas is brought into contact with a limestone slurry absorbing liquid in a liquid storage portion in a gas absorption device which is circulated and supplied, and air is introduced into the absorbing liquid to remove sulfurous acid gas in the exhaust gas as gypsum slurry. Along with, the gypsum slurry generated in the liquid storage part is extracted by a slurry pump, and after recovering as gypsum by solid-liquid separation in a gypsum dehydrator, the obtained mother liquor is returned as the absorption liquid to the gas in the flue gas desulfurization plant. A method for cleaning the inside of an absorption device, wherein the absorption liquid gypsum slurry in the liquid storage section is separated into a clarified liquid having a gypsum concentration of 10 wt% or less and other concentrated liquid by a solid-liquid separation means, and the clarified liquid is used. The solid retention part inside the gas absorption device is washed, and the liquid after washing is returned to the absorption liquid again, and in parallel with this, the concentrated liquid is stored again in the liquid storage. A method for cleaning the inside of a gas absorption device of a flue gas desulfurization plant, which is characterized in that the gas is returned to the absorption liquid inside the section. 2. The method for cleaning the inside of a gas absorption device of a flue gas desulfurization plant according to claim 1, wherein the solid retention portion is an upstream portion, an intermediate portion, or a downstream portion of the mist eliminator. 3. The method for cleaning the inside of a gas absorber of a flue gas desulfurization plant according to claim 1, wherein the gas absorber is a jet bubbling type absorption reaction tank. 4. The gas absorption device is an exhaust gas treatment tower of a packing filling type in which exhaust gas is dispersed in an absorption liquid through a packing, and the solid retention portion is an upstream part and a downstream part of the gas absorption zone. The method for cleaning the inside of a gas absorption device of a flue gas desulfurization plant according to claim 1, wherein the method is at least one of the above. 5. The flue gas is brought into contact with the limestone slurry absorbing liquid in the liquid storage portion in the gas absorption device which is circulated and supplied, and air is introduced into the absorbing liquid to remove the sulfurous acid gas in the flue gas as a gypsum slurry. Along with, the gypsum slurry generated in the liquid storage part is extracted by a slurry pump, and after recovering as gypsum by solid-liquid separation in a gypsum dehydrator, the obtained mother liquor is returned as the absorption liquid to the gas in the flue gas desulfurization plant. A device for cleaning the inside of an absorption device, wherein the absorption liquid gypsum slurry is solid-liquid separated into a clear liquid having a gypsum concentration of 10 wt% or less and other concentrated liquids, and the clear liquid is passed through a cleaning liquid supply pipe. And a solid-liquid separation device that supplies the cleaning liquid as a cleaning liquid, and the cleaning liquid is provided at the tip of the cleaning liquid supply pipe of the solid-liquid separation device to direct the cleaning liquid to a solid retention portion inside the gas absorption device. And a cleaning device for injecting the gas into the gas absorption device of the flue gas desulfurization plant. 6. The solid-liquid separation device comprises a pump for sucking the absorption gypsum slurry in the liquid storage part, a liquid cyclone for solid-liquid separation of the absorption gypsum slurry taken out by the pump, and a liquid cyclone. The flue gas desulfurization device inside the gas sorption device of the flue gas desulfurization plant according to claim 5, further comprising a return pipe for returning the separated concentrated liquid to the liquid storage part of the gas absorption device. 7. The solid-liquid separation device comprises: a pump for sucking the absorbent gypsum slurry in the liquid storage section; a thickener for solid-liquid separating the absorbent gypsum slurry taken out by the pump; and a thickener for separating the solid-liquid separator. The flue gas desulfurization device inside the gas sorption device of the flue gas desulfurization plant according to claim 5, further comprising a return pipe for returning the concentrated liquid to the liquid storage portion of the gas absorption device. 8. The flue gas desulfurization apparatus inside a gas absorption device of a flue gas desulfurization plant according to claim 6, wherein the pump also serves as the slurry pump. 9. The solid-liquid separator is a solid-liquid separator that is integrally provided on a side wall of a liquid storage portion of the gas absorption device to obtain the clear liquid by gravity, and is obtained by the solid-liquid separator. The flue gas desulfurization apparatus inside the gas absorption apparatus of the flue gas desulfurization plant according to claim 5, further comprising a transfer pump that supplies the clarified liquid to the cleaning apparatus. 10. The cleaning device for the inside of a gas absorption device of a flue gas desulfurization plant according to claim 5, wherein the gas absorption device is a jet bubbling type absorption reaction tank.