JPH10128055A - Flue gas desulfurizer and gypsum slurry treatment - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a flue gas desulfurizer and a method for treating gypsum slurry from which the chlorine concentration and moisture content are decreased to obtain gypsum of high quality increasing washing water for gypsum slurry. SOLUTION: Ths flue gas desulfurizer removes gaseous SO2 from waste gas as gypsum slurry and subjects it to solid-liquid separation in a gypsum separator to obtain gypsum of high quality. In this case, gypsum separator is a belt type vacuum dehydrator 50 in which and endless filter cloth 55 is supported on a belt 52 having gas permeability spread between drums 51 so as to be freely traveled and at least gypsum fed onto the filter cloth 52 from a feed tank is sucked from a dehydrating chamber 53 installed below the belt and held at negative pressure to separate it into filtrate and gypsum. On the downstream side of a feed tank 62 of the belt type vacuum dehydrator 50, a steam washing/drying device 65 is arranged in which moisture is vaporized from at least the conveyed gypsum slurry to dehydrate it.

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 device for removing sulfurous acid gas in exhaust gas as gypsum, and a gypsum slurry for separating the gypsum from a gypsum slurry produced in the flue gas desulfurization device. In the processing method.

[0002]

2. Description of the Related Art Conventionally, as one type of flue gas desulfurization apparatus for removing harmful components such as sulfurous acid gas from exhaust gas from boilers, various heating furnaces or incinerators, etc., sulfurous acid gas (SO ₂ ) The sulfur oxides mainly composed of an aqueous solution in which limestone (CaCO ₃ ) is dissolved or suspended are brought into contact with an absorbing solution to neutralize the sulfur oxides. Smoke desulfurization equipment is widely used. FIG. 2 shows a main part of this type of conventional wet flue gas desulfurization apparatus having a jet bubbling type reaction tank. In FIG. 2, reference numeral 1 denotes a reaction tank in the flue gas desulfurization apparatus,
Limestone (Ca) is formed in the reaction tank 1 by a disc-shaped or square-plate-shaped lower deck 2 and upper deck 3 serving as partition walls.
Absorbent solution 4 consisting of an aqueous solution in which CO ₃ is dissolved or suspended
And a storage section for storing the gas at a constant liquid level, an inlet plenum 6 between the upper and lower decks 2 and 3 to which an exhaust gas inlet duct 5 is connected, and an exhaust gas outlet duct 7 above the upper deck 3. Exit plenum 8. A large number of openings are formed in the lower deck 2, and sparger pipes 9 are suspended from each of the openings, and a lower outer periphery of each sparger pipe 9 in the absorbent 4. Exhaust holes for exhaust gas are drilled in the wall.
On the other hand, between the lower deck 2 and the upper deck 3, gas risers 10 are arranged to communicate a space on the absorbent surface of the storage section to the outlet plenum 8 side. Is provided with a mist eliminator 11. The symbol 12 in the figure indicates the absorption liquid 4 in the reaction tank 1.
An oxidizing air supply pipe for introducing oxidizing air into the inside.

[0003] In this flue gas desulfurization apparatus, a gypsum separator 16 for extracting gypsum slurry produced in the reaction tank 1 via a transfer pipe 15 by a pump 14 and separating the gypsum from the gypsum slurry is used.
Is provided, and the gypsum 1 in the gypsum separator 16 is provided.
The mother liquor from which 7 has been separated is once stored in a mother liquor tank 18 and then used as a part of the absorbing solution 4 in the reaction tank 1 via a pump 19 or the mist eliminator 11
Is returned to the system as washing water.

[0004] With the flue gas desulfurization apparatus having the above structure,
For example, in order to remove sulfurous acid gas and the like contained in the exhaust gas from the boiler, the exhaust gas is first sent from the inlet duct 5 to the inlet plenum 6 and is ejected horizontally from the lower end ejection hole of each sparger pipe 9. Then, the exhaust gas is mixed vigorously with the absorbing liquid 4 to form a liquid-phase continuous jet bubbling layer. In this jet bubbling layer, highly efficient gas-liquid contact is carried out, so that SO ₂ is absorbed. The desulfurized exhaust gas is collected in the outlet plenum 8 via the gas riser 10 and discharged from the outlet duct 7 through the mist eliminator 11 to the outside.

In parallel with this, by oxidizing and neutralizing SO ₂ , gypsum is formed in the absorbing solution 4, and the gypsum grows into coarse particles to form a gypsum slurry. When this reaches a predetermined concentration, it is withdrawn from the bottom of the reaction tank 1, sent to a gypsum separator 16 via a transfer pipe 15 by a pump 14 and separated into mother liquor and gypsum 17. Is supplied as a raw material for a gypsum board or as a cement mixture.

[0006]

In the above-mentioned conventional flue gas desulfurization apparatus, the gypsum separator 16 is
What used the centrifugal separator which mainly separated a gypsum slurry into solid and liquid by centrifugal force by high-speed rotation was used. However, the flue gas desulfurization apparatus using the centrifugal separator as the gypsum separator 16 has a problem that the centrifugal separator is expensive. Further, in the above-mentioned flue gas desulfurization device, when it is attempted to reduce the amount of wastewater generated in the system relating to the flue gas desulfurization device including the power generation equipment provided with the same, the chlorine concentration in the reaction tank increases, and as a result, Since the chlorine concentration in the gypsum as a product also increases, it is necessary to wash the gypsum in the gypsum separator to reduce the chlorine concentration in the gypsum. However, in the gypsum separator 16 using such a centrifugal separator, Therefore, there was a problem that the above-mentioned gypsum could not be washed.

Therefore, conventionally, it has been proposed to use a belt-type vacuum dehydrator as shown in FIG. 3 as the gypsum separator 16 instead of the centrifugal separator. The belt-type vacuum dehydrator 30 includes drums 31 and 3 that are rotationally driven.
Belt 3 having a number of holes perforated and having air permeability
2 is stretched and a lower part of the upper belt is -30.
A dehydration chamber 33 that is evacuated to a vacuum of 0 to -600 mmHg is provided, and on the belt 32, an endless filter cloth 35 wound around a number of rollers 34. It is a schematic configuration, and above the filter cloth 35 on the belt 32, the filter cloth 35 indicated by an arrow in the drawing is provided.
Gypsum slurry 3 on filter cloth 35 sequentially along the traveling direction of
A supply tank 37 for flowing down 6 and a cake washing spray 38 for washing cake that is supplied onto the filter cloth 35 and moves while being filtered are provided. A filtrate drainage pipe 39 for draining the filtrate removed by suction into a filtrate tank (not shown) is connected to the bottom of the dehydration chamber 33. Reference numeral 41 in the figure denotes a spray disposed on both sides of the filter cloth 35 for cleaning the filter cloth 35.

[0008] The belt-type vacuum dehydrator 30 having the above configuration
In order to process the gypsum slurry using the gypsum, the gypsum slurry is supplied from the supply tank 37 onto the filter cloth 35 while rotating the drum 31 to move the filter cloth 35 rightward in the figure via the belt 32. At the same time, the washing water is ejected from the cake washing spray 38 to wash the cake transferred on the filter cloth 35. Thereby, the moisture in the cake on the filter cloth 35 is
Gypsum 4 that has been sucked and removed and separated into the dehydration chamber 33
0 is collected from the right end of the filter cloth 35 on a belt conveyor or the like (not shown), and the filtrate separated and removed to the dehydration chamber 33 is drained from the filtrate drain pipe 39 to the filtrate tank. go. Such a gypsum separator 1 in FIG.
6, according to the conventional flue gas desulfurization apparatus using the belt-type vacuum dehydrator 30 and the method for treating gypsum slurry in the flue gas desulfurization apparatus, equipment costs are reduced as compared with the case of using a centrifugal separator. In addition to being able to reduce, even when a gypsum slurry having a high chlorine concentration is supplied, it can be washed.

However, the belt type vacuum dehydrator 3
In the method for treating gypsum slurry using No. 0, there is a problem that moisture in the gypsum slurry increases due to fine particles in the drainage slurry, and further, the fine particles reduce the air permeability of the gypsum slurry and the filtration speed Therefore, there is a problem that it is difficult to obtain gypsum having a water content of 15 to 20% by weight or less, which is generally required.

Particularly, in the above-mentioned flue gas desulfurization apparatus,
In recent years, the cost of treating the generated wastewater sludge has increased in the integrated wastewater treatment of power generation facilities equipped with such facilities, and it has become difficult to discard this type of sludge depending on the location due to the strengthening of environmental standards. Then, the wastewater containing dust and trace components is neutralized in a neutralization tank, and the wastewater slurry obtained by concentrating the wastewater with a concentrator is mixed with the gypsum slurry and dewatered by the belt vacuum dehydrator 30. By performing the treatment, there is also a treatment of recovering as low-grade gypsum used as a cement mixture or the like. However, since the concentration of chlorine (Cl ⁻ ) in the obtained gypsum increases with the reduction in the amount of drainage, when the gypsum slurry and the drainage slurry are mixed as described above, the cake is sufficiently washed to remove the chloride. Increasing the amount of washing water from the washing spray 38 further deteriorates the permeability of the cake and lowers the filtration rate, thereby making it difficult to reduce the water content in the gypsum to a desired value. was there.

The present invention has been made to effectively solve the problems of the conventional flue gas desulfurization apparatus and the method for treating gypsum slurry in the flue gas desulfurization apparatus. Provided is a flue gas desulfurization apparatus and a gypsum slurry treatment method capable of obtaining high-quality gypsum by reducing chlorine concentration and water content without increasing washing water of the gypsum slurry when gypsum is separated. The purpose is to do so.

[0012]

According to a first aspect of the present invention, there is provided a flue gas desulfurization apparatus according to the present invention, wherein exhaust gas is brought into contact with an absorbent containing a Ca component which is circulated and supplied, and air is introduced into the absorbent. In the flue gas desulfurization device, the sulfurous acid gas is removed as gypsum slurry from the exhaust gas, the generated gypsum slurry is extracted, solid-liquid separated in a gypsum separator and collected as gypsum. An endless filter cloth is movably supported on an air-permeable belt stretched over, and a gypsum slurry supplied from a supply tank on the filter cloth is provided below the belt and held at a negative pressure. Is a belt-type vacuum dehydrator that separates the filtrate and the plaster by suction from the dehydration chamber, and the plaster conveyed above a filter cloth located downstream of a supply tank of the belt-type vacuum dehydrator. Sura It is characterized in that it has provided the steam cleaning and drying apparatus for dehydrating moisture from over.

According to a second aspect of the present invention, there is provided a mixing tank for mixing the gypsum slurry and the wastewater slurry from wastewater treatment equipment at a stage preceding the gypsum separator according to the first invention, The gypsum slurry and the drainage slurry mixed in the mixing tank are supplied to the supply tank.

Next, the method for treating a gypsum slurry according to the present invention according to claim 3 is characterized in that the exhaust gas and Ca circulated and supplied are provided.
While contacting the absorbent containing the components, air was introduced into the absorbent to remove sulfurous acid gas from the exhaust gas as a gypsum slurry, the generated gypsum slurry was extracted, and solid-liquid separated in a gypsum separator. In the method for treating a gypsum slurry collected as gypsum, the gypsum slurry is supplied onto a filter cloth of the belt-type vacuum dehydrator according to claim 1, and the water is separated by suction from a dehydration chamber, and further, By spraying steam with a steam cleaning and drying device to reduce the water content,
It is characterized by obtaining a gypsum having a desired moisture content or less.

Further, according to a fourth aspect of the present invention, there is provided a mixture containing a chlorine component generated by collecting a content in an exhaust gas obtained by mixing a wastewater slurry with the gypsum slurry according to the third aspect. By supplying the slurry onto the filter cloth, steam is sprayed by the steam cleaning / drying device to remove water and to remove a chlorine component in the mixed slurry.

In the flue gas desulfurization apparatus according to the first aspect and the method for treating a gypsum slurry according to the third aspect using the same, while rotating the drum to move the filter cloth supported on the belt, Supply gypsum slurry on the filter cloth,
The moisture in the cake on the filter cloth is removed by suction from below the air-permeable belt, and a predetermined amount of steam is sprayed on the cake by a steam washing / drying device. Then, the water adhering to the gypsum in the cake is heated by the sprayed steam, the viscosity is reduced, and the moisture is removed by increasing the air permeability. Along with this, the chlorine component and the like contained in the adhesion water are also removed. Therefore, according to the flue gas desulfurization apparatus and the method for treating gypsum slurry, continuous treatment of the gypsum slurry can be performed by continuous operation, and the chlorine concentration and the water content can be reduced without increasing the washing water of the cake. It is possible to obtain high quality gypsum.

Therefore, as in the flue gas desulfurization apparatus according to the second aspect and the method for treating a gypsum slurry according to the fourth aspect, the chlorine component obtained by mixing the wastewater slurry with the gypsum slurry. In the case of treating a mixed slurry containing a large amount of gypsum, the above-mentioned chlorine component is sufficiently removed, and a remarkable action and effect is obtained such that high-quality gypsum having a water content reduced to a desired value or less can be obtained.

[0018]

FIG. 1 shows a main part of an embodiment of a flue gas desulfurization apparatus according to the present invention. Other parts are the same as those shown in FIG. In the description, the same reference numerals are given and the description is omitted. FIG. 1 shows a configuration of a gypsum separator in the present flue gas desulfurization apparatus, and this gypsum separator uses a horizontal belt type vacuum dehydrator 50. Here, the horizontal belt type vacuum dehydrator 50 has a rubber belt 52 having a large number of holes formed between the rotatably driven drums 51 and 51 and having air permeability and rotatably stretched together with the drum 51. The lower part of the belt 52 located on the upper side is provided with -300 to -600.
A dehydration chamber 53 that is evacuated to a vacuum of mmHg is provided. On the belt 52, a number of rollers 54 are provided.
An endless filter cloth 55 made of polypropylene, polyester, or the like, which is rotatably wound in between, is supported along with the belt 52 so as to be freely movable in a direction indicated by an arrow in the drawing. In addition, a filtrate drain pipe 56 for draining the filtrate removed by suction into a filtrate tank (not shown) is connected to the bottom of the dehydration chamber 53. The reference numeral 57 in the drawing denotes the filter cloth 55.
A separation plate for forcibly removing gypsum from above.

Further, in the flue gas desulfurization apparatus, the drain slurry pipe 23 piped to the outlet side of the concentrator in the integrated waste water treatment facility of the power generation facility provided with the flue gas desulfurization apparatus is the horizontal belt type. It is led to the vacuum dehydrator 50. As shown in FIG. 1, near the horizontal belt type vacuum dehydrator 50, the drainage slurry sent from the drainage slurry pipe 23 and the gypsum slurry sent from the transfer pipe 15 by the pump 14 are used. The mixing tank 60 for mixing is provided. Then, above the filter cloth 55 on the belt 53, a mixed slurry of the gypsum slurry and the drainage slurry that are sequentially mixed in the mixing tank 60 and sent from the supply pipe 61 along the traveling direction of the filter cloth, A supply tank 62 for flowing down on the filter cloth 55, a cake cleaning spray 63 for cleaning cake moving while being filtered and supplied on the filter cloth 56, and a steam injection nozzle for injecting steam into the conveyed cake A steam cleaning / drying device 65 in which the device 64 is incorporated is provided.
The steam cleaning / drying device 65 is configured to inject a predetermined amount of steam toward the cake from the steam injection nozzle 64, thereby heating the water contained in the cake and dehydrating the cake.

In the flue gas desulfurization apparatus having the gypsum separator having the above configuration, the gypsum slurry produced in the absorbing solution 4 of the reaction tank 1 and the wastewater slurry obtained by concentrating in the wastewater treatment equipment are mixed. In order to process the mixed slurry, first, the gypsum slurry and the drain slurry are transferred from the transfer pipe 15 and the drain slurry pipe 23 to the mixing tank 67, respectively.
After mixing, the mixture is sent to a supply tank 62 via a supply pipe 61. In parallel with this, while rotating the drum 51 of the horizontal drum type vacuum dehydrator 50 to move the filter cloth 55 together with the belt 52 in the direction of the arrow in the figure,
A mixed slurry of a gypsum slurry and a drainage slurry is supplied from the supply tank 62 onto the filter cloth 55. Then, filter cloth 5
5 is conveyed by the filter cloth 55 while the moisture is sucked into the dehydration chamber 53 by the dehydration chamber 53 provided below the air-permeable belt 52, and then attached by the cake washing spray 63. The foreign matter that has been washed is sent to the steam washing / drying device 65.

The steam cleaning / drying device 6
In 5, a predetermined amount of steam is injected from the steam injection nozzle 64, and by heating the moisture adhering to the gypsum in the cake, the moisture content is reduced,
Along with the dehydration of the attached water, chlorine components and the like contained in the attached water are also removed. Thus, the gypsum 69 is dehydrated to a desired moisture content, and is collected from the filter cloth 55 to the belt conveyor 70 at the right end in the drawing.

Therefore, according to the flue gas desulfurization apparatus and the method for treating gypsum slurry, the belt-type vacuum dehydrator 50 is used.
When the gypsum slurry can be continuously processed by the continuous operation, and the steam cleaning / drying device 65 is used to mix the waste slurry with the gypsum slurry to process a mixed slurry containing a large amount of chlorine components. Also, high-quality gypsum in which the chlorine component is sufficiently removed and the water content is reduced to a desired value or less can be obtained without increasing the washing water of the cake. In addition, depending on operating conditions such as the purity of the gypsum slurry and the amount of drainage slurry, the cake washing spray 63 may be used.
Can be omitted.

In the above embodiment, the description has been given only of the case where the flue gas desulfurization apparatus and the method for treating gypsum slurry according to the present invention are applied to a wet flue gas desulfurization apparatus having a jet bubbling type reaction tank. Not limited to the above, while contacting the exhaust gas with an absorbent containing a Ca component to be circulated and supplied, air is introduced into the absorbent to remove sulfurous acid gas from the exhaust gas as a gypsum slurry, and the generated gypsum A so-called wet lime-gypsum method flue gas desulfurization device, in which a slurry is extracted by a slurry pump, solid-liquid separated in a gypsum separator and collected as gypsum, can be similarly applied to various forms. .

[0024]

As described above, in the flue gas desulfurization apparatus according to the first aspect and the method for treating gypsum slurry according to the third aspect using the same, the cake is steam-washed and dried by the apparatus. Since the water adhering to the gypsum such as the gypsum slurry can be removed, and the chlorine component and the like contained in the adhering water can also be removed along with the gypsum, without increasing the washing water for the cake, the chlorine concentration and High-quality gypsum can be obtained by reducing the water content. Therefore, as in the flue gas desulfurization apparatus according to the second aspect and the method for treating a gypsum slurry according to the fourth aspect using the same, a chlorine component obtained by mixing a wastewater slurry with a gypsum slurry is particularly large. Even in the case of treating the mixed slurry, there is a remarkable effect that the chlorine component is sufficiently removed and high-quality gypsum having a water content reduced to a desired value or less can be obtained.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram showing a gypsum separator in one embodiment of a flue gas desulfurization device of the present invention.

FIG. 2 is a schematic configuration diagram showing a conventional flue gas desulfurization device.

FIG. 3 is a schematic configuration diagram showing a gypsum separator in another conventional flue gas desulfurization apparatus.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Reaction tank 4 Absorbent solution 12 Oxidation air supply pipe 15 Transfer pipe 23 Drain slurry pipe 50 Horizontal belt type vacuum dehydrator 51 Drum 52 Belt 53 Dehydration chamber 55 Filter cloth 60 Mixing tank 62 Supply tank 65 Steam washing / drying equipment 69 Gypsum

Claims (4)

[Claims] 1. A gypsum slurry produced by contacting an exhaust gas with an absorbent containing a Ca component to be circulated and supplied, and introducing air into the absorbent to remove a sulfurous acid gas from the exhaust gas as a gypsum slurry. In a flue gas desulfurization device for extracting solids and liquids in a gypsum separator to collect gypsum, the gypsum separator has an endless filter cloth that runs freely on a gas-permeable belt stretched between drums. A belt provided on the filter cloth and supplied from a supply tank to suck the gypsum slurry from a dehydration chamber provided under the belt and maintained at a negative pressure to separate the filtrate and the gypsum Steam cleaning for dewatering water from the gypsum slurry that is transported above the filter cloth located on the downstream side of the supply tank of the belt type vacuum dehydrator and of the belt type vacuum dehydrator. Flue gas desulfurization apparatus characterized by comprising by arranging the dryer. 2. A mixing tank for mixing the gypsum slurry and the wastewater slurry from the wastewater treatment facility is provided at a stage preceding the gypsum separator, and the gypsum slurry and the wastewater slurry mixed in the mixing tank are provided. 2. The flue gas desulfurization apparatus according to claim 1, wherein the gas is supplied to the supply tank. 3. The gypsum slurry produced by bringing exhaust gas into contact with an absorbent containing a Ca component that is circulated and supplied, and introducing air into the absorbent to remove sulfurous acid gas from the exhaust gas as a gypsum slurry. A gypsum slurry, wherein the gypsum slurry is supplied to the filter cloth of the belt-type vacuum dehydrator according to claim 1, wherein the gypsum slurry is solid-liquid separated in a gypsum separator and collected as gypsum. By suctioning from the chamber and separating the water, and further spraying steam by the steam cleaning / drying device to lower the viscosity of the water,
A method for treating a gypsum slurry, wherein a gypsum having a desired moisture content or less is obtained. 4. A mixed slurry containing a chlorine component generated by collecting the contents in the exhaust gas obtained by mixing the gypsum slurry and the wastewater slurry onto the filter cloth, 4. The method for treating a gypsum slurry according to claim 3, wherein steam is sprayed by a steam cleaning / drying device to reduce the water content and remove the chlorine component.