JP2010115602A - Two-step wet desulfurization method and apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a two-step wet desulfurization method and apparatus with low running cost without greatly increasing the power of an absorbing liquid circulation pump, by efficiently removing trace components like mercury and fluorine compound in exhaust gas. <P>SOLUTION: The two-step wet desulfurization method and apparatus are provided wherein an advanced venturi scrubber 2 running exhaust gas downward, provided with multiple stages of spray nozzles 3 against the exhaust gas flow is installed upstream of an absorbing tower 1, and replenishing water first coming into contact with the exhaust gas is used as an absorbing liquid to be fed to the spray nozzles 3 at an uppermost stream of the advanced venturi scrubber 2. The feed amount of the replenishing water is preferably set equivalent to a vaporization amount of water in the advanced venturi scrubber. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an exhaust gas treatment device that removes harmful components in exhaust gas, and in particular, a wet type equipped with an advanced venturi scrubber that can efficiently remove trace components such as mercury and fluorine compounds and greatly reduce the power of the desulfurization device. The present invention relates to a two-stage flue gas desulfurization method and apparatus.

FIG. 5 shows an absorption tower in a conventional wet flue gas desulfurization apparatus.
This wet flue gas desulfurization apparatus is mainly composed of an absorption tower body 1, an inlet duct 1a, an outlet duct 1b, a circulation tank 16, an absorbing liquid circulation pump 17, a spray nozzle 21, a mist eliminator 22, and the like.

  Exhaust gas discharged from a boiler (not shown) is introduced from the inlet duct 1a of the absorption tower main body 1 into the main body in a substantially horizontal direction by a desulfurization fan (not shown) and discharged from an outlet duct 1b provided at the top of the tower. The During this time, the absorption liquid containing calcium carbonate in the circulation tank 16 below the absorption tower body 1 is sent to the spray header 20 via the circulation pipe 18 by the circulation pump 17 provided in the circulation pipe 18. Are sprayed from a plurality of spray nozzles 21.

In the absorption tower main body 1, the absorption liquid selectively absorbs SO ₂ in the exhaust gas by gas-liquid contact between the absorption liquid injected from the spray nozzle 21 and the exhaust gas. The absorbing solution that has absorbed SO ₂ once accumulates in the circulation tank 16 and is oxidized by oxygen in the air supplied into the circulation tank 16 to generate calcium sulfate (gypsum). A part of the absorption liquid in the circulation tank 16 in which calcium carbonate and gypsum coexist is sent again to the spray nozzle 21 by the absorption liquid circulation pump 17, and a part is sent to a waste liquid treatment / gypsum recovery system (not shown). Of the absorbing liquid atomized from the absorbing liquid from the spray nozzle 21, those having a small droplet diameter are accompanied by the exhaust gas, but are collected by the mist eliminator 22 provided in the outlet duct 1b. .

This wet flue gas desulfurization apparatus can absorb and remove not only SO ₂ in exhaust gas but also trace components such as mercury (particularly molecular mercury such as mercury chloride) and fluorine compound (particularly hydrogen fluoride). In particular, since mercury chloride, hydrogen fluoride, and the like have high absorbability in water, a removal rate equal to or higher than that of SO ₂ can be obtained. However, in order to comply with strict emission regulations in the United States, high removal performance of about 95 to 99.9% is required, and this requires a large amount of circulating fluid that is greater than the amount of circulating circulating fluid required for SO ₂ removal. As a result, the power of the desulfurization apparatus is greatly increased.
Further, there is known a configuration in which an advanced venturi scrubber having a spray nozzle for spraying an absorbing liquid provided in a flow path of exhaust gas discharged from a combustion apparatus is provided.
JP 2003-260326 A

In the above prior art, sufficient consideration has not been given to the increase in the amount of circulating fluid in the absorber main body for removing trace components contained in the boiler exhaust gas, and there has been a problem that the power of the absorbing fluid circulation pump increases.
Further, in the configuration in which the advanced venturi scrubber is provided to remove dust in the exhaust gas, removal of trace components contained in the boiler exhaust gas has not been considered.

  An object of the present invention is to provide a wet two-stage desulfurization method and apparatus with low operating costs by efficiently removing trace components such as mercury and fluorine compounds in exhaust gas without significantly increasing the power of the absorbent circulation pump. There is in getting.

  The invention according to claim 1 is provided in an advanced venturi scrubber having a spray nozzle for spraying an absorbing liquid provided in a flow path of exhaust gas discharged from a combustion apparatus including a boiler, and provided in an exhaust gas flow path downstream of the advanced venturi scrubber. In a wet two-stage desulfurization apparatus that treats sulfur oxides in exhaust gas with an absorption tower having a spray nozzle for spraying the absorbing liquid, the advanced venturi scrubber has a wall surface that allows the exhaust gas to flow downward along the exhaust gas flow direction. A plurality of spray nozzles for spraying the absorbing liquid along the flow direction of the exhaust gas on the wall surface, and the wet-type two nozzles in which the uppermost spray nozzle in the plurality of spray nozzles is a spray nozzle for spraying makeup water that comes into contact with exhaust gas for the first time. Stage desulfurization equipment.

  According to a second aspect of the present invention, there is provided the spray nozzle in which the spraying direction of the absorbing liquid is set at an angle of 45 degrees obliquely downward with respect to the horizontal direction and the horizontal plane on the opposing wall surfaces of the advanced venturi scrubber. This is a wet two-stage desulfurization apparatus.

  The invention described in claim 3 is the wet two-stage desulfurization apparatus according to claim 2, wherein the spray nozzles are arranged in a staggered manner on the same horizontal plane of the opposing wall surfaces of the advanced venturi scrubber.

  A fourth aspect of the present invention is the wet two-stage desulfurization apparatus according to the second aspect, in which spray nozzles are arranged in a staggered manner in each stage in the vertical direction of the wall surface of the advanced venturi scrubber.

  In the invention according to claim 5, the absorbing liquid injected from the spray nozzle and the exhaust gas discharged from the combustion apparatus such as the boiler are sequentially brought into gas-liquid contact in the advanced venturi scrubber and the absorption tower from the upstream side. In the wet two-stage desulfurization method for treating sulfur oxides, the exhaust gas is circulated downward in the advanced venturi scrubber, and the absorbing liquid is sprayed toward the exhaust gas from spray nozzles provided in a plurality of stages in the exhaust gas flow direction. This is a wet two-stage desulfurization method in which makeup water that comes into contact with exhaust gas for the first time is sprayed from an upstream spray nozzle.

  The invention according to claim 6 is the wet two-stage desulfurization method according to claim 5, wherein the supply amount of the makeup water is set to an amount corresponding to the evaporation amount of water in the advanced venturi scrubber.

  The invention according to claim 7 is the wet two-stage desulfurization method according to claim 5, wherein the pH of the absorbent used in the advanced venturi scrubber is set in the range of 2-4.

(Function)
The problem with the prior art is that in order to remove trace components such as mercury and fluorine compounds in the exhaust gas, it is necessary to increase the amount of circulating fluid more than the amount of absorbent circulating to remove SO ₂ in the exhaust gas. .
In this regard, in the present invention, spray nozzles installed in an advanced venturi scrubber installed upstream of the absorption tower are arranged in multiple stages with respect to the exhaust gas flow, and spray nozzles are sprayed by absorbing liquid toward the downstream side. It is possible to cover the gas blow-through that tends to occur between the two.

In addition, as the absorption liquid supplied to the spray nozzle on the most upstream side of the advanced venturi scrubber, make-up water that makes contact with the exhaust gas is used for the first time, and the supply amount of the make-up water is set to be equivalent to the amount of water evaporation in the advanced venturi scrubber. Thus, scattering of mercury, fluorine compounds, etc. in the liquid accompanying water evaporation can be prevented.
In addition, by setting the pH of the absorbent that is circulated and used in the advanced venturi scrubber to a range of 2 to 4, the concentration of the fluorine compound dissolved in the absorbent can be reduced, and the removal rate of the fluorine compound can be reduced. It is possible to prevent the decrease.

  Further, in the advanced venturi scrubber, the injection direction of the absorbing liquid is set at an angle of 45 degrees obliquely downward with respect to the horizontal direction and the horizontal plane, thereby reducing pressure loss compared to the conventional venturi scrubber. Furthermore, atomization of spray droplets can be promoted by causing the absorbing liquids to collide with each other, and the gas absorption rate can be increased. Therefore, it is possible to efficiently absorb and remove the trace components in the exhaust gas not only under the dust removal by the inertial collision of the conventional venturi scrubber but also under the high gas flow rate condition that can obtain high absorption performance.

In addition, spray nozzles that spray the absorbing liquid are staggered with respect to each other on the same horizontal surface of the opposed wall surface of the advanced venturi scrubber. Can be covered with spray.
In addition, the spray nozzles arranged in multiple stages on the vertical wall surface of the advanced venturi scrubber are arranged in a staggered manner for each stage, and are easily generated between the nozzles by the absorbing liquid sprayed toward the downstream side. Gas blow-by can be covered more reliably.

  ADVANTAGE OF THE INVENTION According to this invention, the trace amount component in waste gas can be efficiently removed with the advanced venturi scrubber provided in the upstream of the desulfurization absorption tower, and the drastic increase in the amount of absorption liquid circulation of a desulfurization absorption tower can be prevented. As a result, it is possible to minimize an increase in circulation pump power.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a schematic configuration diagram of a wet two-stage desulfurization apparatus according to this embodiment, and an advanced venturi scrubber 2 is installed on the upstream side of the desulfurization absorption tower body 1. FIG. 2 shows details of the advanced venturi scrubber 2 in FIG. FIG. 3 shows an AA ′ cross section of the advanced venturi scrubber 2 of FIG. FIG. 4 shows a BB ′ cross section of the advanced venturi scrubber 2 in FIG.

The wet two-stage desulfurization apparatus of this embodiment shown in FIGS. 1 to 4 is conventional in that an advanced venturi scrubber 2 having both functions of gas absorption removal and inertial collision removal is installed on the upstream side of the desulfurization absorption tower body 1. Different from technology.
The structure of the desulfurization absorption tower is the same as that of the wet flue gas desulfurization apparatus of the prior art shown in FIG. 5, and the absorption tower main body 1, the inlet duct 1a, the outlet duct 1b, the circulation tank 16, the absorption liquid circulation pump 17, the spray nozzle 21, It consists of a mist eliminator 22 and the like.

Next, the configuration of the advanced venturi scrubber (hereinafter abbreviated as AVS) 2 side will be described.
The exhaust gas introduced from the upper side to the lower side of the AVS 2 is sprayed obliquely downward from the spray nozzle 3 attached to the wall surface of the AVS 2 whose cross-sectional area of the channel is smaller than the area of the cross-sectional area of the other part. Contacting the absorbing liquid 6, trace components such as mercury and fluorine compounds in the exhaust gas are absorbed and removed. The downward spray nozzle 3 that sprays the absorbing liquid 6 provided on the wall surface of the AVS 2 and the water spray nozzle 10 that sprays makeup water can reduce pressure loss more than the conventional venturi scrubber. By causing the absorbing liquids to collide with each other, atomization of the spray droplets 9 is promoted, and the gas absorption rate can be increased.

  Further, the liquid sprayed from the spray nozzle 3 and the water spray nozzle 10 passes through the downcomer 4 and is stored in the tank 5. The absorbing liquid 6 in the tank 5 is sent to the spray nozzle 3 through a circulation pipe 8 by a pump 7. The spray nozzle 3 for spraying the absorbing liquid 6 is installed on the inner wall surfaces of the AVS 2 which are opposite to each other, and the spray nozzles 3 are arranged in a staggered manner on the inner wall surface of one channel of the AVS 2 and the inner wall surface of the other channel. In addition, the triangular gap generated between the adjacent nozzles 3 and 3 can be covered with the spray from the facing surface of the inner wall of the flow path. Furthermore, by setting the pH of the absorbent used for circulation in AVS2 in the range of 2 to 4, the concentration of the fluorine compound dissolved in the absorbent can be reduced, and the removal rate of the fluorine compound can be reduced. It becomes possible to prevent.

  Further, by arranging the spray nozzles 3 on the vertical wall surface of the AVS 2 in a multi-stage shape, it is possible to cover the gas blow-off that tends to occur between the two adjacent nozzles 3 and 3 with the downstream spray. The spray nozzles 3 arranged in a staggered manner are arranged so as to be staggered at each stage, thereby absorbing the gas blown easily between the two adjacent nozzles 3 and 3 toward the downstream side. The cover can be covered more reliably.

  Furthermore, since the replenishing water 11 that contacts the exhaust gas for the first time is used as the absorbing liquid to be supplied to the spray nozzle 10 on the most upstream side of the AVS 2, it is possible to prevent scattering of mercury or fluorine compounds in the liquid accompanying water evaporation. It is possible to prevent a decrease in the trace component removal rate associated with re-scattering.

  Since the two-stage desulfurization system according to the present invention can contribute to prevention of mercury re-release in the desulfurization apparatus, the industrial applicability is high.

It is a side view of the wet two-stage desulfurization apparatus which installed the advanced venturi scrubber in the upstream of the desulfurization absorption tower of one Example by this invention. FIG. 2 is a detailed view of an advanced venturi scrubber in FIG. 1. It is A-A 'sectional drawing in the advanced venturi scrubber of FIG. It is B-B 'sectional drawing in the advanced venturi scrubber in FIG. It is the figure which showed the wet desulfurization apparatus of the prior art.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Absorption tower body 1a Inlet duct 1b Outlet duct 2 Advance venturi scrubber 3 Spray nozzle 4 Precipitation pipe 5 Tank 6 Absorbing liquid 7 Pump 8 Circulating pipe 9 Spray droplet 10 Water spray nozzle 11 Supplementary water 16 Circulating tank 17 Absorbing liquid circulating pump 18 Circulating pipe 20 Spray header 21 Spray nozzle 22 Mist eliminator

Claims (7)

An advanced venturi scrubber having a spray nozzle for spraying an absorbing liquid provided in a flow path of exhaust gas discharged from a combustion apparatus including a boiler, and a spray nozzle for spraying an absorbing liquid provided in an exhaust gas flow path downstream of the advanced venturi scrubber In a wet two-stage desulfurization apparatus for treating sulfur oxide in exhaust gas equipped with an absorption tower,
The advanced venturi scrubber has a wall surface for flowing the exhaust gas downward along the flow direction of the exhaust gas, and a plurality of spray nozzles for spraying the absorbent along the exhaust gas flow direction are provided on the wall surface. A wet two-stage desulfurization apparatus characterized in that the most upstream spray nozzle is a spray nozzle that sprays makeup water that comes into contact with exhaust gas for the first time.   2. The wet nozzle according to claim 1, wherein spray nozzles are set on the opposing wall surfaces of the advanced venturi scrubber with the injection direction of the absorbing liquid set at an angle of 45 degrees obliquely downward with respect to the horizontal direction and the horizontal plane. Stage desulfurization equipment.   The wet two-stage desulfurization apparatus according to claim 2, wherein the spray nozzles are arranged in a staggered manner on the same horizontal plane of the opposite wall surfaces of the advanced venturi scrubber.   The wet two-stage desulfurization apparatus according to claim 2, wherein spray nozzles are arranged in a staggered manner in each stage in the vertical direction of the wall surface of the advanced venturi scrubber. Wet liquid that treats sulfur oxides in exhaust gas by sequentially contacting the gas injected from the spray nozzle and exhaust gas discharged from combustion equipment such as boilers in the advanced venturi scrubber and the absorption tower from the upstream side. In the two-stage desulfurization method,
The exhaust gas is circulated downward in the advanced venturi scrubber, and the absorbing liquid is sprayed from the spray nozzle provided in multiple stages in the exhaust gas flow direction toward the exhaust gas. A wet two-stage desulfurization method characterized by spraying.   6. The wet two-stage desulfurization method according to claim 5, wherein a supply amount of the makeup water is set to an amount corresponding to an evaporation amount of water in an advanced venturi scrubber.   6. The wet two-stage desulfurization method according to claim 5, wherein the pH of the absorbent used in the advanced venturi scrubber is set in the range of 2 to 4.

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