JPH08215532A - Gas absorber - Google Patents

Abstract

PURPOSE: To provide a gas absorber in which the quantity of a treating liquid for oxidation is increased without increasing the power load of a gas dispersing blade even when the ratio of the quantity of the treating liquid to the quantity of gas introduced into the treating liquid is increased. CONSTITUTION: When the quantity of inlet oxidizing air of a gas dispersing blade 13 of a circulating tank 6 is increased, the push-out quantity of a liquid absorbent which has absorbed a sulfur compound in waste gas is decreased according to the former quantity. Besides, with the decrease in the push-out quantity, force for carrying air is decreased. Then, by forcibly sending a liquid absorbent to the gas dispersing blade 13 from outside the system, the quantity of the liquid absorbent passing the gas dispersing blade 13 is increased to increase the ratio of the quantity of the liquid absorbent to the quantity of air, that is, the introducing quantity of air is increased, and even when the ratio of air passing the gas dispersing blade 13 to the liquid absorbent is changed, power of an air micronizing device 12 is not much changed and excessive equipment is not required.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gas absorbing device, and more particularly to a gas absorbing device suitable for promoting oxidation of an absorbing liquid by air, such as a sewage treatment device and a wet flue gas desulfurization device.

[0002]

2. Description of the Related Art Although a device for supplying and absorbing gas in a solution is widely used such as a sewage treatment device and a wet flue gas desulfurization device, a wet flue gas desulfurization device will be described here as an example. BACKGROUND ART In a combustion device such as a boiler, nitrogen oxides (hereinafter sometimes referred to as NOx), dust and sulfur oxides (hereinafter, referred to as NOx) in exhaust gas generated by combustion of fossil fuels.
Sometimes called SO ₂ . ) Is one of the main causes of global environmental problems such as air pollution and acid rain. For this reason, a thermal power plant is equipped with a denitration device for removing NOx from the flue gas, a dust collector for removing dust, and a desulfurization device for removing SO ₂ . In particular, a method using a relatively inexpensive calcium compound such as calcium carbonate is most often used for a desulfurization device such as a large boiler for power generation.

FIG. 6 shows an apparatus using a spray absorption system as an example of a conventional wet flue gas desulfurization apparatus in a thermal power plant. Exhaust gas from the power plant is introduced into the desulfurization tower 1 through an inlet duct 2. At the bottom of the desulfurization tower 1, there is a circulation tank 6,
Limestone as an absorbent is supplied from a limestone slurry supply pipe 7. The absorption liquid in the circulation tank 6 is extracted by the circulation pump 5 and sent to the spray nozzle 4. The absorbing liquid is sprayed into the desulfurization tower 1 by the spray nozzle 4 and comes into contact with the exhaust gas introduced from the inlet duct 2. SO ₂ contained in the exhaust gas is absorbed by the sprayed absorption liquid. The SO ₂ absorbed in the absorbing solution becomes sulfite and falls into the circulation tank 6. In the circulation tank 6, air is blown into the air pipe 8
Introduced more, sulfite is oxidized and converted to sulfuric acid. This sulfuric acid is neutralized with limestone introduced from the limestone slurry supply pipe 7 to form gypsum. The absorption liquid in the circulation tank 6 is partially withdrawn from the absorption liquid extraction pipe 10 to separate and remove the gypsum in the absorption liquid outside the system.

The exhaust gas from which SO ₂ has been removed passes through the mist eliminator 9 attached to the outlet duct 3,
The mist entrained in the exhaust gas is removed and discharged to the outside of the system. In the circulation tank 6, in order to prevent scaling due to crystallized gypsum and to promote oxidation by air,
The jet blade 14 of the stirrer 11 is stirring the absorbing liquid. In the flow of the absorption liquid in the circulation tank 6, the absorption liquid that has absorbed SO ₂ falls on the liquid surface of the circulation tank 6, is mixed in the circulation tank 6 and is withdrawn from the bottom of the circulation tank 6 by the circulation pump 5. That is, the absorbing liquid in the circulation tank 6 is a downward flow that flows from the upper portion of the circulation tank 6 to the bottom portion.

Oxidizing air is supplied from an air blowing pipe 8 attached to the circulation tank 6, and oxygen in the air is absorbed by the absorbing liquid, so that a sufficient contact time is secured. Further, in order to increase the absorption rate of oxygen, it is necessary to make the diameter of bubbles generated in the circulation tank 6 when air is supplied as small as possible. Therefore, the air refining device 12
A method of dispersing air by means of the gas dispersing blade 13 provided in the above (for example, Japanese Utility Model Application No. 60-132830), a tube group having a plurality of small holes is uniformly arranged at the bottom of the circulation tank 6, and fine bubbles are generated. The method etc. are adopted. In the method using the gas dispersion vane 13, the air is subdivided by the vane, and the air is finely dispersed with the liquid extruded by the vane and supplied to the circulation tank 6, but the air supply amount is limited. There is. Further, in the method of discharging air from the small holes formed in the pipe group, it is necessary to attach many small holes to generate small bubbles, and the pipe group is stretched around the bottom of the circulation tank 6 to disperse the bubbles. It has to be done well and has a complicated structure.

Further, when the gypsum particles produced by the reaction of sulfuric acid and limestone are deposited on the bottom in the circulation tank 6, the gypsums adhere to each other or the gypsum adheres to the inner wall to cause scaling. Therefore, the wall surface of the circulation tank 6 or the circulation tank 6
The stirrer 11 is inserted from the upper part of the above to stir vigorously.
By stirring, the reaction between oxygen dissolved in the absorbing solution and sulfite and the reaction between sulfuric acid generated by oxidation and limestone are promoted.

[0007]

The circulation tank 6 in the wet desulfurization apparatus is generally installed in the lower part of the absorption section of the desulfurization tower 1, and oxidizes sulfite formed by absorbing SO ₂ with air. Reaction of generated sulfuric acid with limestone,
It also has the role of promoting the crystal growth of gypsum. Therefore, the air for oxidation is supplied into the circulation tank 6. In order to efficiently absorb the oxygen in the air into the absorbing liquid, it is desirable that the air bubbles generated in the absorbing liquid be fine and widely dispersed.

A method of subdividing the air with the gas dispersion blade 13 attached to the side wall of the circulation tank 6 will be described as an example. As the gas dispersion blade 13, a blade for forming an extruded flow is generally used in the front, and an air blowing tube 8 is attached to the rear of the blade. The absorption liquid is pushed forward by the gas dispersion blade 13, but the supplied air is also entrained in the absorption liquid and passes through the gas dispersion blade 13. At this time, the gas dispersion blade 13 divides the air into small bubbles. It is desirable to make a large amount of air fine with one gas dispersion blade 13, but as the amount of air is increased, the ratio of air to the absorption liquid around the gas dispersion blade 13 increases, so the gas dispersion is increased. At the same time that the blade 13 spins and the outflow amount of the absorbing liquid decreases, the air is not atomized. Therefore, the amount of air to be supplied to the air refining device 12 is limited.

The amount of air is determined by the amount of sulfur component absorbed in the desulfurization tower 1, but in the case of an actual coal-fired boiler, the amount of sulfur component in exhaust gas is as wide as 500 to 5000 ppm, and the amount of sulfur component is 500 ppm. When several air refining devices 12 are required, the amount of sulfur component is 5000
If it is increased to ppm, several tens of air refining devices 12 have to be provided, and both equipment and operating cost will increase. Further, when air is supplied to the gas dispersion blades 13, the amount of extrusion of the absorbing liquid sharply decreases, so the power for rotating the gas dispersion blades 13 also decreases as shown in FIG. Therefore, the power at the time of start-up or stop of operation without supplying air is larger than that at the time of normal operation.
It is necessary to match the planned power with the power required at start-up, which requires an excessively large installation capacity. In addition, the circulation tank 6
When the stirrer 11 also serves as the gas dispersion blade 13, if the supply amount of air is increased, the absorbing liquid cannot be sufficiently stirred. Therefore, it is necessary to increase the number of equipments of the air refining device 12.

An object of the present invention is to provide a gas absorption device capable of increasing the ratio of the amount of processing liquid to the amount of gas introduced into the processing liquid. Another object of the present invention is to provide a gas absorption device that increases the amount of treatment liquid for oxidation without increasing the power load on the gas dispersion blade even if the amount of air for oxidation is increased.

[0011]

The above objects of the present invention can be achieved by the following constitutions. That is, in a gas absorption device that guides gas into the treatment liquid and atomizes and disperses the gas by the gas dispersion blade to absorb it in the treatment liquid, a jet blade that forcibly forms the flow of the treatment liquid in the gas dispersion blade direction. Is a gas absorption device.

The jet impeller of the gas absorption device of the present invention forms a forced flow of the treatment liquid so as to guide the gas to the vicinity of the gas dispersion vane in the treatment liquid, and is installed coaxially or separately from the gas dispersion vane. Any thing can be used. As the gas dispersion blade and the jet flow blade, those in which the rotation axes thereof are installed horizontally or vertically within the gas absorption device can be used.

Specific examples of the gas absorption device of the present invention include (1) a wet flue gas desulfurization device for treating a sulfur compound in exhaust gas by bringing an absorption liquid containing an alkaline compound into gas-liquid contact with the exhaust gas from the combustion device. A circulation tank for air-oxidizing the absorbing liquid that has absorbed the sulfur compounds in the exhaust gas,
(2) There is an aeration tank of a sewage treatment apparatus that supplies air to sewage to treat the sewage with activated sludge.

[0014]

[Function] When the air is made fine by the gas dispersion blade, the processing liquid such as the exhaust gas absorbing liquid is forced out by the gas dispersion blade,
The air supplied to this flow will be entrained and atomized by the gas dispersion blade, but if the treatment liquid cannot be discharged at a sufficiently high speed, the atomized bubbles will re-associate into large bubbles. As a condition for preventing re-association of the finely divided air, it is desirable that the amount of air with respect to the amount of treatment liquid is about 15% or less by volume. However, when the amount of air to be processed increases, the amount of air around the gas dispersion blade also increases, so that the amount of processing liquid pushed out also decreases. Further, the presence of air causes cavitation, which further reduces the amount of processing liquid pushed out.

Therefore, in order to make the air fine, the volume ratio of the amount of air to the processing liquid must be 15% or less, and the amount of air also decreases as the flow rate of the processing liquid decreases. Therefore, if the absorption liquid is forcibly supplied to the gas dispersion blade from the outside of the system, the amount of the processing liquid passing through the gas dispersion blade increases, and the air amount can be increased accordingly. Moreover, since the discharge amount of the processing liquid can be arbitrarily set, it is possible to supply the air bubbles, which are miniaturized by the gas dispersion blade, into the processing liquid storage tank without causing them to associate with each other.

The conventionally known gas dispersion blade has a structure for pushing out the processing liquid, but it can be structured only to make bubbles fine by supplying the processing liquid from outside the system. Therefore, even if the ratio of the air passing through the gas dispersion blade and the treatment liquid changes, the power of the device for refining the air does not change so much, and there is an advantage that no excessive equipment is required.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment in which a flue gas desulfurization device is applied as a gas absorption device of the present invention will be described with reference to the drawings. FIG. 1 shows a schematic cross-sectional view of the circulation tank 6 of this embodiment, and FIGS. 2 and 3 show plan views thereof. The circulation tank 6 of this embodiment is shown in FIG.
The circulation tank 6 in the lower part of the desulfurization tower 1 of the flue gas desulfurization apparatus shown in (1) is improved, and a gas dispersion blade 13 and a jet blade 14 are attached to an air refining apparatus 12. An air blowing tube 8 is attached near the gas dispersion blade 13.

Oxidation in the conventional circulation tank 6 shown in FIG. 6 was carried out only by the gas dispersion blade 13, but in this embodiment,
Further, in addition to the gas dispersion blade 13, a large amount of oxidizing air is also made fine by the jet blade 14. 2 shows the gas dispersion blade 13 and the jet blade 14 mounted coaxially, and FIG. 3 shows the gas dispersion blade 13 and the jet blade 14 mounted on separate shafts. In the present embodiment shown in FIGS. 2 and 3, the gas dispersion blade 13 is a rotary blade for atomizing the air, and the jet blade 14 is arranged at a position where the absorbing liquid can be sent to the gas dispersion blade 13. It is a rotary wing.

The air supplied from the air blowing pipe 8 is entrained in the absorbing liquid which is forcibly sent from the jet vanes 14 and sent to the gas dispersion vanes 13. In the conventional gas dispersion blade 13, the absorption liquid is sent out, and at the same time, the air is made fine, but in the present embodiment, the jet blade 14 sends out the absorption liquid, and therefore the gas dispersion blade 13 is optimal for making the air fine. It can be a structure. Further, the jet vane 14 can also have an optimum structure for delivering the absorbing liquid.

In the vicinity of the jet vane 14, there is no impeding factor that reduces the amount of liquid to be sent out, that is, air or the like, so that the liquid amount can always be kept at the maximum outflow amount. Therefore, the air blowing pipe 8 can supply an amount of air commensurate with the maximum outflow amount of the liquid amount. In the conventional method, since the absorbing liquid and the air are sent out by the gas dispersing blade 13, when the air is supplied, the amount of the outflowing liquid will decrease in proportion to this amount. Also, since the vicinity of the gas dispersion blade 13 is depressurized by rotation,
The supplied air expands, which further reduces the discharge of absorbing liquid, which is 40 to 50 in the absence of air.
%. However, if only the absorbing liquid is supplied by the jet vanes 14, 200 to 250% of air can be supplied. In this way, the number of air refining devices 12 can be halved.

FIG. 4 shows another embodiment of the present invention. FIG.
Has a vertical rotation axis in the circulation tank 6 and performs a stirring operation and an air refining operation of the absorbing liquid at the same time by a vertical air refining device 12 having a gas dispersion vane 13 and a jet vane 14 coaxially provided. It is a thing. An air blowing tube 8 is attached between the gas dispersion blade 13 and the jet blade 14. The air supplied from the air blowing pipe 8 is entrained in the absorbing liquid that is forcibly sent from the jet vanes 14 and sent to the gas dispersion vanes 13. Since there is no air or the like that hinders the discharge of the absorbing liquid in the vicinity of the jet vane 14, the maximum amount of absorbing liquid can always flow out. Therefore, the air can be supplied in an amount commensurate with the maximum outflow amount of the absorbing liquid, so that a large amount of air can be stably supplied.

Further, the air may be supplied from the gas dispersion blade 13 through the rotary shaft of the air refining device 12. If there is no jet vane 14, the supplied air is
The gas is dispersed in contact with the gas dispersion blade 13 and is made finer. In this case as well, the presence of air around the gas dispersion blade 13 hinders the outflow and agitation of the absorbing liquid. Therefore, the gas dispersion blade 13
It is desirable to quickly discharge the air bubbles that have been made finer from the vicinity of the dispersion blade 13. Therefore, the jet vane 14 is further
By mounting the absorbing liquid in the vicinity of the dispersing blade 13 and forming an upward flow of the absorbing liquid, and quickly making the fine bubbles into the vicinity of the dispersing blade 13, a large amount of air can be stably reduced.

According to the above embodiment of the present invention, by combining the gas dispersion blade 13 and the jet flow blade 14, it is possible to supply 200 to 250% of air as compared with the case where only the gas dispersion blade 13 is used. In this way, compared with the case where only the gas dispersion blade 13 is used,
It can be halved.

Further, when only the gas dispersion blade 13 is used, it is necessary to disperse air bubbles, so that the absorbing liquid is also pushed out at the same time. Therefore, the amount of air is reduced at the time of start, stop, and load change. However, if the amount of air is reduced, the amount of the absorbing liquid pushed out increases, so the power for operating the gas dispersion blade 13 increases. . Therefore, the conventional technique using only the gas dispersion blade 13 is the gas dispersion blade 13
The air refining device 12 equipped with must be designed with a power that maximizes the amount of extruded liquid (there is no air), but the embodiment of the present invention does not have such a problem.

[0025]

According to the present invention, the gas dispersion blade and the jet flow blade are combined to stir the processing liquid in the processing liquid storage tank, and at the same time, the air is atomized. , 200 to 250% of air can be supplied, and the number of air refining devices can be halved.

Compared to the case where only the gas dispersion blade is used,
Since it is not necessary to reduce the amount of air when the device is started, stopped, or when the load changes, and the discharge amount of the processing liquid can be set arbitrarily, it is possible to associate fine air bubbles with the gas dispersion blade. It can be supplied to the treatment liquid storage tank without any treatment, and the desulfurization performance of exhaust gas or the wastewater treatment performance can be improved.

[Brief description of drawings]

FIG. 1 is a schematic sectional view of a circulation tank portion of a flue gas desulfurization apparatus according to an embodiment of the present invention.

FIG. 2 is a plan view of the circulation tank of FIG.

FIG. 3 is a plan view of the circulation tank of the circulation tank portion of the flue gas desulfurization apparatus according to the embodiment of the present invention.

FIG. 4 is a schematic cross-sectional view of a circulation tank portion of the flue gas desulfurization device according to one embodiment of the present invention.

FIG. 5 is a diagram showing changes over time in the power ratio of the air refining device in the circulation tank portion of the conventional flue gas desulfurization device.

FIG. 6 is a schematic cross-sectional view of a circulation tank portion of a conventional flue gas desulfurization apparatus.

[Explanation of symbols]

6 ... Circulation tank, 8 ... Air blowing pipe, 12 ... Air refining device, 13 ... Gas dispersion blade, 14 ... Jet blade

 ─────────────────────────────────────────────────── ─── Continuation of the front page (72) Hirofumi Yoshikawa, No. 36 Takaracho, Kure City, Hiroshima Prefecture Babcock-Hitachi Co., Ltd. Kure Research Institute (72) Shigeru Nozawa, No. 6-9 Takaracho, Kure City, Hiroshima Prefecture Babcock-Hitachi Ltd. Kure Factory

Claims (5)

[Claims] 1. A gas absorption device for guiding a gas into a processing liquid and for refining and dispersing the gas by a gas dispersion blade to absorb the gas into the processing liquid, forcibly forming a flow of the processing liquid in the gas dispersion blade direction. A gas absorption device, characterized in that it is provided with a jet vane that allows the gas to flow. 2. A jet flow vane forms a forced flow of the treatment liquid so as to guide the gas to the vicinity of the gas dispersion vane in the treatment liquid,
The gas absorption device according to claim 1, wherein the gas absorption device is installed coaxially or separately from the gas dispersion blade. 3. The gas absorbing device according to claim 1, wherein the gas dispersion blade and the jet flow blade are arranged such that their rotation axes are horizontal or vertical in the gas absorbing device. 4. The sulfur compound in the exhaust gas provided in the wet flue gas desulfurization device for treating the sulfur compound in the exhaust gas by bringing the absorption liquid containing the alkaline compound into gas-liquid contact with the exhaust gas from the combustion device by the gas absorption device. A circulation tank for air-oxidizing the absorbed absorption liquid.
5. The gas absorbing device according to any one of 3 to 3. 5. The gas according to claim 1, wherein the gas absorption device is an aeration tank for a wastewater treatment device that supplies air to the wastewater to treat the wastewater with activated sludge. Absorber.