KR101353431B1 - Gas cooling system - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling tower, a wet purification apparatus, and a device for cooling a high temperature gas discharged from a chimney or the like. More particularly, to a gas cooling apparatus for cooling a high temperature gas to a small amount of cooling heat. A gas cooling apparatus according to the present invention includes a gas cooling chamber provided at an outlet side of a device for discharging hot gas and a cooling device for cooling cooling water for cooling the gas. The gas cooling apparatus according to the present invention has an advantage that it can cool the gas with a small amount of cooling heat to easily remove the white smoke because only the gas containing water vapor is cooled by the cold cooling water instead of cooling the entire liquid such as the water to be cooled.

Description

Gas cooling system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cooling tower, a wet purification apparatus, and a device for cooling a high temperature gas discharged from a chimney or the like. More particularly, to a gas cooling apparatus for cooling a high temperature gas to a small amount of cooling heat.

The gas cooling device according to the present invention can be utilized particularly as a device for removing white smoke by cooling the gas containing water vapor discharged from a cooling tower, a wet cleaning device and the like in a cool manner to remove white smoke.

There is a growing demand for cooling towers for cooling large quantities of water used in various plants, factories, and buildings. In the cooling tower, external air is introduced into the cooling tower by using a blower installed at the exhaust port at the upper end, cooling water is sprayed by using a nozzle inside the cooling tower, heat exchange is performed between the water to be cooled and external air, do. At this time, the outside air used for cooling the water to be cooled is discharged from the cooling tower in a state of high temperature and high humidity. When the temperature outside the cooling tower is below the dew point, the moisture contained in the discharged outside air condenses and becomes a droplet of water, scattering light to look like white smoke, which is called white smoke. Such white glaze occurs not only in cooling towers but also in structures that emit high-temperature gases that contain water vapor, such as chimneys and wet scrubbing equipment. There is no legal regulation on white smoke, but it is often mistakenly mistaken for nearby residents to report a fire due to a fire or to discharge pollutants, and complaints often occur.

Conventionally, a method of removing white smoke by cooling the water to be cooled or the cleaning liquid as much as possible by a method of removing white smoke from a cooling tower or a wet cleaning apparatus has been used. However, the conventional method of cooling the whole of the water to be cooled is uneconomical because the amount of cooling heat is too much.

A method of cooling water used for a chimney or a wet cleaning apparatus to remove white smoke has been used. Further, in the case of the wet cleaning apparatus, the metal cooling coil of the heat exchanger used for cooling the cleaning liquid may be corroded by the cleaning liquid.

As described above, conventionally, as a means for removing white smoke, a method of directly lowering the temperature of the liquid used in the wet cleaner or the cooling tower has been used. However, in order to lower the temperature of the liquid such as the cooling water or the cleaning liquid to a temperature at which the white smoke does not occur, a large amount of external air must be introduced, so that it is practically impossible to remove the white smoke.

An object of the present invention is to provide a gas cooling device capable of cooling a gas containing water vapor with a small amount of cooling heat to remove white smoke.

In order to accomplish the above object, a gas cooling apparatus according to the present invention includes a gas cooling chamber provided on an outlet side of a device for discharging hot gas and a cooling device for cooling cooling water for cooling the gas.

The gas cooling chamber includes an inlet through which a hot gas is introduced, an outlet through which the introduced gas is discharged, and a side wall which forms an inner space through which the introduced gas flows from the inlet toward the outlet.

A nozzle for injecting cooling water into the inner space is provided at an upper portion of the inner space of the gas cooling chamber. A cooling water guide plate is installed under the nozzle.

The cooling water guide plate forms a path along which the gas flows together with the side wall. The cooling water guide plate is configured to have a surface against which cooling water falling from above collides and to form a cooling water curtain that blocks the passage of the gas by dropping cooling water flowing down from the surface.

In addition, a cooling water storage portion for storing cooling water separated from the cooling water guide plate is provided in the inner space of the gas cooling chamber.

The cooling device is configured to cool the cooling water supplied from the cooling water storage part and supply it to the nozzle of the gas cooling chamber.

The inlet of the gas cooling chamber of the above-described gas cooling device is integrally connected to an outlet of a device for discharging hot gas, for example, a cooling tower, a wet scrubber, a chimney or a duct.

The cooling device includes a cooling water cooling chamber including an inlet through which the outside air for cooling the cooling water flows, an outlet through which the introduced outside air is discharged, and a side wall through which the introduced outside air flows from the inlet toward the outlet, A cooling water reservoir for storing the cooling water sprayed from the spray nozzle, a cooling water reservoir for storing the cooling water sprayed from the spray nozzle, A connection pipe for connecting the cooling water reservoir and the injection nozzle so as to supply the cooling water stored in the cooling water re-storage unit to the injection nozzle, and a connection pipe for connecting the cooling water reservoir to the injection nozzle, And a cooling water supply unit for supplying cooling water stored in the cooling water storage unit to the nozzle of the gas cooling chamber To, may comprise a circulation pump provided in the circulation pipe and the circulation pipe connecting the coolant material storage section and the nozzle of the gas-cooling chamber.

Further, the cooling device is provided below the injection nozzle, and forms a path along which the outside air flows together with the sidewalls of the cooling water cooling chamber. The cooling device has a surface on which cooling water falling from above flows, And at least one cooling water guide plate configured to drop down the cooling water curtain to block the passage of the outside air.

The cooling device may further include a cooling coil, a pipe for transferring the cooling water stored in the cooling water storage portion of the gas cooling chamber to the cooling coil, and a cooling water supply portion for supplying the cooling water, And a circulation pump installed in the circulation pipe. The circulation pipe is connected to the nozzle of the gas cooling chamber.

The cooling water guide plate may include a horizontally extended section from a side wall of the gas cooling chamber to an inner space.

Further, the cooling water guide plate extends from the side wall of the gas cooling chamber to the inner space, and can be inclined to guide the cooling water downward.

The cooling water guide plate may be provided at a central portion of the gas cooling chamber, and may include a pair of inclined surfaces extending in mutually opposite directions and inclined downward.

Further, the gas cooling apparatus may include at least a pair of the cooling water guide plates extending from the side walls so as to face each other.

The end of the cooling water guide plate is preferably rounded up or down.

In addition, a cooling water guide bar having a curved surface along which the cooling water flows may be disposed under the end portion of the cooling water guide plate.

Preferably, the cooling water guide plate is formed with a conical spiral on the upper surface thereof so that the cooling water dropped on the cooling water guide plate can be dropped while performing the conical spiral movement.

A guide vane may be formed on the upper surface of the cooling water guide plate.

The gas cooling apparatus may further include an eliminator installed in an internal space at an outlet side of the gas cooling chamber and removing droplets generated in the gas cooling chamber. It may further comprise a blower configured to introduce gas into the gas cooling chamber.

According to another embodiment of the gas cooling apparatus according to the present invention, an inlet through which a hot gas is introduced, an outlet through which the introduced gas is discharged, and an inlet space through which gas flows horizontally from the inlet toward the outlet A gas cooling chamber including a side wall, a nozzle installed in the inner space for spraying cooling water at the inlet side, an eliminator installed at a rear end of the nozzle in the inner space to remove droplets in the gas, And a cooling device for collecting and cooling the droplets separated from the eliminator and the cooling water injected from the nozzles and supplying the cooling water to the nozzles.

According to another embodiment of the present invention, there is provided a gas cooling apparatus comprising: a duct connected to an outlet of a device for discharging a high-temperature gas; an inlet connected to the duct for introducing the hot gas and an outlet for discharging the introduced gas; A gas cooling chamber including a sidewall defining an inner space through which the introduced gas flows from the inlet toward the outlet; a nozzle installed at an upper portion of the inner space and injecting cooling water into the inner space; And a circulation pipe and a pump for supplying the cooling water supplied from the cooling water storage unit to the nozzle, wherein the side wall of the gas cooling chamber is provided with a cooling chamber for cooling the cooling water and gas, There is provided a gas cooling apparatus in which an outside air inflow port through which a gas is introduced is provided.

The gas cooling apparatus according to the present invention has an advantage that it can cool the gas with a small amount of cooling heat to easily remove the white smoke because only the gas containing water vapor is cooled by the cold cooling water instead of cooling the entire liquid such as the water to be cooled. The gas cooling apparatus according to the present invention can be installed in any apparatus that generates white smoke such as a cooling tower, a wet purifier, and a chimney for discharging hot gas, thereby effectively removing white smoke. Further, the high-temperature gas can be cooled and discharged.

1 is a schematic view of a cooling tower equipped with an embodiment of a gas cooling apparatus according to the present invention.
2 to 10 are views showing a part of another embodiment according to the present invention.
11 is a schematic view of a cooling tower in which another embodiment of the gas cooling apparatus according to the present invention is installed.
12 is a schematic view of a wet scrubbing apparatus equipped with another embodiment of the gas cooling apparatus according to the present invention.
13 and 14 are views schematically showing a malodor generating part provided with another embodiment of the gas cooling device according to the present invention.
15 is a schematic view of a cooling tower in which another embodiment of the gas cooling apparatus according to the present invention is installed.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments are provided by way of example so that those skilled in the art can fully understand the spirit of the present invention. Therefore, the present invention is not limited to the embodiments described below, but may be embodied in other forms. And in the drawings, the width, length, thickness, etc. of the components may be exaggerated for convenience. Like numbers refer to like elements throughout.

1 is a schematic view of a cooling tower equipped with an embodiment of a gas cooling apparatus according to the present invention. 1, an embodiment of a gas cooling apparatus according to the present invention includes a gas cooling unit 100 having a gas cooling chamber 110 and a cooling water cooling unit 200 having a cooling water cooling chamber 210 . In this embodiment, the gas cooling chamber 110 is integral with the top of the cooling tower 300.

The gas cooling chamber 110 includes an inlet 111 through which the gas is introduced and an outlet 113 through which the introduced gas is discharged and an inner space 114 through which the introduced gas flows from the inlet 111 toward the outlet 113 (Not shown).

The gas may be a hot gas containing water vapor discharged from a cooling tower, a gas discharged from a wet scrubber, or a hot gas discharged from a chimney. In this embodiment, a gas cooling apparatus coupled to the cooling tower 300 will be described as an example.

The outside air to be supplied to the cooling tower 300 is supplied from below to the outside by the blower 120 installed at the outlet 113 of the gas cooling chamber 110. The outside air supplied to the cooling tower 300 is supplied to the inlet 111 of the gas cooling chamber 110 in a state of high temperature and high humidity by the to-be-cooled water (the cooling water supplied to the cooling tower after heated by the load) supplied to the cooling tower 300 ≪ / RTI > The water to be cooled injected from the water injection nozzle 331 of the cooling tower 300 is cooled by the outside air and then stored in the water to be cooled 336. The stored water to be cooled is supplied to the water-cooling water injection nozzle 331 through the water-cooling water circulation pipe 334.

In the present invention, in the present invention, the cooling water discharged from the cooling tower 300 in the state of containing water vapor and the gas introduced into the gas cooling chamber 110 To remove the white smoke. In this way, the white smoke can be removed with a small amount of cooling heat.

The inner space 114 of the gas cooling chamber 110 is provided with a nozzle 131 and a cooling water guide plate 133 for spraying cool cooling water for cooling the gas. The nozzle 131 is installed in the upper part of the inner space 114. In the nozzle 131, cold cooling water is uniformly sprayed at an angle of about 120 degrees. A cooling water guide plate 133 is provided below the nozzle 131. A cooling water storage portion 132 is provided under the cooling water guide plate 133.

The cooling water guide plate 133 serves to form a path along which the gas (high-temperature outside air containing steam discharged from the cooling tower) flows together with the side wall 112 of the gas cooling chamber 110. In addition, it serves to guide the cooling water jetted from the nozzle 131 to the cooling water storage part 132. And serves to form the cooling water curtain 3 on the flow path of the gas. The gas is not discharged to the outlet 113 without passing through the cooling water curtain 3. Thus, gas and cooling water are brought into complete contact. In the present invention, the frequency of contact between the gas and the cool cooling water can be increased simply by increasing the number of the cooling water guide plates 133.

In this embodiment, the cooling water guide plate 133 extends from the side wall 112 toward the inner space 114. The cooling water guide plate 133 extends in a downwardly inclined state so as to allow the cooling water to flow to the cooling water storage part 132. The remaining space is blocked by the pair of cooling water guide plates 133 so that the gas can flow into the space between the pair of cooling water guide plates 133. [ The cooling water which has struck the cooling water guide plate 133 flows downward along the cooling water guide plate 133 and falls from the end of the cooling water guide plate 133 to the cooling water storage part 132 like waterfall water, And the cooling water curtain 3 is formed between the two portions 132. [

The present embodiment has a cooling water cooling chamber 210 as a cooling device for cooling the cooling water in the cooling water storage part 132 and supplying it to the nozzle 131.

The cooling water cooling chamber 210 has an inlet 211 through which cool outside air for cooling the cooling water flows and an outlet 213 through which the introduced outside air is discharged and an outlet 213 through which the introduced outside air flows from the inlet 211 toward the outlet 213 And a sidewall 212 forming an outer-air flow space 214.

An injection nozzle 231 for injecting cooling water into the outside-air flow space 214 is provided at an upper portion of the outside-air flow space 214 of the cooling-water cooling chamber 210. A cooling water reservoir 236 for storing the cooling water injected from the injection nozzle 231 is disposed below the cooling water cooling chamber 210.

A drain pipe 150 for transferring the cooling water having a slightly increased temperature in contact with the high-temperature gas containing water vapor stored in the cooling water storage unit 132 to the cooling water storage unit 236; a cooling water storage unit 236 A circulation pipe 134 connecting the cooling water reservoir 236 and the nozzle 131 to supply the cooling water stored in the circulation pipe 134 to the nozzle 131 and a circulation pump 135 installed in the circulation pipe 134 .

A connection pipe 234 for connecting the cooling water reservoir 236 and the injection nozzle 231 to supply the cooling water having a slightly increased temperature stored in the cooling water re-storage unit 236 to the injection nozzle 231, And a pump 245 installed in the pump 234. The cooling water supplied from the injection nozzle 231 is cooled by being brought into contact with the cool outside air flowing into the cooling chamber 210.

In the present invention, the cold cooling water cooled by contact with the cold outside air supplied by the blower 220 is injected from the nozzle 131 inside the gas cooling chamber 110 and is heated and cooled in the cooling tower 300 Gas. Cooling water having a slight temperature rise in contact with the gas is recovered in the cooling water cooling chamber 210. That is, the cooling water is not stored in the water to be cooled 336, but is stored in the cooling water restoring unit 236. The cooling water is not mixed with the relatively hot water to be cooled in the water to be cooled 336.

The cold cooling water supplied from the cooling water cooling chamber 210 is not mixed with the water to be cooled 336 and cooled again in the cooling water cooling chamber 210 with the temperature slightly raised by heat exchange with the gas.

However, in the present invention, only the high-temperature gas containing the water vapor on the cooling tower 300 is cooled in the cooling water cooling chamber 210 by cooling water chilled by cold outside air. The cooling water having a slightly increased temperature recovered in contact with the high temperature gas is cooled by the cooling water cooling chamber 210 having a small amount of cooling heat so that the white smoke generated at the top of the cooling tower 300 can be effectively removed even with a small amount of cooling heat.

Hereinafter, the operation of the gas cooling apparatus according to the present embodiment will be described.

The water to be cooled heated by a load such as a mechanical device is stored in the water to be cooled 336 of the cooling tower 300. The stored water to be cooled is injected from the cooling water injection nozzle 331 and cooled to about 32 ° C by the outside air flowing into the cooling tower 300. In this process, the outside air flowing into the cooling tower 300 is in a state of high temperature and high humidity. When the gas including the water vapor is directly discharged to the outside of the cooling tower 300, water vapor coagulates and water droplets are formed and white smoke is generated.

In the present invention, a high-temperature gas including water vapor discharged from the cooling tower 300 flows into the gas cooling chamber 110, which is integrally coupled to the upper portion of the cooling tower 300. This gas is cooled to less than 18 캜 while passing through the cooling water curtain 3 formed in the internal space 114 of the gas cooling chamber 110 and discharged outside the gas cooling chamber 110. The temperature of the gas is sufficiently lowered in the process of passing through the coolant curtain 3, so that even if this gas is discharged to the outside, white smoke does not occur. The cooling water whose temperature has slightly increased in the process of cooling the gas is first stored in the cooling water storage part 132 and is transferred to the cooling water storage part 236 of the cooling water cooling chamber 210 through the drain pipe 150. The cooling water stored in the cooling water re-storage section 236 is supplied to the injection nozzle 231 along the connection pipe 234 connecting the cooling water storage section 236 and the injection nozzle 231, The cooling water is cooled by the cool outside air flowing into the cooling water cooling chamber 210. The cooled cooling water is stored in the cooling water reservoir 236 and supplied to the nozzle 131 along the circulation pipe 134 connecting the cooling water reservoir 236 and the nozzle 131.

In the present invention, not only the water to be cooled of the cooling tower 300, but only the high temperature gas including the water vapor introduced into the gas cooling chamber 110 is cooled using the cool cooling water cooled in the cooling water cooling chamber 210, Can be removed.

However, in the present invention, only the high-temperature gas including the water vapor on the cooling tower 300 is cooled using the separate cooling water, , Only the cooling water whose temperature has slightly increased in this process is cooled in the cooling water cooling chamber 210, so that the white smoke can be effectively removed with a small amount of cooling heat.

2 to 10 are views showing the structure inside the gas cooling chamber of another embodiment according to the present invention.

As shown in Fig. 2, in this embodiment, one cooling water storage unit 132 is provided on the left and right sides, respectively. The configuration of the cooling water guide plate 133 is changed.

The cooling water guide plate 133 includes a first cooling water guide plate 133a and a pair of second cooling water guide plates 133b.

The first cooling water guide plate 133a is inclined so that the cooling water flows to both the left and right cooling water storage parts 132 in the drawing.

The pair of second cooling water guide plates 133b is provided between the first cooling water guide plate 133a and the nozzle 131 and guides the cooling water injected from the nozzle 131 to drop it on the first cooling water guide plate 133a. The pair of second cooling water guide plates 133b extend from the side walls 112 facing each other toward the center of the inner space 114. [ The cooling water flowing along the pair of second cooling water guide plates 133b falls onto the first cooling water guide plate 133a to form the cooling water curtain 3.

The high temperature gas including the water vapor flowing in the downward direction in the drawing passes through the cooling water curtain 3 formed between the first cooling water guide plate 133a and the cooling water storage part 132, the second cooling water guide plate 133b, Flows through the cooling water curtain 3 formed between the cooling water curtains 133a and then flows upward in the direction in which the outlet is formed. If necessary, a third cooling water guide plate having the same shape as that of the first cooling water guide plate 133a may be provided on the cooling water guide plate 133b, and cooling water guide plates may be provided thereon.

The first cooling water guide plate 133a and the second cooling water guide plate 133b may be disposed at different positions and only one cooling water storage unit 132 may be provided at the lower center of the inner space 114. [

3, the cooling water curtains 3 are formed by using the cooling water guide plates 133 extending from the side walls 112 opposed to each other with a height difference to guide the cooling water to the cooling water storage part 132 It is possible.

The embodiment shown in FIG. 4 differs from the embodiment shown in FIG. 3 in that the end portion 137 of the cooling water guide plates 133 is rounded downward. The curled end portion 137 serves to change the direction of the cooling water falling from the cooling water guide plate 133 by using the Coanda effect. The cooling water falling from the cooling water guide plate 133 flows along the curved surface of the curled end portion 137 of the cooling water guide plate 133 by the Coanda effect. As a result, the cooling water is diverted from the cooling water guide plate 133 by a diagonal line. When the cooling water falls to the diagonal line, the area of the cooling water curtain 3 becomes larger so that the cleaning efficiency is improved.

The cooling water storage unit 132 is provided with a baffle plate 140 for preventing the cooling water from overflowing.

In the embodiment shown in Fig. 5, as in the embodiment shown in Fig. 4, cooling water falling from the cooling water guide plate 133 is diagonally shaded by the Coanda effect. The end 138 of the cooling water guide plate 133 is curled upward so that the cooling water stored in the space surrounded by the cooling water guide plate 133 and the side wall 112 flows to the end portion 138 of the cooling water guide plate 133, So that the cooling water curtain 3 is formed.

In the embodiment shown in FIG. 6, a cooling water guide bar 139 having a circular cross section is provided below the end of the cooling water guide plate 133, and the cooling water, which is separated from the cooling water guide plate 133, Flows along the surface of the cooling water 139 and falls into a diagonal line to form the cooling water curtain 3.

The embodiment shown in Fig. 7 shows a method of constructing the cooling water guide plate 133 to guide the cooling water injected from the plurality of nozzles 131 when the inner space 114 is wide. 7, in the width direction of the inner space 114, the third cooling water guide plates 133c extending in an inclined downward direction from the side wall 112 and the pair of third cooling water guide plates 133c extending in the opposite directions The fourth cooling water guide plates 133d having the inclined surfaces are appropriately arranged to form a path through which the outside air flows and the cooling water can be guided to the cooling water storage part 132 while forming the cooling water curtain 3 on the path of the outside air have.

The first cooling water guide plate 133e and the pair of second cooling water guide plates 133f may extend horizontally from the side wall 112 as shown in FIG. In addition, the end portion may be inclined.

In the embodiment shown in FIG. 9, the cooling water has a conical spiral structure on the second cooling water guide plate 133g so that the cooling water can perform a conical spiral movement in the second cooling water guide plate 133g. The first cooling water guide plate 133a has the same structure as that of FIG. In this embodiment, the cooling water is rotated by the second cooling water guide plate 133g and is separated from the cooling water, so that the gas including the water vapor and cooling water are more in contact with each other.

In the embodiment shown in FIG. 10, a guide vane 142, which is bent on the second cooling water guide plate 133h, is installed so that the cooling water can rotate in the second cooling water guide plate 133h. The first cooling water guide plate 133a has the same structure as that of FIG. In this embodiment, the cooling water is allowed to fall along the guide vane 142 in the second cooling water guide plate 133h, so that the gas including the water vapor and the cooling water are more in contact with each other.

11 is a schematic view of a cooling tower in which another embodiment of the gas cooling apparatus according to the present invention is installed.

In this embodiment, an eliminator 160 for removing droplets is installed near the outlet 113 of the gas cooling chamber 110. The eliminator 160 serves to prevent the cooling water jetted from the cooling water nozzle 131 from being liquidized and discharged to the outlet 113.

1, a cooling water curtain (not shown) is interposed between the injection nozzle 231 and the cooling water storage part 236 so that the cooling water and the outside air all come in contact with the cooling water cooling chamber 210 in order to increase the cooling efficiency of the cooling water cooling chamber 210. [ The cooling water guide plate 233 and the cooling water storage unit 232 are disposed. An eliminator (260) is installed on the upper part of the injection nozzle (231). In addition, the cooling tower 300 is configured in such a manner that the water coolant curtain 1 can be formed.

12 is a schematic view of a wet scrubbing apparatus equipped with another embodiment of the gas cooling apparatus according to the present invention. The wet scrubbing apparatus 500 in this embodiment is arranged so that gas flows in the lateral direction.

Referring to FIG. 12, the cleaning liquid sprayed from the cleaning nozzle 531 of the wet cleaning apparatus 500 is contacted with hot exhaust gas. The hot gas containing the water vapor discharged to the downstream side of the wet scrubber 500 flows into the gas cooling chamber 410 connected to the rear end of the wet scrubber 500. Cooling water cooler than 18 deg. C in the cooling water cooling chamber 210 is injected into the internal space 414 of the gas cooling chamber 410 through the nozzle 431. [ The cooling water is brought into contact with the gas containing the water vapor so that the water vapor in the gas is condensed and is condensed and combined with the cooling water to be removed from the eliminator 460 of the gas cooling chamber 410. The cooled gas is discharged to the outside of the cooling water cooling chamber 210 and the cooling water is collected in the cooling water storage portion 432 under the eliminator 460. The cooling water collected in the cooling water storage part 432 is discharged to the cooling water storage part 236 of the cooling water cooling chamber 210 through the drain pipe 450. The cooling water is cooled in the cooling water cooling chamber 210 and then injected through the nozzle 431 in the gas cooling chamber 410 again.

In addition, it may be discharged directly through the drain pipe 450 without a separate cooling water storage part 432.

FIG. 13 is a schematic view of a malodor generating unit provided with another embodiment of the gas cooling apparatus according to the present invention. In this embodiment, the gas cooling chamber 110 is provided on the upper portion of the odor generating unit 700 to cool the high temperature gas. If the cooling water is injected into the high-temperature gas and cooled, the odor can be reduced.

When the cooling water for cooling the hot gas with odor is cooled using the cooling water cooling chamber described above, the offensive odor can be discharged to the outside through the outlet of the cooling water cooling chamber. Therefore, a metal cooling coil 610 is provided in place of the cooling water cooling chamber to supply cooling water to the inside of the cooling coil 610, and the outside air is brought into contact with the cooling coil 610 by the blower 620 outside the cooling coil 610, Thereby cooling the cooling water in the cooling water tank 610. A cooling fin 611 may be provided outside the cooling coil 610 to increase the cooling efficiency. Since the cooling coil 610 is of a closed type, the odor of the cooling water is not discharged to the outside.

FIG. 14 is a schematic view of a malodor generating part provided with another embodiment of the gas cooling device according to the present invention.

In the present embodiment, cooling water is indirectly cooled using a heat exchanger 670, unlike in Fig. When the malodor generating unit 700 and the heat exchanger 670 are stopped in winter, the cooling water remaining in the cooling coil 610 is frozen and the cooling coil 610 is broken. Therefore, the cooling coil 610 is filled with antifreeze And the cooling water in the gas cooling chamber 110 is cooled through the heat exchanger 670 by heat exchange with coolant cooled by the outside air.

15 is a schematic view of a cooling tower in which another embodiment of the gas cooling apparatus according to the present invention is installed.

The gas cooling apparatus according to the present embodiment includes an inlet 811 through which gas containing water vapor is introduced from a duct 840 connected to an outlet 313 of the cooling tower 300, an outlet 813 through which the introduced gas is discharged, Includes a gas cooling chamber 810 that includes a sidewall 812 that defines an interior space 814 through which gas flows from the inlet 811 toward the outlet 813.

In the present embodiment, the side wall 812 of the gas cooling chamber 810 is formed with an outside air inlet 819 through which the outside air is introduced to cool the cooling water and the gas, so that the cooling water is also cooled in the gas cooling chamber 810.

A nozzle 831 for injecting cooling water into the inner space 814 is provided at an upper portion of the inner space 814 of the gas cooling chamber 810 and a cooling water injected from the nozzle 831 is injected into the lower portion of the gas cooling chamber 810. [ A cooling water storage portion 836 for storing the cooling water is disposed.

The embodiments described above are merely illustrative of the preferred embodiments of the present invention, the scope of the present invention is not limited to the described embodiments, those skilled in the art within the spirit and claims of the present invention It will be understood that various changes, modifications, or substitutions may be made thereto, and such embodiments are to be understood as being within the scope of the present invention.

110, 410, 810: gas cooling chamber 111: inlet
113: outlet 114: inner space
131: nozzle 132: cooling water storage part
133: cooling water guide plate 210: cooling water cooling chamber
220: blower 300: cooling tower
460: Eliminator 500: Wet Purifier
610: Cooling coil 700: Odor generating part

Claims (22)

A gas cooling chamber including an inlet through which a hot gas is introduced, an outlet through which the introduced gas is discharged, and a side wall forming an inner space through which the introduced gas flows from the inlet toward the outlet;
A nozzle installed at an upper portion of the inner space and injecting cooling water into the inner space,
It is installed under the nozzle, and forms a path through which the gas flows along with the side wall, and has a surface to which the coolant falling from above hits and flows, and drops the coolant flowing from the surface down to block a path through which the gas passes. At least one coolant guide plate configured to form a coolant curtain,
A coolant storage unit for storing the coolant dropped from the coolant guide plate;
And a cooling device for cooling the cooling water supplied from the cooling water storage unit and supplying the cooling water to the nozzle. delete The method of claim 1,
Wherein the inlet of the gas cooling chamber is integrally coupled to the outlet of the device for discharging the hot gas. The method of claim 3,
Wherein the apparatus for discharging the hot gas is a cooling tower, a wet scrubber, a chimney, or a duct. The method of claim 1,
The cooling device includes:
A cooling water cooling chamber including an inlet for introducing outside air for cooling the cooling water, an outlet through which the introduced outside air is discharged, and a side wall forming an outside air flow space through which the introduced outside air flows from the inlet toward the outlet;
A spray nozzle installed at an upper portion of the outside air flow space for spraying cooling water to the outside air flow space,
A cooling water reservoir for storing the cooling water injected from the injection nozzle,
A drain pipe for transmitting the cooling water stored in the cooling water storage portion of the gas cooling chamber to the cooling water storage portion,
A connection pipe connecting the cooling water reservoir and the injection nozzle to supply the cooling water stored in the cooling water reservoir to the injection nozzle, and a pump installed in the connection pipe,
And a circulation pump connected to a nozzle of the gas cooling chamber to supply the cooling water stored in the cooling water reservoir to the nozzle of the gas cooling chamber and a circulation pump installed in the circulation pipe, Device. The method of claim 5,
A cooling water cooling chamber disposed below the injection nozzle and forming a path along which the outside air flows together with the side wall of the cooling water cooling chamber and having a surface through which cooling water falling from above collides with the cooling water flowing down from the cooling water cooling chamber, Further comprising at least one cooling water guide plate configured to form a cooling water curtain that obstructs the path through which the cooling water is passed. The method of claim 1,
The cooling device includes:
A cooling coil and an air blower for supplying outside air toward the cooling coil,
A pipe for transferring the cooling water stored in the cooling water storage portion of the gas cooling chamber to the cooling coil;
And a circulation pump connected to a nozzle of the gas cooling chamber so as to supply the cooling water cooled by the cooling coil to the nozzle of the gas cooling chamber, and a circulation pump installed in the circulation pipe, . The method of claim 1,
Wherein the cooling water guide plate comprises a section horizontally extending from a side wall of the gas cooling chamber to an inner space. The method of claim 1,
Wherein the cooling water guide plate extends from a side wall of the gas cooling chamber to an inner space and is inclined to guide cooling water downward. The method of claim 1,
And said coolant guide plate comprises at least a pair of guide plates extending to face each other from said side wall. The method of claim 1,
Wherein the cooling water guide plate is provided at a central portion of the gas cooling chamber and has a pair of inclined surfaces extending in directions opposite to each other and inclined downward. The method of claim 1,
Wherein the end of the cooling water guide plate is rounded up or down. The method of claim 1,
And a cooling water guide bar having a curved surface along which the cooling water flows is disposed under the end portion of the cooling water guide plate. The method of claim 1,
Wherein the cooling water guide plate has a conical spiral formed on the upper surface thereof so that the cooling water dropped on the cooling water guide plate can be dropped while performing conical spiral movement. The method of claim 1,
And a guide vane is formed on the upper surface of the cooling water guide plate. The method of claim 1,
Further comprising an eliminator installed in an internal space at the outlet side of the gas cooling chamber, for removing droplets generated in the gas cooling chamber. The method of claim 1,
Further comprising a blower configured to introduce a gas into the gas cooling chamber. delete delete delete delete delete

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