KR20160113559A - Cooling Tower Abating Plume - Google Patents

Abstract

Disclosed is a cooling tower capable of white smoke reduction, including: a housing which has a hollow inside and includes a first air inlet, formed on a lower portion to allow external air to flow into the same, and an upper air outlet formed on an upper portion to release discharged air; a filler unit which is formed at a location higher than the first air inlet in the housing to make the external air pass therethrough and flow to an upper portion; a processing water spraying unit which is located on an upper portion of the filler unit in the housing and sprays processing water to an upper portion of the filler unit; a cooling water spraying unit which sprays, above the processing water spraying unit, cooling water at a temperature lower than the temperature of the processing water, sprayed by the processing water spraying unit, to an upper portion of the processing water spraying unit; an electrical discharge unit which is located above the cooling water spraying unit in the housing and collects mist by electrically charging, through corona discharge, the mist included in water vapor formed when the processing water comes in contact with external air; and a discharge unit which is located on the upper air outlet and releases the discharge air having passed through the electrical discharge unit.

Description

{Cooling Tower Abating Plume}

The present invention relates to a method for reducing the amount of white smoke generated when cooling process water is used, in a manufacturing plant using a semiconductor manufacturing facility, a flat panel display manufacturing facility, or a general industrial manufacturing facility, a factory building, The present invention relates to a white smoke reduction cooling tower.

Generally, a cooling tower is a device installed in the outdoors of a building in which equipment for using cooling water is installed, such as semiconductor processing equipment, and is used as cooling water in the equipment to cool treated water at a high temperature. The cooling tower is also installed on the roof of an office building that operates heating and cooling equipment.

The cooling tower flows into the open area of the lower part of the sidewall, and the low-temperature external air flowing in the upper part is sprayed from the upper part and the high-temperature treatment water flowing downward is brought into contact with the cooling tower. When the cooling tower is operated in a state where the outside temperature is low as in winter, the white smoke is generated due to the dew-point lowering of the discharged air and the condensation of water vapor. More specifically, the outside air flowing into the lower portion of the cooling tower contacts with the treated water at a high temperature and contains an excessive amount of water, and is discharged to the outside of the cooling tower in a saturated air state where the temperature rises. The supersaturated air discharged to the outside of the cooling tower comes into contact with the outside air having a relatively low temperature, so that the dew point is lowered and the steam condensation phenomenon occurs to cause white smoke.

The white smoke is harmless because it is generated by the condensation of the water that is the main component of the process water, but it is recognized that the harmful substance or the pollutant harmful to the appearance is mixed, thereby causing the generation of complaints.

The present invention provides a cooling tower capable of reducing the occurrence of white smoke during the cooling process of treated water.

The white smoke reduction cooling tower of the present invention comprises: a housing having a hollow interior and including a first air inlet formed at a lower portion to receive external air and an upper air outlet formed at an upper portion to discharge the exhaust air; A filler portion formed at a position higher than the first air inlet and formed so as to allow the outside air to pass through and to flow upward; and a process water injecting portion for injecting the process water into the upper portion of the filler portion, A cooling water spraying unit for spraying cooling water having a temperature lower than that of the treated water sprayed from the treated water spraying unit on the treated water spraying unit to the upper portion of the treated water spraying unit above the treated water spraying unit; Is located at an upper portion of the jetting portion, and is brought into contact with the outside air by the corona discharge All trapping by charging the mist contained in the steam room that is formed and characterized in that it comprises located in the upper air discharge outlet for discharging the exhaust air which has passed through the discharge section.

In addition, the housing may further include a cooling water pipe inlet located at an upper portion of the treated water injection portion, wherein the cooling water injection portion is formed of a pipe having an inner hollow portion and is located at an upper portion of the treated water injection portion, And a cooling water pipe extending from the outside of the housing to the inside of the housing through the cooling water inflow pipe and connected to the cooling water injection pipe to supply cooling water to the cooling water injection pipe .

Further, the housing further includes a process water inlet formed at a lower portion of the housing, the process water inlet extending from the outside of the housing to the inside of the housing through a process water inlet, A circulation pump connected to the cooling water pipe at an outlet thereof for introducing process water collected at a lower portion of the housing through a process water pipe and supplying the process water to the cooling water pipe, And a cooling unit for cooling the process water using process cooling water.

In addition, the housing may include a collecting tank which is hermetically closed at the bottom and collects treated water sprayed from the treated water spraying portion, cooling water sprayed from the cooling water spraying portion, and the treated water and cooling water collected in the water collecting tank, The processing water inlet port being formed at a position lower than the water level of the processing water inlet port, one end of the processing water inlet port being connected to the processing water inlet port and the other end being connected to the processing water spraying port, As shown in FIG.

The discharge unit may include a plurality of discharge plates formed in a plate shape and positioned vertically inside the housing and spaced apart from each other in the horizontal direction and a plurality of discharge cells extending in the horizontal direction between the discharge cells, And a discharge plate having a support rod positioned at the center, a coupling hole formed at the center, and a protrusion formed on the outer side and coupled to the support rod through the coupling hole, wherein the discharge electrode is disposed between the discharge plate of the collector plate and the discharge electrode As shown in FIG.

The discharge unit may include a plurality of discharge plates formed in a plate shape and positioned vertically inside the housing and spaced apart from each other in the horizontal direction, and a plurality of discharge cells extending in the vertical direction between the discharge plates, And a discharge plate having a support rod spaced apart from the support plate, a coupling hole formed at the center of the support plate, and a protrusion formed on the outer side of the support plate and coupled to the support bar through the coupling hole. The discharge plate of the discharge plate, As shown in FIG.

The discharging unit may include a collecting plate having upper and lower openings and hollow collecting passages arranged in a lattice shape, and a support bar extending vertically in the collecting passage of the collecting plate and a coupling And a discharge plate having a hole and a protrusion formed on the outer side and coupled to the support rod through the coupling hole. The discharge electrode may be formed to discharge between the discharge plate and the discharge electrode.

In addition, the water collecting passage may be formed by arranging a triangular barrel, a rectangular barrel, a cylindrical barrel, or a hexagonal barrel having an open upper part and a lower part and hollow inside, in a lattice form.

In addition, the housing may further include a second air inlet formed between the treated water sprayer and the discharge unit to allow the outside air to flow.

The housing may further include a third air inlet formed between the discharge unit and the discharge unit to allow the outside air to flow.

The discharge plate of the discharge unit is formed at a vertical height of 200 to 1,000 mm, and the discharge plates are spaced apart from each other in the vertical direction by a vertical distance of 5 to 100 mm, and the discharge plate, May be spaced horizontally by a horizontal distance of 50 to 200 mm.

According to another aspect of the present invention, there is provided a white smoke reduction cooling apparatus comprising: a housing having a hollow interior and including a first air inlet formed at a lower portion thereof to receive external air and an upper air outlet formed at an upper portion thereof to discharge exhaust air; A filler portion formed at a position higher than the first air inlet and formed so as to flow the upper portion of the air through the outer air passing through the upper portion of the filler portion; A heat exchanging unit which is located above the treated water injecting unit and cools water vapor rising to the upper part of the treated water injecting unit, and a heat exchanger located in the upper part of the heat exchanging unit inside the housing, The mist contained in the water vapor formed by the contact between the treated water and the outside air is charged to form a foil And a discharge unit which discharges the discharge air which is located at the upper air discharge port and has passed through the discharge unit.

In addition, the heat exchanger may include a cooling pipe through which the cooling water flows, a cooling water supply pipe connected to one side of the cooling pipe, for supplying cooling water to the cooling pipe, and a cooling water pipe connected to the other side, And a cooling water discharge pipe for discharging the cooling water from the cooling pipe. At this time, the cooling pipe includes a plurality of horizontal cooling pipes extending from one side to the other and spaced apart from each other, and two vertical cooling pipes extending in a direction perpendicular to the horizontal cooling pipes and connected to both ends of the horizontal cooling pipes And the cooling water supply pipe and the cooling water discharge pipe may be respectively connected to the vertical cooling pipe. In addition, the housing may further include a cooling water supply pipe through hole through which the cooling water supply pipe passes, and a cooling water discharge pipe through hole through which the cooling water discharge pipe passes.

The discharge unit is formed in a plate shape and is disposed in a vertical direction inside the housing and is formed in a plurality of collecting plates and plate shapes spaced apart from each other in the horizontal direction and formed in a shape corresponding to the collecting plate, And a discharge is formed between the discharge plate and the discharge electrode.

The white smoke reduction cooling tower of the present invention can cool the generated saturated water vapor primarily by the cooling water to increase the size of the mist and further remove the mist of the saturated water vapor to remove the white smoke of the discharged air efficiently .

In addition, the white smoke reduction cooling tower of the present invention allows outside air to flow between the cooling water spraying part and the discharge part, thereby lowering the temperature of the saturated water vapor and increasing the size of the mist. In particular, The temperature of the saturated steam is lowered to efficiently increase the size of the mist, thereby increasing the removal efficiency of the mist and the efficiency of reducing the occurrence of white smoke.

In addition, the white smoke reduction cooling tower of the present invention mixes the exhaust air from the inside of the housing with the outside air by introducing the outside air into the upper part of the discharge unit, thereby absorbing the mist contained in the exhaust air into the outside air, Can be reduced. In addition, the white smoke reduction cooling tower of the present invention has the effect of reducing the generation of complaints due to the concern of leakage of harmful substances by reducing white smoke.

Further, the white smoke reduction cooling tower of the present invention has the effect of reducing the operating cost by reusing the treated water by recovering the mist contained in the saturated water vapor.

1 is a vertical cross-sectional view of a white smoke reduction cooling tower according to an embodiment of the present invention.
2 is a bottom cross-sectional view according to AA of Fig.
3 is a detailed vertical cross-sectional view of the discharge unit shown in FIG.
4 is a bottom cross-sectional view according to BB of Fig.
FIG. 5 is a bottom cross-sectional view corresponding to FIG. 4 of the discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.
FIG. 6 is a bottom cross-sectional view corresponding to FIG. 4 of the discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.
7 is a bottom view of a discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.
8 is a bottom view of a discharging part provided in the white smoke reduction cooling tower according to another embodiment of the present invention.
9 is a vertical cross-sectional view corresponding to FIG. 1 of a white smoke reduction cooling tower according to another embodiment of the present invention.
10 is a bottom cross-sectional view according to CC of Fig.
11 is a horizontal sectional view of a discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.

Hereinafter, a white smoke reduction cooling tower according to an embodiment of the present invention will be described with reference to the accompanying drawings.

First, a white smoke reduction cooling tower according to an embodiment of the present invention will be described.

1 is a vertical cross-sectional view of a white smoke reduction cooling tower according to an embodiment of the present invention. 2 is a bottom cross-sectional view taken along line A-A in Fig. 3 is a detailed vertical cross-sectional view of the discharge unit shown in FIG. 1. FIG. 4 is a bottom cross-sectional view taken along line B-B of FIG.

1 to 4, the white smoke reduction cooling tower 100 according to the embodiment of the present invention includes a housing 110, a filler portion 120, a treated water sprayer 130, a cooling water sprayer 150, A discharge unit 160 and a discharge unit 170. The white smoke reduction cooling tower 100 may further include a treatment water supply pipe 140.

The white smoke reduction cooling tower 100 emits cooling water having a relatively low temperature to the saturated water vapor generated by contact with the external air to which the relatively high-temperature treatment water supplied from the treated water spraying unit 130 flows. Accordingly, the white smoke reduction cooling tower 100 increases the size of the mist in the saturated water vapor and passes it to the discharge unit 160, and the mist contained in the saturated water vapor is charged and collected to remove the mist. At this time, the mist collides with the polarity arranged in the discharging part 160 through charging, and the size of the mist is increased. Also, the mist is condensed as the temperature is lowered while being in contact with cooling water having a relatively low temperature, and the size of the mist is increased. Here, the mist refers to water particles in the water vapor generated by contact between the treated water and the outside air.

In addition, the white smoke reduction cooling tower 100 allows external air to flow between the cooling water sprayer 150 and the discharge unit 160, thereby lowering the temperature of the saturated water vapor and increasing the size of the mist. The white smoke reduction cooling tower 100 has a structure in which outside air having a relatively low temperature and humidity is introduced between the cooling water spraying part 150 and the discharging part 160 in winter so that the temperature of the saturated steam is lowered, . ≪ / RTI > Accordingly, the discharge unit 160 collects and collects the mist of which the particle size is increased by the cooling water, so that the mist is collected and removed more efficiently. Mist having a small particle size contained in the saturated water vapor can be discharged to the outside without being collected in the discharger 160. The mist is condensed in contact with the outside air having a relatively low temperature and is increased in size, . In particular, the mist can be condensed and regenerated as white smoke as the outside air becomes lower as in winter. However, the cooling water spraying unit 150 increases the mist size of the saturated water vapor, the discharge unit 160 efficiently collects the mist, thereby reducing the mist in the saturated water vapor, and even if the temperature is low, Thereby reducing the possibility of occurrence. Accordingly, the white smoke reduction cooling tower 100 reduces the occurrence of white smoke when the exhaust air discharged to the outside by the discharge unit 170 comes into contact with the outside air.

Saturated water vapor at a relatively high temperature, when contacted with air at a relatively low temperature, lowers the dew point and causes water vapor condensation to occur, resulting in white smoke. Therefore, in order to reduce the white smoke generated by the saturated water vapor, it is necessary to increase the temperature of the supersaturated water vapor or to reduce the humidity of the saturated water vapor. The white smoke reduction cooling tower 100 of the present invention reduces the humidity of saturated water vapor and reduces the occurrence of white smoke.

The housing 110 is formed to include a first air inlet 111 and an upper air outlet 114 and a process water outlet 115 and a process water inlet 116 and a cooling water pipe inlet 117. The housing 110 may further include a second air inlet 112, a third air inlet 113, and a process water inlet 118. Meanwhile, the housing 110 may be formed as a general cooling tower housing.

The housing 110 may be formed in a polygonal cylinder shape such as a hollow cylinder, a rectangular cylinder, or a hexagonal cylinder. The lower portion of the housing 110 may be formed of a treated water sprayed from the treated water sprayer 130 and a water collecting tank 119 for collecting the cooling water sprayed from the cooling water sprayer 150.

The first air inlet 111 is formed in a lower portion of the filler portion 120 and allows external air to be introduced into the filler portion 120. The lower air inlet 111 is formed to have a size necessary for the amount of outside air to be introduced for cooling the process water jetted from the process water jetting unit 130. The first air inlet 111 may be formed as a circular or square hole and may have a circular or rectangular shape and may be formed continuously along the circumferential direction of the housing 110.

The second air inlet 112 is formed between the cooling water sprayer 150 and the discharge unit 160 so that external air is introduced and mixed with the saturated water vapor. The external air introduced into the second air inlet 112 is mixed with the saturated water vapor to lower the temperature and humidity of the saturated water vapor. The second air inlet 112 is formed to a size necessary for introducing a sufficient amount of air to lower the temperature of the saturated water vapor and to reduce the humidity. On the other hand, the second air inlet 112 may not be formed when the generation of white smoke is sufficiently reduced by the discharge unit 160. The second air inlet 112 may be formed as a circular or square hole and may be formed in a continuous shape along the circumferential direction of the housing 110 in a circular or rectangular shape.

The third air inlet 113 is formed between the discharge unit 160 and the discharge unit 170 so that the external air is mixed with the discharge air that has passed through the discharge unit 160. The third air inlet 113 may be formed as a circular or square hole and may be formed in a continuous shape along the circumferential direction of the housing 110 in a circular or rectangular shape. The external air introduced into the third air inlet 113 is mixed with the exhaust air passing through the discharge unit 160 to shorten the time taken for the mist to be absorbed into the outside air which is in contact with the exhaust air from the outside of the housing 110, Can be reduced. That is, since the mist contained in the exhaust air is absorbed by the incoming external air inside the housing 110, the degree of absorption of mist into the outside air from the outside of the housing 110 can be reduced, and the occurrence of white smoke can be reduced. The small mist of about 100 nm that the discharge unit 160 can not collect is absorbed into the outside air while being in contact with the outside air inside the housing 110, The concentration of generated white smoke and the generation height are lowered.

The upper air outlet 114 is formed at an upper portion of the housing 110 and a discharge unit 170 is installed. The upper air outlet 114 allows the exhaust air passing through the discharge unit 160 to be discharged. The upper air outlet 114 is formed in a size such that exhaust air can be smoothly discharged.

The treated water outlet 115 is formed at a lower portion of the housing 110 and is preferably formed at a position adjacent to the lower end of the housing 110 at a position lower than the water level of the collected water. The process water outlet 115 allows the process water discharge pipe 115a connected to the process equipment to be coupled. The treated water outlet 115 allows the treated water collected in the water collecting tank 119 to be supplied to the treated water discharging pipe 115a.

The treatment water inlet 116 is formed at a lower portion of the housing 110 and is preferably formed at a position lower than the water level formed by the treated water and the cooling water. The process water inlet port 116 is coupled to the process water supply pipe 140 located inside the housing 110 so that the process water inlet pipe 116a connected to the process facility is coupled. The process water inlet 116 allows the process water used in the process facility to flow into the process water supply pipe 140 through the process water inflow pipe 116a. The process water inlet 116 is formed at a position where the process water sprayer 130 is formed when the process water supply pipe 140 is not formed in the housing 110 and the process water sprayer 130 Or the like.

The cooling water pipe inlet 117 is formed at an upper portion of the processing water jetting unit 130 at an upper portion of the housing 110. The cooling water tube inlet 117 provides a passage through which the cooling water tube 153 of the cooling water sprayer 150 described below passes.

The treatment water inlet 118 is formed in the side or bottom area of the collecting tank where the treated water is collected in the lower part of the housing 110. The process water inlet 118 provides a passage through which the process water pipe 154 of the cooling water sprayer 150 described below is penetrated.

The filler member 120 is formed at a position higher than the first air inlet 111 in the housing 110. The filler part 120 is formed with a horizontal area corresponding to the horizontal cross-sectional area of the housing 110 and filled with a filler (not shown) having a plurality of pores therein. The filler part 120 may be formed of a filler used in a general cooling tower. The filler part 120 is formed so that external air flowing into the first air inlet 111 passes through and flows upward. The filling material part 120 allows the treated water jetted from the treated water jetting part 130 to be cooled while being in contact with the outside air. That is, the filler part 120 passes through the upper part of the upward air rising from the lower part, and the lower part of the treatment water injected from the upper part passes.

The treated water sprayer 130 is formed to include a treated water spray tube 131 and a spray nozzle 132. The treated water sprayer 130 is used in a process facility to spray treatment water having a relatively high temperature onto the upper portion of the filler material portion 120. The treated water sprayer 130 may be formed of a spray nozzle used in a general cooling tower. The treated water spraying part 130 is formed in the upper part of the filler part 120 in the housing 110 to spray the treated water to the upper part of the filler part 120.

The treatment water injection pipe 131 is formed of a pipe having an inner hollow portion and is formed extending in the horizontal direction in a radial form or a lattice form on the filler portion 120. One end of the process water injection pipe 131 is connected to the process water inflow pipe 116a through the process water inflow port 116. [ The treatment water injection tube 131 receives treatment water through the treatment water inflow pipe 116a.

The injection nozzles 132 are coupled to the lower portion of the process water injection pipe 131 at regular intervals. The injection nozzle 132 injects the process water supplied from the process water injection pipe 131 into the upper part of the filler part 120.

One end of the process water supply pipe 140 is connected to the process water inlet 116 and the other end of the process water supply pipe 140 is connected to the process water injection pipe 131 of the process water sprayer 130. The treatment water supply pipe 140 extends from the outer side to the inner side in the lower part of the housing 110 and then extends upwardly and is connected to the treatment water injection pipe 131 through the filler part 120. The process water supply pipe 140 may extend from the outside of the housing 110 to the inside of the housing 110 while being immersed in the treated water collected in the water collecting tank 119. Therefore, the relatively high temperature process water flowing into the process water supply pipe 140 is lowered in temperature as the heat exchange with the process water of the relatively low temperature water collection tank 119 proceeds. In addition, the treated water of the treated water supply pipe 140 passes through the filler member 120 and the temperature thereof is lowered. Therefore, the treated water supply pipe 140 supplies the treated water having a lower temperature to the treated water spray pipe 131, thereby lowering the temperature of steam generated, and ultimately reducing the occurrence of white smoke.

On the other hand, the treated water supply pipe 140 may be omitted when the treated water spraying unit 130 is directly connected to the treated water inflow pipe 116a. That is, when the treated water inlet 116 is formed in the upper part of the housing 110 and the treated water inflow pipe 116a is directly connected to the treated water spray tube 131 of the treated water sprayer 130, The supply pipe 140 is omitted.

The cooling water spraying unit 150 includes a cooling water spraying pipe 151 and a cooling water pipe 153. The cooling water spraying unit 150 may further include a treatment water pipe 154, a circulation pump 155, and a cooling unit 156.

The cooling water spraying unit 150 injects cooling water having a lower temperature than the treated water sprayed from the treated water spraying unit 130 at the upper portion of the treated water spraying unit 130 to lower the temperature of the saturated water vapor. Accordingly, as the temperature of the saturated steam is lowered, the fine mist contained therein is condensed with each other, and the particle size is increased, so that the discharged water vapor can be efficiently collected at the discharge unit 160. The cooling water injected from the cooling water injecting unit 150 is collected in the water collecting tank 119 under the housing 110.

The cooling water injection pipe 151 is formed of a pipe having an inner hollow portion and is located at an upper portion of the process water injection portion 130. The cooling water discharge pipe 151 is formed to include at least one pipe extending from the side where the cooling water pipe inlet 117 is formed to the opposite side. In addition, the cooling water injection pipe 151 may be formed in parallel with a plurality of pipes spaced apart from each other by a predetermined distance in a direction perpendicular to the extending direction. In addition, the cooling water discharge pipe 151 may be formed in a radial form or a lattice form. One end of the cooling water injection pipe 151 is connected to a cooling water pipe 153 passing through the cooling water pipe inlet 117. The cooling water injection pipe 151 receives cooling water through a cooling water pipe 153.

The cooling water injection pipe 151 is further formed with a spray hole 152 penetrating downward. The injection hole 152 injects the supplied cooling water downward, that is, in the direction of the process water jetting part 130. The injection holes 152 are formed at a predetermined distance apart from the lower portion of the cooling water injection pipe 151.

The cooling water pipe 153 is formed of a hollow pipe and extends from the outside of the housing 110 to the inside of the housing 110 through a cooling water pipe inlet 117 so that one side is connected to the cooling water pipe 151 do. The cooling water pipe (153) supplies cooling water to the cooling water discharge pipe (151). The other side of the cooling water pipe 153 is connected to the circulation pump 155 and receives cooling water supplied from the circulation pump 155 and cooled by the cooling unit 157 and supplies the cooling water to the cooling water injection pipe 151. In addition, the cooling water pipe 153 can receive the cooling water from another cooling water supply means (not shown) and supply it to the cooling water injection pipe 151. Meanwhile, the cooling water pipe 153 may be formed so that a portion passing through the inside of the cooling unit 157 is curved to increase the cooling efficiency.

One end of the water pipe 154 extends from the outside of the housing 110 to the interior of the housing 110 through the water inlet 118 and the other end is connected to the circulation pump 155, Lt; / RTI > The treatment water pipe 154 supplies the treated water of the water collecting tank 119, which flows into one side by the operation of the circulation pump 155, to the circulation pump 155.

The circulation pump 155 is formed of a general pump for supplying water. The circulation pump 155 has a treatment water pipe 154 connected to an inlet thereof and a cooling water pipe 153 connected to an outlet thereof. The circulation pump 155 introduces the treated water of the water collecting tank 119 to the cooling water pipe 153 through the treatment water pipe 154.

The cooling unit 156 may be a general heat exchanger using process cooling water. For example, the cooling unit 156 is hollow so that the process cooling water flows from one side and the process cooling water flows out from the other side. Further, the cooling unit 156 is formed so that the cooling water pipe 153 passes through the inside thereof. The cooling unit 156 is formed to enclose the outer surface of the cooling water pipe 153. The cooling water is supplied from the circulation pump 155 using process cooling water to cool the process water flowing in the cooling water pipe 153, . Further, the cooling unit 156 may be formed to surround the outer surface of the process water pipe. Therefore, the cooling unit 156 cools the process water flowing in the process water pipe 154 to be the cooling water.

The discharging unit 160 includes a collecting plate 161 and a discharging electrode 162. The discharge unit 160 is formed between the process water jetting unit 130 and the discharge unit 170 in the housing 110. The discharge unit 160 collects and collects the mist mixed in the saturated water vapor by the corona discharge (or the low temperature plasma discharge) generated between the collector plate 161 and the discharge electrode 162.

The discharge unit 160 may be formed to have a required height and width according to the amount of treated water flowing into the cooling tower, the amount of saturated water vapor generated, and the amount of mist contained in the saturated water vapor. The collecting area of the discharging space and the mist is increased according to the height and the total width of the discharging unit 160, and the collecting efficiency is increased. However, the discharge unit 160 may be formed to have a proper height and width depending on the limitation of the installation space of the cooling tower and the installation space of the discharge unit 160 inside the housing.

The discharge unit 160 may include separate spray means (not shown) for spraying water or steam to the lower portion of the discharge unit 160, though not shown in detail. The spraying means may spray water or steam to saturated water vapor to increase the size of the mist contained in the saturated water vapor. The mist is combined with water or water vapor to increase in size and fall downward before entering the discharge unit 160, and the amount of mist of the saturated water vapor is reduced. Accordingly, the dust collecting efficiency of the mist can be increased. On the other hand, water or water vapor sprayed by the spraying means is sprayed at a temperature lower than the temperature of the treated water, so that it does not generate additional saturated water vapor in contact with the treated water.

The water collecting plate 161 is formed in a plurality of plates having a width and a height and is positioned in a vertical direction inside the housing 110, and a plurality of the water collecting plates 161 are spaced apart from each other in the horizontal direction. The water collecting plate 161 is installed parallel to the flow direction of the saturated water vapor. A plurality of the water collecting plates 161 are spaced apart at regular intervals by a separate support member (not shown) and are installed parallel to each other. The space between the collecting plates 161 is directly spatially connected to the upper part of the treated water spraying unit 130 and the saturated water vapor passing through the treated water spraying unit 130 flows into the collecting plate 161. Accordingly, the saturated water vapor passes through the space between the collecting plate 161 and the collecting plate 161 through the treated water injecting unit 130. The water collecting plate 161 allows the mist contained in the water vapor to be charged and collected on the surface.

The collecting plate 161 is formed with a vertical height L required to collect the charged mist. When the flow rate of water vapor passing through the discharge unit 160 is high or the temperature of the process water to be sprayed is high and the mist moving speed is high, the vertical height L of the water collecting plate 161 is increased, Can be increased. The vertical height (L) is 200 to 1,000 mm. If the vertical height (L) is too large, the collection efficiency of the mist increases, but the current can be increased and the consumed power can be increased. If the vertical height L is too small, the charged mist can not be collected on the collecting plate 161 and may flow to the upper part of the discharging unit 160.

The collector plate 161 is made of an electrically conductive material and is electrically connected to a cathode of a separate control unit (not shown) to form a cathode. Preferably, the water collecting plate 161 is made of CFRP mixed with hastelloy, stainless steel or fiber reinforced plastics (FRP) and carbon, and the durability against corrosion is increased. Meanwhile, the collector plate 161 may be connected to the ground of the white smoke reduction cooling tower 100.

The discharge electrode 162 is formed to include a support rod 163 and a discharge plate 164. The discharge electrodes 162 extend in the horizontal direction in the space between the collecting plates 161, and a plurality of the discharge electrodes 162 are formed at a predetermined interval in the vertical direction. A plurality of the discharge electrodes 162 are spaced apart from each other at regular intervals by a separate support member (not shown), and are installed parallel to each other.

The discharge electrode 162 is made of a conductive material as a whole, and is electrically connected to the anode of the control unit to form an anode. Therefore, the discharge electrode 162 causes a corona discharge together with the collecting plate 161.

The support bar 163 is formed into a rod or a bar shape such as a cylindrical column, a rectangular column, or a polygonal column. The support rods 163 extend in the horizontal direction in the space between the collector plates 161 and are spaced a predetermined distance apart in the vertical direction. A plurality of the support rods 163 are spaced apart at regular intervals by a separate support member (not shown) and are installed parallel to each other. The support rod 163 is made of a conductive material as a whole, and is electrically connected to the anode of the control unit to form an anode.

The discharge plate 164 is formed in a plate or block shape and includes a coupling hole 165 formed at the center and a projection 166 formed at the outer side. The discharge plate 164 is inserted into the coupling hole 165 with a support rod 163 and is coupled to the support rod 163 in a vertical direction. A plurality of the discharge plates 164 are coupled to the support rods 163 at a predetermined vertical distance D along the horizontal direction. The vertical distance D of the discharge plate 164 affects the density of the electric lines of force generated between the discharge plate 161 and the discharge plate 164 during discharge. Accordingly, when the mist flows between the collector plate 161 and the discharge plate 164, the degree of discharge is controlled according to the vertical distance D to effectively collect the mist. The discharge plate 164 is spaced apart by a vertical distance D of 5 to 100 mm, preferably 10 to 20 mm. If the vertical distance D is too small, the frequency of sparking becomes too high when the same voltage is applied due to excessive densification of the electric force lines. If the vertical distance D is too large, the ionization rate of the mist and the degree of generation of electrons are lowered, and the charging efficiency of the mist is lowered, thereby lowering the collection efficiency of the mist.

The discharge plate 164 is formed of a conductive material, and may be formed of hastelloy or stainless steel, which is preferably excellent in corrosion resistance.

The protrusions 166 may protrude from the outer surface of the discharge plate 164 and may have a triangular shape or a fin shape so as to have a sharp edge. The projections 166 are formed on the outer surface of the discharge plate 164 in regular shapes and intervals. Accordingly, the discharge unit 160 uniformly advances the corona discharge between the collecting plate 161 and the protrusions 166, so that more mist can be collected. The projection 166 is formed such that an end thereof is spaced apart from the catcher plate 161 by a horizontal distance d. The horizontal distance d determines a discharge voltage applied between the collector plate 161 and the discharge electrode 162. The horizontal distance d is preferably 50 to 200 mm. If the horizontal distance d is too small, the discharge voltage must be small, so that the discharge is not sufficient and the collection efficiency is low. If the horizontal distance d is too large, the discharge voltage becomes too high, and the moving distance of the charged mist becomes long, so that the collecting efficiency can be lowered.

Also, the horizontal distance d is proportional to the applied discharge voltage. The discharge voltage according to the horizontal distance d may be 20 to 50 kV. As the horizontal distance d increases, the discharge voltage applied between the collector plate 161 and the discharge electrode 162 increases. Further, the horizontal distance d increases according to the amount of mist contained in the steam. If the discharge voltage is too low, the discharge efficiency is decreased. If the discharge voltage is too high, the corona discharge does not proceed, and a spark discharge is generated to generate a flame.

The protrusions 166 are formed in a sharp shape at the ends thereof, so that the discharge voltage can be reduced. That is, since the discharge is progressed by the inequalent electric field system of the surface plate and the discharge plate 164, the corona discharge is more efficiently performed at a low discharge voltage, and the mist is effectively charged and collected.

The discharge plate 164 may be welded to the support rod 161 or fixed to the discharge plate 164 by a separate fixed guide (not shown). The fixing guide is formed into a ring shape and inserted into the support rod 161 to be separated from the discharge plates 164. In addition, the discharge plate 164 may be formed integrally with the support rod 163. That is, the discharge plate 164 may be formed by projecting the surface of the support rod 163.

The discharge unit 170 includes a motor 171 and a cooling fan 172. The discharge unit 170 is coupled to the upper air outlet 114 at an upper portion of the housing 110 to discharge exhaust air having passed through the discharge unit 160 to the outside of the housing 110. The discharge unit 170 may be formed as a discharge unit 170 used in a general cooling tower.

The motor 171 is used as a motor for the cooling tower and is coupled to the upper air outlet 114 by a separate support member 171a.

The cooling fan 172 is connected to the motor 171 by a rotary shaft and is rotated by a motor 171. The cooling fan 172 discharges the exhaust air to the outside of the housing 110.

Next, the operation of the white smoke reduction cooling tower according to one embodiment of the present invention will be described.

The motor 171 and the cooling fan 172 of the discharge portion 170 coupled to the upper air outlet 114 from the upper portion of the housing 110 are operated and the outside air outside the housing 110 is supplied to the first air And flows into the interior of the lower portion of the housing 110 through the inlet port 111. The outside air rises while passing through the filler part 120 while rising. On the other hand, the process water supply pipe 140 receives the process water having a relatively high temperature from the process water inlet pipe 116a of the process facility connected to the process water inlet port 116, and supplies the process water to the process water spraying unit 130 . At this time, the treated water supply pipe 140 passes through the water collecting tank 119 and the filler part 120 to cool the treated water in a primary process. The treated water is injected into the upper portion of the filler portion 120 while flowing through the treated water injection tube 131 of the treated water injector 130 and the injection nozzle 132. The treated water drops downward and comes into contact with outside air rising from the bottom. The treated water is continuously in contact with the outside air at the upper portion, the inside and the lower portion of the filler portion 120. Therefore, the outside air is brought into contact with the treated water, and the temperature rises, and the dew point rises and the humidity rises to become saturated water vapor. The cooling water spraying pipe 151 of the cooling water spraying part 150 injects the relatively low temperature cooling water supplied from the cooling water pipe into the saturated water vapor to lower the temperature of the saturated water vapor to condense the mist in the saturated water vapor to increase the particle size . At this time, the cooling water supplied to the cooling water pipe can be used as a treatment water which is introduced from the water collecting tank through the treatment water pipe by the circulation pump. Accordingly, the discharge unit 160 collects and collects the mist of which the particle size is increased by the cooling water, so that the mist is collected and removed more efficiently. Meanwhile, the external air introduced through the second air inlet 112 is mixed with the saturated water vapor to lower the temperature and the relative humidity of the saturated water vapor. The saturated water vapor flows into the spaces between the collecting plates 161 of the discharging unit 160 while rising. At this time, the discharge unit 160 generates a corona discharge by a discharge voltage applied between the discharge plate 161 and the discharge electrode 162. The mist contained in the saturated water vapor is charged while being polarized by the applied discharge voltage, and the particle size is increased by attraction between the different electrodes. The mist is collected in the collector plate 161 or the discharge electrode 162 and flows downward and is collected in the collecting tank 119 located in the lower portion of the housing 110. [ The saturated water vapor rises to the upper portion of the discharge unit 160 in a state in which the humidity is relatively low, and becomes exhaust air. The external air introduced into the third air inlet 113 is mixed with the exhaust air passing through the discharge unit 160 to shorten the time taken for the mist to be absorbed into the outside air which is in contact with the exhaust air from the outside of the housing 110, Can be reduced. That is, since the mist contained in the exhaust air is absorbed by the incoming external air inside the housing 110, the degree of absorption of mist into the outside air from the outside of the housing 110 can be reduced, and the occurrence of white smoke can be reduced. The discharge air is discharged to the outside of the housing 110 by the discharge unit 170. The discharged air is discharged to the outside of the housing 110 in a low humidity state, and is contacted with the outside air, so that occurrence of white smoke is reduced.

Next, a white smoke reduction cooling tower according to another embodiment of the present invention will be described.

FIG. 5 is a bottom cross-sectional view corresponding to FIG. 4 of the discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.

1 to 5, the white smoke reduction cooling tower according to another embodiment of the present invention includes a housing 110, a filler portion 120, a treated water sprayer 130, a discharge portion 260, 170). The white smoke reduction cooling tower may further include a treatment water supply pipe 140.

The whitening reduction cooling tower according to another embodiment of the present invention is formed in the same or similar structure as the whitening reduction cooling tower 100 according to FIGS. 1 and 3 except for the discharge portion 260. Therefore, only the discharging unit 260 will be described below, not illustrating the entire structure of the white smoke reduction cooling tower according to another embodiment of the present invention. 1 and 3, the same components as those of the discharge unit 160 of the white smoke reduction cooling tower 100 according to FIGS. 1 and 3 are denoted by the same reference numerals, and a detailed description thereof will be omitted. .

The discharge unit 260 is formed to include a discharge plate 161 and a discharge electrode 262.

The discharge electrode 262 is formed to include a support rod 263 and a discharge plate 264. The discharge electrodes 262 extend in the vertical direction in the space between the collecting plates 161, and a plurality of the discharge electrodes 262 are formed at a predetermined interval in the horizontal direction. A plurality of the discharge electrodes 262 are spaced apart from each other at regular intervals by a separate support member (not shown), and are installed parallel to each other. The discharge electrode 262 is formed such that the discharge plate 264 is spaced apart from the surface of the collector plate 161 by a predetermined distance.

The support rods 263 extend in the vertical direction in the space between the collecting plates 161, and a plurality of the support rods 263 are spaced apart from each other by a predetermined distance in the horizontal direction.

The discharge plate 264 is formed in a plate or block shape and includes a coupling hole 265 formed at the center and a projection 266 formed at the outer side. The discharge plate 264 is inserted into the coupling hole 265 and the support rod 263 is coupled to the support rod 263 in the horizontal direction. The discharge plate 264 may be inclined such that the outer surface of the discharge plate 264 on which the protrusions 266 are formed is directed downward or upward. When the discharge plate 264 is formed obliquely, the trapped mist becomes larger in particle size as it flows more easily through the inclined surface of the discharge plate 264. Accordingly, the collected mist flows down toward the protrusion 266. The collected mist flows in the direction of the support rod 263, and a hole (not shown) through which the mist can pass through the support rod 263 ) Is formed, it falls down through the hole.

A plurality of the discharge plates 264 are coupled to the support rods 263 at predetermined intervals along the vertical direction. That is, the discharge plate 264 is connected to the discharge plate 164 of the discharge unit 160 according to FIGS. 1 and 2 except that the discharge plate 264 is horizontally coupled to the support rod 263 and is spaced apart in the vertical direction. Respectively.

Next, a white smoke reduction cooling tower according to another embodiment of the present invention will be described.

FIG. 6 is a bottom cross-sectional view corresponding to FIG. 4 of the discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.

1 to 6, the white smoke reduction cooling tower according to another embodiment of the present invention includes a housing 110, a filler portion 120, a treated water sprayer 130, a discharge portion 360, (Not shown). The white smoke reduction cooling tower may further include a treatment water supply pipe 140.

The whitening reduction cooling tower according to another embodiment of the present invention is formed in the same or similar shape as the whitening reduction cooling tower according to FIGS. 1 to 5 except for the discharge part 360. Therefore, the discharging unit 360 of the white smoke reduction cooling tower according to another embodiment of the present invention will be mainly described below. 4 and 5, the same components as those of the discharge unit 260 of the white smoke reduction cooling tower according to FIGS. 4 and 5 are denoted by the same reference numerals, and a detailed description thereof will be omitted. Hereinafter, Explain.

The discharge unit 360 is formed to include a collecting plate 361 and a discharge electrode 262.

The collector plate 361 is formed to have a lattice shape with a dust collecting passage 361a having open upper and lower parts and hollow inside. The collector plate 361 is formed such that the horizontal cross-sectional shape of the dust collection passage 361a is rectangular. That is, the collector plate 361 may be formed to have a lattice shape while horizontally arranging a rectangular tube having a hollow interior. In addition, the collector plate 361 may have a circular cross-sectional shape. That is, the water collecting passage 361a may be formed to have a cylindrical shape.

The collector plate 361 is located inside the housing so that the central axis thereof is vertical, and a plurality of the collector plates 361 are formed to be in a lattice shape by being in contact with each other. The collecting plate 361 is formed so that the entire horizontal area is the same as the horizontal area inside the housing. The inner space of the water collecting plate 361 is directly connected to the upper space of the filler part 120 so that saturated water vapor is introduced into the water collecting plate 361 in parallel with the flow direction of the saturated water vapor.

The discharge electrode 262 is formed to include a support rod 263 and a discharge plate 264.

The support bar 263 is formed to extend in the vertical direction within the dust collecting passage 361a of the collecting plate 361.

The discharge plate 264 is formed to include a coupling hole 265 and a projection 266. The discharge electrode 262 is installed to extend in the vertical direction in the inner space of the collecting plate 361. The discharge electrode 262 is formed such that the discharge plate 264 is spaced apart from the surface of the collector plate 361 by a predetermined distance.

The corona discharges uniformly between the collector plate 361 and the protrusions 266 because the discharge plate 360 and the protrusions 266 of the discharge electrode 262 are uniformly spaced as a whole . The discharger 360 can collect more mist.

Next, a white smoke reduction cooling tower according to another embodiment of the present invention will be described.

7 is a bottom view of a discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.

1 to 7, the white smoke reduction cooling tower according to another embodiment of the present invention includes a housing 110, a filler portion 120, a treated water sprayer 130, a discharge portion 460, (Not shown). The white smoke reduction cooling tower may further include a treatment water supply pipe 140.

The white smoke reduction cooling tower according to another embodiment of the present invention is formed in the same or similar to the white smoke reduction cooling tower according to FIG. 6 except for the discharge part 460. Therefore, the discharging unit 460 of the white smoke reduction cooling tower according to another embodiment of the present invention will be mainly described below. The same components as those of the discharge unit 260 of the white smoke reduction cooling tower shown in FIG. 6 are denoted by the same reference numerals, and a detailed description thereof will be omitted.

The discharge unit 460 includes a collecting plate 461 and a discharge electrode 262. The discharger 460 is formed in the same manner as the discharger 360 according to FIG. 6 except that the shape of the collecting plate 461 is different. More specifically, the water collecting plate 461 is formed to have a dust collecting passage 461a which is open at the top and bottom and hollow inside. The collector plate 461 is formed such that the dust collecting passage 461a has a hexagonal cross-sectional shape. That is, the water collecting passage 461 is formed in a hexagonal tube shape. Accordingly, the discharge part 460 is formed such that the horizontal cross-sectional shape has a honeycomb shape as a whole. In addition, the collector plate 461 may have a horizontal cross-sectional shape in a triangular shape, and six triangular shapes may be formed to have a hexagonal shape with one vertex thereof facing each other. That is, the water collecting plate 461 may be formed to have the water collecting passage 461a in the shape of a triangular bar. In the case where the discharge part is formed in a rectangular shape or a cylindrical shape, the space a between the collecting plates may be shielded by a separate member so that steam does not flow.

Next, a white smoke reduction cooling tower according to another embodiment of the present invention will be described.

8 is a bottom view of a discharging part provided in the white smoke reduction cooling tower according to another embodiment of the present invention.

1 to 6 and 8, the white smoke reduction cooling tower according to another embodiment of the present invention includes a housing 110, a filler portion 120, a treated water sprayer 130, a discharge portion 560, And a discharging portion 170. As shown in Fig. The white smoke reduction cooling tower may further include a treatment water supply pipe 140.

The white smoke reduction cooling tower according to another embodiment of the present invention is formed in the same or similar structure as the white smoke reduction cooling tower according to FIG. 6 except for the discharge portion 560. Therefore, the discharging unit 560 of the white smoke reduction cooling tower according to another embodiment of the present invention will be mainly described below. The same components as those of the discharge unit 260 of the white smoke reduction cooling tower according to FIG. 6 are denoted by the same reference numerals, and a detailed description thereof will be omitted below.

The discharging unit 560 includes a collecting plate 561 and a discharge electrode 262. The discharger 560 is formed in the same manner as the discharger 360 according to FIG. 6 except that the shape of the collecting plate 561 is different. More specifically, the water collecting plate 561 is formed to have a dust collecting passage 561a which is open at the top and bottom and hollow inside. The collector plate 561 is formed so that the dust collecting passage 561a has a circular cross-sectional shape. Meanwhile, in the case where the overall shape of the discharge part is formed into a square shape or a cylindrical shape, the void areas a and b between the collector plates may be formed so as to be shielded by a separate member (not shown) .

Next, a white smoke reduction cooling tower according to another embodiment of the present invention will be described.

9 is a vertical cross-sectional view corresponding to FIG. 1 of a white smoke reduction cooling tower according to another embodiment of the present invention. 10 is a bottom cross-sectional view taken along line C-C of Fig.

1, 9, and 10, the white smoke reduction cooling tower 200 according to another embodiment of the present invention includes a housing 210, a filler portion 120, a treated water sprayer 130, (250), a discharge unit (160), and a discharge unit (170). The white smoke reduction cooling tower 200 may further include a treated water supply pipe 140.

The white smoke reduction cooling tower 200 according to another embodiment of the present invention includes a heat exchanging part 250 instead of the cooling water spraying part 150 of FIG. 1, so that a part of the housing 210 is formed differently And is formed in the same manner as the white smoke reduction cooling tower according to FIG. Therefore, the following description will focus on the coupling relationship of the white smoke reduction cooling tower 200 with the heat exchanger 250 and the housing 210 according to another embodiment of the present invention. The same components of the white smoke reduction cooling tower 200 as those of the white smoke reduction cooling tower 100 shown in FIG. 1 are denoted by the same reference numerals, and a detailed description thereof will be omitted.

The heat exchange unit 250 includes a cooling pipe 251, a cooling water supply pipe 254, and a cooling water discharge pipe 255. The cooling water supplied from the cooling water supply device is sequentially supplied to the cooling water supply pipe 254, the cooling pipe 251 and the cooling water discharge pipe 255 in sequence Flow. The heat exchanger 250 is located above the treated water sprayer 130 and cools the saturated water vapor rising from the lower part of the treated water sprayer 130 to the upper part to lower the temperature of the saturated water vapor. Accordingly, as the temperature of the saturated steam is lowered, the fine mist contained therein is condensed with each other and the particle size is increased, so that the discharged water vapor can be efficiently collected at the discharge unit 160.

The cooling pipe 251 includes a horizontal cooling pipe 252 and a fresh cooling pipe 253. The horizontal cooling pipe 252 and the vertical cooling pipe 253 are formed to have a flat shape corresponding to the inner horizontal surface shape of the housing 210 as a whole 253 are disposed. Accordingly, the cooling pipe 251 is formed to have a rectangular shape as a whole. Meanwhile, when the inner horizontal surface of the housing 110 is circular, the planar shape may be circular. At this time, the horizontal cooling pipe 254 and the vertical cooling pipe 255 may not be distinguished as shown in FIG. Here, the horizontal and vertical lengths are determined based on FIG. In addition, one side refers to the right side of Fig. 10, and the other side refers to the left side in Fig. The front side refers to the direction in which the cooling water supply pipe 254 is located, and the rear side refers to the direction in which the cooling water discharge pipe 255 is located.

The transverse cooling pipes 252 are formed by a plurality of tubes extending from one side to the other side, that is, in the transverse direction and spaced apart from each other in the longitudinal direction. The horizontal cooling pipe (252) allows the cooling water to flow from one side to the other side inside.

The vertical cooling pipe 253 is formed of two pipes extending in a direction perpendicular to the horizontal cooling pipe 252 and connected to both ends of the horizontal cooling pipe 252. The vertical cooling pipe 253 supplies cooling water to one side of each of the horizontal cooling pipes 252 and allows cooling water discharged from the other side of each of the horizontal cooling pipes 252 to flow.

The cooling water supply pipe 254 is connected to a vertical cooling pipe 253 located at one side and supplies cooling water to the vertical cooling pipe 253. 10, the cooling water supply pipe 254 is biased to the front side and connected to the vertical cooling pipe 253, but may be offset to the rear side or may be located in the central area and connected to the vertical cooling pipe 253. [

The cooling water discharge pipe 255 is connected to the vertical cooling pipe 253 located at the other side and discharges the cooling water discharged from the vertical cooling pipe 253 to the cooling water supply device. As shown in FIG. 10, the cooling water discharge pipe 255 is connected to the vertical cooling pipe 253 at a rear side. However, the cooling water discharge pipe 255 may be offset toward the front side or may be located at a central area and connected to the vertical cooling pipe 253.

The housing 210 may further include a cooling water discharge pipe through hole 217a through which a cooling water supply pipe 254 is coupled and a cooling water discharge pipe through hole 217a through which a cooling water discharge pipe 255 is coupled have. The cooling water supply pipe through-hole 217a and the cooling water discharge pipe through-hole 217b may be formed to penetrate from the outside to the inside of the housing 210, preferably at the same height as the heat exchanging unit 250.

Next, a white smoke reduction cooling tower according to another embodiment of the present invention will be described.

11 is a horizontal sectional view of a discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.

1 to 4 and 11, the white smoke reduction cooling tower according to another embodiment of the present invention includes a housing 110, a filler portion 120, a treated water sprayer 130, and a discharge portion 660, And a discharging portion 170. As shown in Fig. The white smoke reduction cooling tower may further include a treatment water supply pipe 140.

The white smoke reduction cooling tower according to another embodiment of the present invention is formed in the same or similar structure as the white smoke reduction cooling tower according to FIGS. 1 to 4 except for the discharge portion 660. Therefore, the discharging unit 660 of the white smoke reduction cooling tower according to another embodiment of the present invention will be mainly described below. The same components as those of the discharge unit 160 of the white smoke reduction cooling tower 100 shown in FIGS. 3 and 4 are denoted by the same reference numerals and detailed description thereof will be omitted. Hereinafter, .

The discharge unit 660 includes a discharge plate 161 and a discharge electrode 662.

The discharge electrode (662) is formed in a plate shape and has a shape corresponding to the collector plate (161). A plurality of the discharge electrodes 662 are spaced apart at regular intervals by a separate support member (not shown) and are installed parallel to each other. The discharge electrode 662 is installed so as to face the collector plate 161 in a space between two adjacent collector plates 161. At this time, the discharge electrode (662) is positioned so as to be spaced apart from the surface of the collecting plate (161) whose both surfaces are opposite to each other.

The discharge unit 660 is formed in a plate-like shape, and the discharge is progressed by the discharge plate 161 and the discharge electrode 662 facing each other, so that the discharge can proceed in a wider area. Therefore, the dust collecting efficiency of the mist can be increased in the discharger 660.

100, 200: White smoke reduction cooling tower
110: housing 120: filler part
130: treated water jetting section 140: treated water supply pipe
150: Cooling water distributing part
160, 260, 360, 460, 560, 660:
170:
250: Heat exchanger

Claims (16)

A housing having a hollow interior and formed at a lower portion thereof, the housing including a first air inlet through which external air flows and an upper air outlet through which the exhaust air is discharged;
A filler portion formed at a position higher than the first air inlet in the housing and configured to allow the external air to pass therethrough,
A processing water spraying part located at an upper portion of the filling material part inside the housing and spraying treated water to an upper part of the filling material part;
A cooling water spraying unit for spraying cooling water having a temperature lower than that of treated water sprayed from the treated water spraying unit to the upper portion of the treated water spraying unit above the treated water spraying unit,
A discharge unit which is located at an upper portion of the cooling water spraying unit inside the housing and collects and collects mist contained in water vapor formed by contact between the treated water and outside air by discharge,
And a discharge unit located at the upper air discharge port and discharging the discharge air passed through the discharge unit. The method according to claim 1,
The housing further includes a cooling water pipe inlet located above the treated water injection portion,
The cooling water injector
A cooling water discharging pipe formed inside the hollow pipe and spraying the cooling water through the spray hole formed at the lower part,
And a cooling water pipe extending from the outside of the housing to the inside of the housing through the cooling water inflow pipe and connected to the cooling water injection pipe to supply cooling water to the cooling water injection pipe. 3. The method of claim 2,
The housing further comprises a process water inlet formed at the bottom,
The cooling water injector
A treatment water pipe extending from the outside of the housing to the inside of the housing through a treatment water inlet,
A circulation pump connected to the treatment water pipe at an inlet thereof and connected to the cooling water pipe at an outlet thereof, for introducing treatment water collected at a lower portion of the housing through a treatment water pipe to the cooling water pipe,
Further comprising a cooling unit configured to surround the outside of the process water pipe or the cooling water pipe and cooling the process water using process cooling water supplied from the outside. The method according to claim 1,
The housing has a water collecting tank which is hermetically closed at the bottom and collects the treated water sprayed from the treated water spraying part and the cooling water sprayed from the cooling water spraying part, and the water level of the treated water and the cooling water collected in the water collecting tank below the housing And a process water inlet formed at a lower position,
And a treatment water supply pipe connected to the treatment water inlet at one side in the housing and connected to the treatment water sprayer at the other side to supply treatment water. The method according to claim 1,
The discharge unit
A plurality of water collecting plates formed in a plate shape and positioned in the vertical direction inside the housing and spaced apart from each other in the horizontal direction,
A plurality of support plates extending in the horizontal direction between the support plates and spaced apart from each other in the vertical direction, a coupling hole formed at the center and a protrusion formed at the outer side, and a discharge plate coupled to the support rod through the coupling hole, And a discharge electrode,
And the discharge progresses between the discharge plate and the discharge plate of the discharge electrode. The method according to claim 1,
The discharge unit
A plurality of water collecting plates formed in a plate shape and positioned in a vertical direction inside the housing and spaced apart from each other in the horizontal direction,
A plurality of support bars extending in the vertical direction between the support plates and spaced apart from each other in the horizontal direction, a coupling hole formed at the center and protrusions formed at the outer side, and a discharge coupled to the support bar through the coupling hole And a discharge electrode having a plate,
And the discharge progresses between the discharge plate and the discharge plate of the discharge electrode. The method according to claim 1,
The discharge unit
A collecting plate having upper and lower openings and formed with hollow collecting passages arranged in a lattice form and
And a discharge electrode having a support rod extending vertically in the dust collecting passage of the collector plate, a coupling hole formed at the center and a protrusion formed on the outer side, and a discharge plate coupled to the support rod through the coupling hole In addition,
And the discharge progresses between the collector and the discharge electrode of the discharge plate. 8. The method of claim 7,
The white smoke reduction cooling tower according to claim 1, wherein the water collecting passage is formed by arranging a triangular barrel, a rectangular barrel, a cylindrical barrel, or a hexagonal barrel having openings in the upper and lower parts and hollow inside thereof. The method according to claim 1,
Wherein the housing further comprises a second air inlet formed between the cooling water spraying part and the discharge part to allow the outside air to flow therein. The method according to claim 1,
Wherein the housing further comprises a third air inlet formed between the discharge unit and the discharge unit to allow the outside air to flow. The method according to any one of claims 5 to 7,
The collector plate is formed at a vertical height of 200 to 1,000 mm,
The discharge plates are spaced apart from each other in the vertical direction by a vertical distance of 5 to 100 mm,
And the protrusions of the discharge plate and the discharge plate are horizontally spaced apart by a horizontal distance of 50 to 200 mm. The method according to claim 1,
The discharge unit
A plurality of water collecting plates formed in a plate shape and positioned in a vertical direction inside the housing and spaced apart from each other in the horizontal direction,
And a discharge electrode which is formed in a plate shape and is formed in a shape corresponding to the collector plate and is formed to be positioned vertically between the collector plates,
And the discharge progresses between the collector and the discharge electrode. A housing having a hollow interior and formed at a lower portion thereof, the housing including a first air inlet through which external air flows and an upper air outlet through which the exhaust air is discharged;
A filler portion formed at a position higher than the first air inlet in the housing and configured to allow the external air to pass therethrough,
A processing water spraying part located at an upper portion of the filling material part inside the housing and spraying treated water to an upper part of the filling material part;
A heat exchanging unit located above the treated water jetting unit and cooling water vapor rising above the treated water jetting unit,
A discharge unit located at an upper portion of the heat exchange unit inside the housing and collecting and collecting mist contained in water vapor formed by contact between the treated water and outside air by discharge;
And a discharge unit located at the upper air discharge port and discharging the discharge air passed through the discharge unit. 14. The method of claim 13,
The heat-
A cooling pipe which is formed of a hollow pipe and in which cooling water flows;
A cooling water supply pipe connected to one side of the cooling pipe and supplying cooling water to the cooling pipe,
And a cooling water discharge pipe connected to the other side of the cooling water pipe and discharging cooling water from the cooling pipe. 15. The method of claim 14,
The cooling pipe includes a plurality of horizontal cooling pipes extending from one side to the other side and spaced apart from each other,
And two vertical cooling pipes extending in a direction perpendicular to the horizontal cooling pipes and connected to both ends of the horizontal cooling pipes,
Wherein the cooling water supply pipe and the cooling water discharge pipe are respectively connected to the vertical cooling pipe. 15. The method of claim 14,
The housing
A cooling water supply pipe through-hole through which the cooling water supply pipe passes
And a cooling water discharge pipe through which the cooling water discharge pipe passes.

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