KR20160045651A - Cooling Tower Abating Plume - Google Patents

Abstract

According to the present invention, a plume-reducing cooling tower is disclosed, which comprises a housing, a filler unit, a spray nozzle unit, a discharge unit, and an exhausting unit. The discharge unit comprises: a plurality of water collection plates wherein a plurality of water collection passages are arranged on a flat surface; a discharge electrode inserted into the water collection passages to cause a corona discharge with the water collection plates; a support frame placed in an upper portion of the water collection plates, and supporting the discharge electrode to be spaced from the water collection plates; and an insulator module supporting the support frame in an internal side of the water collection plates for the water collection plates and the discharge electrode to be electrically insulated.

Description

{Cooling Tower Abating Plume}

The present invention is used in the cooling water supply equipment of a manufacturing factory or a general industrial factory using a semiconductor manufacturing facility, a flat panel display manufacturing facility, or a general industrial manufacturing facility, a cooling system of a factory building or a general building, The present invention relates to a cooling tower for reducing white smoke.

Generally, a cooling tower is a device for cooling high-temperature cooling water used in equipment installed outdoors in a building in which equipment for using cooling water is installed, such as semiconductor processing equipment. 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 portion of the side wall, and the low temperature external air flowing in the upper part and the high temperature cooling water flowing in the lower part are sprayed from the upper part to cool the cooling water having relatively high temperature. 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 cooling water at a high temperature and contains excessive moisture, 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 cooling water which is the main component of water, but it is perceived as a mixture of substances or pollutants harmful to the appearance, which causes the generation of complaints.

The present invention provides a cooling tower for reducing white smoke and capable of increasing white smoke reduction efficiency.

The white smoke reduction cooling tower of the present invention includes a housing having a hollow interior and including an upper air inlet for discharging outside air and a lower air inlet for discharging exhaust air; A spray nozzle part for spraying cooling water to an upper part of the filler part in an upper part of the filler part in the inside of the housing and a spray nozzle part for spraying cooling water in an upper part of the filler part, And a discharge unit for collecting and collecting the mist contained in the water vapor formed by the contact of the cooling water and the outside air by discharging, and a discharge unit which is located at the upper air discharge port and passes through the discharge unit, And a discharge unit for discharging the water, A discharge electrode inserted in the water collecting passage to cause a discharge with the water collecting plate; a discharge electrode located at an upper portion of the water collecting plate, the discharge electrode being spaced apart from the collecting plate, And an insulator module for supporting the support frame inside the collector plate so that the collector plate and the discharge electrode are electrically insulated from each other.

The housing includes a water collecting tank which is hermetically closed at the bottom and collects the cooling water injected from the injection nozzle unit, and a cooling water inlet formed at a lower position than the water level of the cooling water collected in the water collecting tank below the housing, And a cooling water pipe connected to the cooling water inlet port on one side of the housing and connected to the injection nozzle unit on the other side to supply cooling water.

In addition, the discharge unit may include a collecting plate formed in a lattice shape such that upper and lower collecting passages are arranged in a lattice pattern, a support rod extending vertically in the collecting passage of the collecting plate, A plurality of horizontal frames coupled to the upper ends of the support rods, and a vertical frame coupled to both sides of the horizontal frames. The plasma display apparatus of claim 1, further comprising: a discharge electrode having a projection formed on an outer side thereof and coupled to the support rod through the coupling hole; And a fixing plate fixed to the inner surface of the water collecting passage at a predetermined height, the insulator module being coupled to a lower portion of the insulator and including an insulator coupled to the fixing rod, . At this time, the water collecting passage may be formed to have a triangular barrel shape, a rectangular barrel shape, a cylindrical shape, or a hexagonal barrel shape in which the upper part and the lower part are opened and the inside is hollow.

The discharge unit may include a plurality of discharge plates formed in a plate shape and positioned vertically inside the housing and spaced from each other in the horizontal direction to form a water collecting passage, a support rod vertically disposed in the water collecting passage, A discharge electrode having a coupling hole formed therein and a projection formed on the outer side and coupled to the support rod through the coupling hole, a plurality of horizontal frames coupled to the upper end of the support bar, And a fixing plate coupled to a lower portion of the insulator and fixed at a predetermined height on an inner surface of the water collecting passage of the water collecting plate And the like.

The discharge unit may include a collecting plate having upper and lower openings and hollow collecting passages arranged in a lattice pattern, a supporting rod extending vertically in the collecting passage of the collecting plate, A discharge electrode having a coupling hole and a projection formed on the outer side and coupled to the support rod through the coupling hole; a plurality of horizontal frames coupled to an upper end of the support rod; The insulator module including a support frame having a frame and a fixing rod coupled to the horizontal frame, an insulator coupled to the fixing rod, and a fixing plate coupled to a lower portion of the insulator and positioned on an upper surface of the collecting passage of the collecting plate. . At this time, the water collecting passage may be formed to have a triangular barrel shape, a rectangular barrel shape, a cylindrical shape, or a hexagonal barrel shape in which the upper part and the lower part are opened and the inside is hollow.

The insulator module may further include an upper block coupled to a lower portion of the fixing rod and an upper portion of the insulator, and a lower block coupled to a lower portion of the insulator and an upper portion of the fixing plate.

The housing may further include an upper air inlet formed between the jet nozzle unit and the discharge unit to allow the outside air to flow.

The discharge plate is formed at a vertical height of 200 to 1,000 mm, and the discharge plates are spaced apart from each other in a vertical direction by a vertical distance of 5 to 100 mm, and the projections of the discharge plate and the discharge plate are 50 to 200 mm As shown in FIG.

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 corona discharge may be formed between the collector plate and the discharge electrode.

The white smoke reduction cooling tower of the present invention has the effect of effectively reducing the generation of white smoke of the exhaust air by removing the generated mist of the saturated water vapor by charging.

Further, in the white smoke reduction cooling tower of the present invention, since the insulator module for insulation between the collector plate and the discharge electrode is located above the collecting passage of the collector plate, the volume and the horizontal area of the discharge part can be reduced. In the same housing space, It is possible to increase the efficiency of reducing white smoke and to smooth the flow of noxious gas.

In addition, since the insulator of the insulator module is located inside the collecting passage of the collector plate, the white smoke reduction cooling tower of the present invention has the effect of reducing the volume and height of the discharge part.

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 recovering the mist contained in the saturated water vapor, thereby reusing the cooling water and reducing the operating cost.

FIG. 1A is a vertical sectional view of a white smoke reduction cooling tower according to an embodiment of the present invention. FIG.
FIG. 1B is an enlarged view of FIG.
Fig. 2 is a horizontal sectional view taken along line AA of Fig. 1A.
Fig. 3 is a horizontal sectional view taken along the line BB of Fig.
FIG. 4 is a horizontal sectional view corresponding to FIG. 3 of the discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.
FIG. 5 is a horizontal sectional view corresponding to FIG. 3 of the discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.
FIG. 6 is a horizontal sectional view corresponding to FIG. 3 of the discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.
7 is a vertical cross-sectional view corresponding to the discharging portion of FIG. 1A of the discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.
8 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.

FIG. 1A is a vertical sectional view of a white smoke reduction cooling tower according to an embodiment of the present invention. FIG. FIG. 1B is an enlarged view of FIG. Fig. 2 is a horizontal sectional view taken along line A-A in Fig. 1a. 3 is a horizontal sectional view taken along line B-B in Fig.

1A to 3, the white smoke reduction cooling tower 100 according to the embodiment of the present invention includes a housing 110, a filler portion 120, a spray nozzle portion 130, a discharge portion 150, (Not shown). In addition, the white smoke reduction cooling tower 100 may further include a cooling water pipe 140.

The white smoke reduction cooling tower 100 passes the saturated water vapor generated by the contact with the outside air into which the relatively high temperature cooling water supplied from the spray nozzle unit 130 flows into the discharge unit 160, By collecting and collecting the mist, the humidity of the saturated water vapor discharged to the outside is lowered. Here, the mist means fine water particles. 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 150 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 lower air inlet 111, an upper air outlet 113, a cooling water outlet 114, and a cooling water inlet 115. The housing 110 may further include an upper air inlet 112. 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 part of the housing 110 may be formed as a water collecting tank 116 in which the lower end is closed to collect the cooling water sprayed from the spray nozzle unit 130.

The lower 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 to allow an amount of external air required for cooling the cooling water injected from the injection nozzle unit 130 to flow. The lower air inlet 111 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 upper air inlet 112 is formed between the jet nozzle unit 130 and the discharge unit 160 to allow external air to flow into the upper air inlet 112 to be mixed with the saturated water vapor. The external air introduced into the upper air inlet 112 is mixed with the saturated water vapor, thereby lowering the temperature of the saturated water vapor and lowering the humidity. The upper air inlet 112 is formed to have a size necessary for introducing a sufficient amount of air to lower the temperature of the saturated water vapor and reduce the humidity. On the other hand, when the occurrence of white smoke is sufficiently reduced by the discharge unit 160, The upper air inlet 112 may not be formed.

The upper air outlet 113 is formed at an upper portion of the housing 110 and has a discharge unit 150 installed therein. The upper air outlet 113 allows the exhaust air passing through the discharge unit 160 to be discharged. The upper air outlet 113 is formed to have a size such that exhaust air can be smoothly discharged.

The cooling water outlet 114 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 cooling water. The cooling water outlet 114 allows the cooling water discharge pipe 114a connected to the process facility to be coupled. The cooling water outlet 114 allows the cooling water collected in the water collecting tank 116 to be supplied to the cooling water discharge pipe.

The cooling water inlet 115 is formed at a lower portion of the housing 110, and is preferably formed at a position lower than the water level of the collected cooling water. The cooling water inlet 115 is coupled to the cooling water pipe 140 located inside the housing 110 and the cooling water inlet pipe 115a connected to the process facility is coupled to the cooling water inlet 115. The cooling water inlet 115 allows the cooling water used in the process facility to flow into the cooling water pipe 140 through the cooling water inflow pipe. The cooling water inlet 115 is formed at a position where the injection nozzle unit 130 is formed when the cooling water pipe 140 is not formed in the housing 110 so that the injection nozzle unit 130 is coupled .

The filler part 120 is formed at a position higher than the lower 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 the external air flowing into the lower air inlet 111 passes through and flows upward. The filler part 120 allows the cooling water injected from the injection nozzle part 130 to be cooled while being in contact with the outside air. That is, the filler portion 120 passes through the upper portion of the rising air from the lower portion, and allows the cooling water injected from the upper portion to pass downward.

The injection nozzle unit 130 includes a spray tube 131 and an injection nozzle 132. The injection nozzle unit 130 is used in a process facility and injects cooling water having a relatively high temperature to the upper portion of the filler material portion 120. The injection nozzle unit 130 may be formed of a spray nozzle used in a general cooling tower. The injection nozzle unit 130 is disposed in the upper part of the filler member 120 in the housing 110 and is formed to inject cooling water into the upper part of the filler member 120.

The injection pipe 131 is formed of a pipe having an inner hollow and is formed to extend horizontally in a radial form or a lattice form at an upper portion of the filler portion 120. The injection pipe 131 is connected to the cooling water pipe 140 described below, and the cooling water flows from the outside.

The injection nozzles 132 are coupled to the lower side of the injection tube 131 at regular intervals. The injection nozzle 132 injects the cooling water supplied from the injection pipe 131 onto the filler part 120.

One end of the cooling water pipe 140 is connected to the cooling water inlet 115 and the other end of the cooling water pipe 140 is connected to the injection pipe 131 of the injection nozzle unit 130. The cooling water pipe 140 extends from the lower side of the housing 110 inwardly from the outside to the upper side and is connected to the injection pipe 131 through the filler part 120. The cooling water pipe 140 may extend from the outside of the housing 110 to the inside of the housing 110 while being locked to the cooling water collected in the water collecting tank 116 inside the housing 110. Accordingly, the cooling water having a relatively high temperature flowing into the cooling water pipe 140 is heat-exchanged with the cooling water of the water collection tank 116 having a relatively low temperature, so that the temperature is lowered. In addition, the cooling water of the cooling water pipe 140 passes through the filler part 120 and the temperature thereof is lowered. Accordingly, the cooling water pipe 140 supplies cooling water having a lower temperature to the injection pipe 131, thereby lowering the temperature of steam generated, and ultimately reducing the occurrence of white smoke.

The cooling water pipe 140 may be omitted when the cooling water inflow pipe 115a is directly connected to the injection nozzle unit 130. [ That is, when the cooling water inlet 115 is formed on the upper part of the housing 110 and the cooling water inflow pipe 115a is directly connected to the spray pipe 131 of the injection nozzle unit 130, the cooling water pipe 140 is omitted do.

The discharge unit 150 includes a motor 151 and a cooling fan 152. The discharge unit 150 is coupled to the upper air outlet 113 at an upper portion of the housing 110 to discharge the exhaust air having passed through the discharge unit 160 to the outside of the housing 110. The discharge unit 150 may be formed as a discharge unit 150 used in a general cooling tower.

The motor 151 is used as a motor for the cooling tower and is coupled to the upper air outlet 113 by a separate support member 151a.

The cooling fan 152 is connected to the motor 151 by a rotating shaft and rotated by the motor 151. The cooling fan 152 discharges the exhaust air to the outside of the housing 110.

The discharge unit 160 includes a collector plate 161, a discharge electrode 162, a support frame 167, and an insulator module 168. The discharge unit 160 is formed in the housing 110 between the discharge nozzle unit 130 and the discharge unit 150. 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 have a required height and width depending on the amount of cooling water flowing into the cooling tower, the amount of saturated water vapor generated, and the amount of mist contained in the 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 according to a restriction of an installation space of the cooling tower and a limitation of an installation space of the discharge unit 160 in the housing 110.

Although not shown in detail, the discharge unit 160 may include separate spray means (not shown) for spraying water or steam to the lower portion of the discharge unit. 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, the water or water vapor injected by the injection means is sprayed at a temperature lower than the temperature of the cooling water, so that it does not generate additional saturated water vapor in contact with the cooling water.

The collector plate 161 and the discharge electrode 162 are electrically insulated from each other by the insulator module 168 and are discharged. The insulator module 168 is formed inside the collector plate 161 at a position where the discharge electrode 162 is formed to reduce the volume or the horizontal area of the discharge unit 160. Therefore, in the white smoke reduction cooling tower 100, the space of the discharge unit 160 for removing white smoke is relatively increased in the space of the same housing 110, thereby increasing the reduction efficiency of white smoke. The white smoke reduction cooling tower 100 has a structure in which the insulator module 168 is formed inside the collector plate 161 so that the flow of the noxious gas compared with the case where the insulator module 168 is located on the side of the collecting passage 161a It is possible to smoothly perform the operation.

The water collecting plate 161 is formed in a plate shape, and has a plurality of water collecting passages 161a having open upper and lower parts and hollow inside and arranged in a planar shape. The water collecting plate 161 is formed such that the horizontal cross-sectional shape of the water collecting passage 161a is rectangular. In addition, the collector plate 161 may have a circular cross-sectional shape. That is, the water collecting plate 161 is formed in a rectangular tube shape and arranged horizontally to form a lattice shape. In addition, the water collecting plate 161 may be formed to have a cylindrical shape. The water collecting plate 161 is positioned inside the housing 110 such that the center axis thereof is vertical. The collecting plate 161 is formed so that the entire horizontal area is the same as the horizontal area inside the housing 110. Therefore, the outer surface of the water collecting plate 161 is fixed to the housing 110 while being in contact with the inner surface of the housing 110. The outer surface of the water collecting plate 161 is separated from the inner surface of the housing 110 and is supported by a separate block (not shown) to be fixed to the housing 110.

The collecting plate 161 is formed with a vertical height L required to collect the charged mist. When the flow rate of the steam passing through the discharge unit 160 is high or the temperature of the process water to be sprayed is high and the moving speed of the mist is high, the vertical height L of the collecting plate 161 is 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 portion of the discharging unit 160.

The space between the collecting plates 161 is spatially directly connected to the upper portion of the jet nozzle unit 130 and the saturated water vapor passing through the jet nozzle unit 130 flows into the collecting plate 161. Therefore, The saturated water vapor passes through the space between the collecting plate 161 and the collecting plate 161 through the injection nozzle unit 130. The water collecting plate 161 allows the mist contained in the water vapor to be charged and collected on the surface.

The water collecting plate 161 is installed in parallel with the flow direction of the saturated water vapor so that the water collecting passage 161a is connected to the upper space of the filler part 120 and saturated water vapor flows into the water collecting plate 161.

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. The collector plate 161 is electrically connected to the housing 110 and 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 electrode 162 is installed so as to extend in the vertical direction to the water collecting passage 161a of the collecting plate 161. 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 vertically in the water collecting passage 161a of the collecting plate 161 and are spaced apart from each other by a predetermined distance in the horizontal direction. The support rods 163 are coupled to a support frame 167 whose upper ends are located at upper portions, and are spaced apart and fixed at uniform intervals. 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 to include a coupling hole 164a and a projection 164b. The discharge plate 164 is formed in a plate or block shape and includes a coupling hole 164a formed at the center and a projection 164b formed at the outer side. The discharge plate 164 is coupled to the support rod 163 in the horizontal direction by inserting the support rod 163 into the coupling hole 164a. A plurality of the discharge plates 164 are coupled to the support rods 163 at a predetermined vertical distance D along the vertical 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 discharging. Therefore, when the mist flows into the space between the collector plate 161 and the discharge plate 164, the degree of spark generation is controlled according to the vertical distance D to effectively collect the mist. The discharge plate 164 is spaced at 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 is preferably formed of hastelloy or stainless steel (STS) having excellent corrosion resistance.

The protrusion 164b protrudes from the outer surface of the discharge plate 164 and may be formed into a triangular shape or a pin shape so that the end portion has a sharp shape. The projections 164b are formed on the outer surface of the discharge plate 164 in regular shapes and intervals. The discharge unit 160 uniformly advances the corona discharge between the collecting plate 161 and the protrusion 164b to collect more mist. The protrusion 164b is formed such that its end portion 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 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. For example, the discharge voltage according to the horizontal distance d may be 20 to 50 kV. The horizontal distance d is proportional to the applied discharge voltage. That is, when the horizontal distance d is increased, the discharge voltage applied between the collector plate 161 and the discharge electrode 162 is also increased. 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 protrusion 164b is formed with a sharp edge so as to have a pin shape, 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 in a ring shape and is inserted into the support bar 161 to be separated from the discharge plates. 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 support frame 165 is formed to include a horizontal frame 166 and a vertical frame 167. The support frame 165 is disposed on the upper portion of the collector plate 161 and supports the discharge electrode 162 to be separated from the collector plate 161 by being coupled with the upper portion of the discharge electrode 162. Here, the horizontal direction means the x direction in Fig. 2, and the vertical direction means the y direction. The support frame 165 is electrically insulated from the collector plate 161 and the housing 110, and may be electrically connected to the anode of the control unit. It is needless to say that the horizontal and vertical frames may be formed by changing the coupling relations.

The horizontal frame 166 is formed in a bar shape and has a longer length than a length between the support bar 162 located at one side and the support bar 162 located at the other side with respect to the horizontal direction. The plurality of horizontal frames 166 are spaced apart from each other by a distance equal to the distance of the support rods 162 along the longitudinal direction. The transverse frame 166 is engaged with the upper end of the support rod 162 to support the support rod 162. The transverse frame 166 is engaged with the upper portion of the fixing rod 164a of the insulator module 168 to support the insulator module 168.

The vertical frame 167 is formed in a bar shape and has a longer length than a length between the horizontal frame 166 located on the front side and the horizontal frame 166 located on the rear side with respect to the vertical direction. The vertical frame 167 is made up of at least two frames and is coupled to both sides of the horizontal frame 166 at both sides of the horizontal frame 166 to support the horizontal frame 166.

The insulator module 168 includes a fixed rod 168a, an upper block 168b, an insulator 168c, a lower block 168d, and a fixed plate 168e. The insulator module 168 is located at a position where the discharge electrode 162 is to be formed on the inner side of the collector plate 161 so that the collector plate 161 and the discharge electrode 162 are electrically insulated. The insulator module 168 is formed at a position of the discharge electrode 162 adjacent to the edge of the housing 110 to stably support the support frame 165. Accordingly, the insulator module 168 reduces the volume and the horizontal area of the discharge part 160. The insulator module 168 reduces the height of the discharge part 160 because a part of the insulator 168c is located inside the water collecting passage 161a of the collecting plate 161. [ The insulator module 168 can appropriately adjust the height of the discharge part 160 inside the housing 110 by controlling a portion located inside the water collecting passage 161a.

Although not shown in detail, the insulator module 168 may be configured such that a gap between the insulator 168c and the collector plate 161 is narrow, and electrical short-circuiting may occur between the collector plate 161 and the insulator 168c The collector plate 161 may be deformed outward so that the horizontal cross-sectional area of the catchment passage 161a where the insulator 168c is located may be deformed or the four adjacent catchment passages 161a may be combined to form a relatively wide space And the insulator 168c may be formed later.

The insulator module 168 may have a fixing rod 168a for fixing the insulator 168c and an upper block 168b or a lower block 168d, which may be omitted or integrally formed if necessary.

The fixing rod 168a is formed in a bar shape and an upper end thereof is coupled to the horizontal frame 166 of the support frame 165. [ The fixing rod 168a is formed to have an appropriate length in consideration of the total height of the insulator module 168. [

The upper block 168b is formed in a block shape, and the upper portion is coupled to the fixing rod 168a. The upper block 168b is formed to have an appropriate area for fixing the insulator 168c according to the area of the insulator 168c. The lower block 168b is coupled to the upper portion of the insulator 168c to have a shape corresponding to the upper shape of the insulator 168c. The upper block 168b may be omitted when the fixing rod 168a is directly coupled to the insulator 168c.

The insulator 168c is formed of a general insulator used for electrical insulation. The insulator 168c is formed to have a circular cross-sectional area, and is formed such that its diameter is smaller than the width and length of the water collecting passage 161a. The insulator 168c is formed at a proper height in consideration of the height of the water collecting passage 161a and the allowable height of the discharge unit 160. [ The upper portion of the insulator 168c is fixedly coupled to the upper block 168b or the fixing rod 168a.

The lower block 168d is formed in a block shape and an upper portion is coupled to the lower portion of the insulator 168c to support the insulator 168c. The lower block 168d is formed to have an appropriate area required for fixing the insulator 168c according to the area of the insulator 168c. In addition, the lower block 168d is formed in a shape corresponding to the lower shape of the insulator 168c because the upper portion is coupled to the lower portion of the insulator 168c.

The fixing plate 168e is formed in a plate shape and has a width or a length corresponding to the width of the water collecting passage 161a. The fixing plate 168e is fixed to the inner surface of the water collecting passage 161a of the collecting plate 161 by welding or bolt at a predetermined height. The fixing plate 168e is coupled to the lower surface of the lower block 168d to support the lower block 168d and the insulator 168c.

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

First, the discharge plate 161 is coupled to and fixed to the housing 110 from the inside of the upper portion of the housing 110 in view of the coupling relation of the discharge unit 160. The discharge electrode 162 is supported by the support frame 165 and inserted into the water collecting passage 161a of the collecting plate 161 so as to be spaced apart from the inner surface of the collecting plate 161. [ A part of the insulator 168c is inserted into the water collecting passage 161a of the collecting plate 161 in the vicinity of the four corners of the insulator module 168 with respect to the plane of the collecting plate 161, And is fixed to and supported by the inner surface of the collecting plate 161 while supporting the discharge tube 168c. The insulator module 168 is coupled to the support frame 165 at its upper portion and supports the support frame 165. Accordingly, the discharge electrode 162 is electrically insulated from and supported by the collector plate 161 by the insulator module 168. Since the insulator module 168 is located inside the collector plate 161, the discharge unit 160 reduces the volume and the horizontal area, and can reduce the total volume and the horizontal area of the white smoke reduction cooling tower.

The motor 151 and the cooling fan 152 of the discharge unit 150 coupled to the upper air outlet 113 from the upper portion of the housing 110, And external air outside the housing 110 flows into the interior of the lower portion of the housing 110 through the lower air inlet 111. The outside air rises while passing through the filler part 120 while rising. The cooling water pipe 140 receives cooling water having a relatively high temperature from the cooling water inflow pipe 115a of the process facility connected to the cooling water inlet 115 and supplies the cooling water to the injection nozzle unit 130. At this time, the cooling water pipe 140 firstly cools the cooling water while passing through the water collecting tank 116 and the filler part 120. The cooling water is injected into the upper part of the filler part 120 while flowing through the injection pipe 131 of the injection nozzle part 130 and the injection nozzle 132. The cooling water drops downward and comes into contact with the outside air rising from the bottom. The cooling water is continuously in contact with the outside air at the upper portion, the inside and the lower portion of the filler portion 120. Accordingly, the outside air comes into contact with the cooling water, and the temperature rises, and the dew point rises and the humidity rises to become saturated water vapor. Meanwhile, the external air introduced through the upper 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 with polarity by the applied discharge voltage, and the size is increased by attraction between the different polarities. The mist is collected in the collector plate 161 or the discharge electrode 162 and flows downward and is collected in the collection vessel 116 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 discharge air is discharged to the outside of the housing 110 by the discharge unit 150. 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. 4 is a horizontal sectional view corresponding to FIG. 3 of the discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.

1A through 4, the white smoke reduction cooling tower according to another embodiment of the present invention includes a housing 110, a filler portion 120, a spray nozzle portion 130, a discharge portion 150, and a discharge portion 260 . The white smoke reduction cooling tower may further include a cooling water 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 100 according to FIGS. 1A to 3 except for the discharge portion 260. Therefore, only the discharging unit 260 will be shown and the discharging unit 260 will be mainly described, without explaining the entire structure of the white smoke reduction cooling tower according to another embodiment of the present invention. The same components as those of the discharging unit 160 of the white smoke reduction cooling tower 100 according to FIGS. 1A to 3 are denoted by the same reference numerals and detailed description thereof will be omitted. Hereinafter, .

The discharge unit 260 includes a collector plate 261, a discharge electrode 162, a support frame 167, and an insulator module 168.

A plurality of plate-like plates having a width and a height are vertically disposed in the housing 110 and are spaced apart from each other in the horizontal direction. The water collection plate 261 is installed parallel to the flow direction of the saturated water vapor. A plurality of the water collecting plates 261 are spaced apart at regular intervals by a separate support member (not shown) and are installed parallel to each other. Accordingly, the water collecting plate 261 is connected to the water collecting passages 261a in the forward and backward directions, and is separated from the water collecting passage 261a in the one side and the other side.

The insulator module 168 is installed at a position where the discharge electrode 162 is to be installed in the four corners of the collector plate 261. The insulator module 168 is installed at the same interval as the discharge electrode 162.

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

FIG. 5 is a horizontal sectional view corresponding to FIG. 3 of the discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.

1A to 3 and 5, the white smoke reduction cooling tower according to another embodiment of the present invention includes a housing 110, a filler portion 120, an injection nozzle portion 130, a discharge portion 150, (360). The white smoke reduction cooling tower may further include a cooling water pipe 140.

The whitening reduction cooling tower according to still another embodiment of the present invention is formed in the same or similar shape as the whitening reduction cooling tower 100 according to FIGS. 1A to 3 except for the discharging unit 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. The same components as those of the discharge unit 160 of the white smoke reduction cooling tower according to FIGS. 1A to 3 are denoted by the same reference numerals and detailed description thereof will be omitted. Hereinafter, Explain.

The discharge unit 360 includes a collector plate 361, a discharge electrode 162, a support frame 167, and an insulator module 168. The discharge unit 360 is formed in the same manner as the discharge unit 160 according to FIGS. 1A to 3 except that the shape of the collecting plate 361 is different. More specifically, the water collecting plate 361 is formed to have a water collecting passage 361a whose upper and lower portions are open and hollow inside. The water collecting plate 361 is formed to have a hexagonal cross-sectional shape of the water collecting passage 361a, that is, the water collecting passage 361 has a hexagonal tube shape. Accordingly, the discharge unit 360 is formed such that the horizontal cross-sectional shape has a honeycomb shape as a whole. The water collecting plate 361 may be formed in a triangular shape in a horizontal cross section and six triangular shapes may be formed to have a hexagonal shape with one of the vertexes of the water collecting plate 361 facing each other. May be formed to have a triangular bar shape. When the discharge unit 360 is formed in a rectangular or cylindrical shape, the space a between the collecting plates may be shielded by a separate member to prevent water vapor from entering the discharge space. In addition, the housing 110 of the white smoke reduction cooling tower may be formed in a circular, hexagonal, or octagonal shape in a horizontal plane. In this case, the inner space of the housing 110 may be more efficiently utilized, Can be arranged.

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

FIG. 6 is a horizontal sectional view corresponding to FIG. 3 of the discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.

1A to 3 and 6, the white smoke reduction cooling tower according to another embodiment of the present invention includes a housing 110, a filler portion 120, an injection nozzle portion 130, a discharge portion 150, The front portion 460 is formed. The white smoke reduction cooling tower may further include a cooling water 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. 1A to 3 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 160 of the white smoke reduction cooling tower according to FIGS. 1A to 3 are denoted by the same reference numerals, and a detailed description thereof will be omitted. Hereinafter, Explain.

The discharge unit 460 includes a collector plate 461, a discharge electrode 162, a support frame 167, and an insulator module 168. The discharge unit 460 is formed in the same manner as the discharge unit 160 according to FIGS. 1A to 3 except that the shape of the collecting plate 461 is different. More specifically, the water collecting plate 461 is formed to have a water collecting passage 461a which is open at the top and bottom and hollow inside. The water collecting plate 461 is formed so that the horizontal cross-sectional shape of the water collecting passage 461a is circular. That is, the water collecting passage 461a is formed to have a cylindrical shape. In the case where the discharge part 460 is formed in a rectangular or cylindrical shape, the void areas a and b between the collector plates 461 are shielded by a separate member (not shown) . In addition, the housing 110 of the white smoke reduction cooling tower may be formed in a circular, hexagonal, or octagonal shape in a horizontal plane. In this case, the inner space of the housing 110 may be more efficiently utilized, Can be arranged.

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

7 is a vertical cross-sectional view corresponding to the discharging portion of FIG. 1A of the discharge unit provided in the white smoke reduction cooling tower according to another embodiment of the present invention.

1A to 3 and 7, the white smoke reduction cooling tower according to another embodiment of the present invention includes a housing 110, a filler portion 120, a spray nozzle portion 130, a discharge portion 150, The front portion 560 is formed. The white smoke reduction cooling tower may further include a cooling water pipe 140.

The white smoke reduction cooling tower according to another embodiment of the present invention is formed in the same or similar portion as the white smoke reduction cooling tower according to FIGS. 1A to 3 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 160 of the white smoke reduction cooling tower according to FIGS. 1A to 3 are denoted by the same reference numerals, and a detailed description thereof will be omitted. Hereinafter, Explain.

The discharge unit 560 includes a collector plate 161, a discharge electrode 562, a support frame 167, and an insulator module 568. The discharge unit 460 is formed in the same manner as the discharge unit 160 according to FIGS. 1A to 3 except that the shape of the collecting plate 461 is different.

The discharge electrode 562 is formed to include a support rod 563 and a discharge plate 164. The support rod 563 is formed in the same manner as the support rod 163 according to Figs. 1A to 3 except that the length thereof is increased in proportion to the position of the insulator module.

The insulator module 568 includes a fixed rod 168a, an upper block 168b, an insulator 168c, a lower block 168d, and a fixed plate 568e. The insulator module 568 is located at a position where the discharge electrode 162 is to be formed on the upper portion of the collecting plate 161 and electrically insulates the collecting plate 161 and the discharge electrode 162 from each other. More specifically, the fixing plate 568e is mounted on the upper portion of the current collecting passage 161a on the upper surface of the collecting plate 161, and the fixing rod 168a, the upper block 168b and the insulator 168c The lower block 168d is located. Therefore, the insulator module 568 supports the support frame 167 while exposing the entire upper portion of the collecting plate 161. The insulator module 568 is mounted on the upper surface of the collecting plate 161 to support the support frame 167, and thus has a side easily installed.

It should be noted that the insulator module 568 according to the embodiment of FIG. 7 may be applied to the embodiment according to FIGS. That is, the insulator module 568 may be applied to a case where the collector plate is formed into a cylindrical shape or a hexagonal tube shape.

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

8 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.

1A through 3 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, 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 whitening reduction cooling tower according to another embodiment of the present invention is formed in the same or similar portion as the whitening reduction cooling tower according to FIG. 1A to FIG. 3 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 discharging unit 160 of the white smoke reduction cooling tower 100 according to FIGS. 1A to 3 are denoted by the same reference numerals and detailed description thereof will be omitted. Hereinafter, .

The discharge unit 660 includes a collector plate 161, a discharge electrode 662, a support frame 167, and an insulator module 168.

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. Meanwhile, the discharge electrode 662 is not located between the collector plate 161 where the insulator module 168 is located. Further, a saturated member (not shown) may be hermetically sealed between the collector plate 161 on which the insulator module 168 is located to prevent saturated air including water vapor from passing therethrough.

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: White smoke reduction cooling tower
110: housing 120: filler part
130: injection nozzle part 140: cooling water pipe
150:
160, 260, 360, 460, 560, 660:

Claims (11)

A housing having a hollow interior and including a lower air inlet through which external air flows and an upper air outlet through which exhaust air is discharged;
A filler portion formed at a position higher than the lower air inlet in the housing to allow the external air to pass therethrough,
An injection nozzle unit located at an upper portion of the filler member in the housing to inject cooling water into the upper portion of the filler member,
A discharger for discharging and collecting the mist contained in the water vapor formed by the contact of the cooling water and the outside air by discharging in the inside of the housing,
And a discharge unit positioned at the upper air discharge port and discharging the discharge air that has passed through the discharge unit ,
The discharge unit
A plurality of water collecting plates formed so that a plurality of water collecting passages are arranged in a plane,
A discharge electrode inserted into the water collecting passage to cause a discharge with the water collecting plate,
A support frame positioned above the collector plate and supporting the discharge electrode so as to be spaced apart from the collector plate,
And an insulator module for supporting the support frame inside the collector plate so that the collector plate and the discharge electrode are electrically insulated from each other. The method according to claim 1,
And a cooling water inlet formed at a lower position than the water level of the cooling water collected in the water collecting tank at a lower portion of the housing, wherein the cooling water inlet is formed at a lower position than the water level of the cooling water collected in the water collecting tank,
Further comprising a cooling water pipe connected to the cooling water inlet at one side in the housing and connected to the injection nozzle unit at the other side to supply cooling water. The method according to claim 1,
The discharge unit
A collecting plate formed so as to be arranged in a lattice shape,
A discharge electrode having a support rod extending vertically in the water collecting passage of the water collecting plate, a discharge hole formed at the center, a discharge hole formed at the center of the discharge hole, ,
A support frame having a plurality of transverse frames coupled to an upper end of the support bar and a vertical frame coupled to both sides of the transverse frame,
Characterized in that it is coupled to the lower portion of the insulator and the insulator is coupled to the fixing rod fixing rods and coupled to the horizontal frame, including a straight module comprises a fixed plate which is fixed at a predetermined height to the inner surface of the water collecting channel of the home abacus Reduction cooling tower. The method of claim 3,
Wherein the water collecting passage is formed in a shape of a triangular barrel, a rectangular barrel, a cylindrical barrel, or a hexagonal barrel having open top and bottom and hollow inside. The method according to claim 1,
The discharge unit
A plurality of collecting plates which are formed in a plate shape and are positioned in a vertical direction inside the housing and are spaced apart from each other in a horizontal direction to form a collecting passage;
And a discharge plate coupled to the support rod through the coupling hole, the discharge electrode having a coupling hole formed at the center thereof and a protrusion formed at the outer side,
A support frame having a plurality of transverse frames coupled to an upper end of the support bar and a vertical frame coupled to both sides of the transverse frame,
And an insulator module including an insulator coupled to the transverse frame, an insulator coupled to the insulator, and a fixing plate coupled to a lower portion of the insulator and fixed at a predetermined height on an inner surface of the sump channel of the sump plate. White smoke reduction cooling tower. The method according to claim 1,
The discharge unit
A water collecting plate having an upper portion and a lower portion opened and a hollow water collecting passage formed to be arranged in a lattice shape;
A discharge electrode having a support rod extending vertically in a water collecting passage of the water collecting plate, a discharge hole formed at a center, a discharge hole formed at an outer side, and a discharge hole coupled to the support rod through the joint hole;
A support frame having a plurality of transverse frames coupled to an upper end of the support bar and a vertical frame coupled to both sides of the transverse frame,
And an insulator module including an insulator coupled to the transverse frame, an insulator coupled to the fixing rod, and a fixing plate coupled to a lower portion of the insulator and positioned on an upper surface of the collecting passage of the collecting plate. . The method according to claim 6,
Wherein the water collecting passage is formed in a shape of a triangular barrel, a rectangular barrel, a cylindrical barrel, or a hexagonal barrel having open top and bottom and hollow inside. 8. A method according to any one of claims 3 to 7
The insulator module includes an upper block coupled to a lower portion of the fixed bar and an upper portion of the insulator,
Further comprising a lower block coupled to a lower portion of the insulator and an upper portion of the fixing plate. The method according to claim 1,
Wherein the housing further comprises an upper air inlet formed between the jet nozzle unit and the discharge unit to allow the outside air to flow therein. The method of any one of claims 3, 5, and 6,
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.

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