KR101200330B1 - Evaporated Water Recovery and Plume Abatement Apparatus from the evaporated water vapor using Condensing Device and Method using the same - Google Patents

Abstract

The present invention can recover by condensing water in saturated steam by using the cold air of the atmosphere from the saturated air discharged to the atmosphere through a stack or cooling tower, and after the condensation, the moisture content and temperature of the air is lowered And it relates to a condensation apparatus to reduce the white smoke by mixing the condensation air heated to a low humidity while passing through the condenser, and to reduce the white smoke and evaporated water recovery using the same. The present invention provides a condensation apparatus for recovering steam by introducing saturated steam discharged from a stack or a duct, the speed reducing unit for reducing the flow rate of the saturated steam discharged from the chimney or the duct; A condenser for introducing air in the air to condense the saturated steam; A first discharge pipe discharging the air in the atmosphere that has passed through the condensation unit to the outside; And a second discharge pipe discharging the saturated water vapor passing through the condensation unit to the outside. It includes, the end of the first discharge pipe is characterized in that connected to the inside of the second discharge pipe.

Description

Evaporated Water Recovery and Plume Abatement Apparatus from the evaporated water vapor using Condensing Device and Method using the same

The present invention can be recovered by condensing saturated water vapor from the saturated air discharged to the atmosphere through a stack or cooling tower using cold air of the atmosphere, and after the condensation, the exhaust air and the water content and the temperature is lowered, The present invention relates to a white lead reduction and evaporated water recovery device and a control method for reducing white lead by mixing condensed air heated to low humidity while passing through a condenser.

In the case of steel plant, in the process of making the intermediate material such as slab, bloom, billet, etc. by passing the casting through a continuous casting machine, when the large amount of water is sprayed on the casting to cast a constant temperature of 600 ℃, steam closes to the casting. It is in a state and is discharged to the atmosphere through the stack (chimney) by the blowing fan. In general, the amount of water disappearing into the atmosphere through the chimneys of continuous casting facilities is 200 ~ 300 tons per day per chimney, and water consumption is very high, accounting for 60% of the total water of the steel mill. The temperature of the saturated steam discharged from the chimney is 60 ~ 80 ℃, and white smoke, which looks like white smoke, occurs as the saturated steam drops below the dew point regardless of the air temperature. White smoke is not a harmful substance as pure water vapor, but it is recognized as a visual pollutant generated in the manufacturing process when viewed outside the factory, causing environmental problems.

By directly cooling water generated in the process of manufacturing plants such as petrochemical, food, semiconductor, electronics, automobile, pulp, steel, and various mechanical devices including air conditioning freezers with water or indirectly by using water-cooled heat exchanger When the heat transferred to the water is cooled by the cooling tower, some of the cooling water is evaporated and released to the atmosphere. In steel plants, 20-30% of the total plant water and in general plants 70-80% of the total plant water are evaporated through the cooling tower and disappeared into the atmosphere. In addition, when saturated air discharged from the cooling tower reaches approximately 20 ° C. or less, water vapor in the saturated air becomes less than the dew point temperature, thereby generating white lead. White lead is recognized as a pollutant generated in the manufacturing process from the outside of the factory. In winter, water condensed from saturated exhaust air freezes around the cooling tower and outside the boundary area of the factory, causing safety accidents.

Production activities are becoming increasingly limited due to lack of water, and apart from research for saving water, research has been conducted for a long time to recover water that is evaporated and released into the atmosphere. Research has been conducted using low temperature water to condense water vapor from saturated steam or saturated air discharged, but it requires a separate freezer to make low temperature water. It is so high that it is not widely applied in practice.

1 is a schematic longitudinal cross-sectional view of a conventional conventional white reduction cooling tower.

Referring to FIG. 1, a typical white reduction cooling tower includes a pair of wet part air suction holes 158 formed under both sides 157 of the cooling tower 150; A pair of dry part air intakes 153 including a heat exchanger 163; An air mixer 161 installed in the air buffer region facing the dry air suction port 153; A fan stack 164 disposed in the air discharge area; A driving unit 151 installed in the fan stack 164; A water distribution pipe 162 connected to the pair of heat exchangers 163 and installed above the wet heat exchanger 156 inside the cooling tower 150; Shatter eliminator 154 disposed above the water distribution pipe 162; And a water collecting tank 159 under the wet heat exchange part 156. Here, the dry part air inlet 153 is provided with a damper 152 for adjusting the amount of air flowing in.

Such a conventional white reduction cooling tower only serves to reduce white smoke, it is not possible to recover the water that is evaporated in the cooling tower disappears into the atmosphere. Furthermore, although there is an air mixer 161 for mixing the low humidity air passing through the dry part and the saturated air passing through the wet part, these two air are not mixed well at the center of the cooling tower, and the effect of reducing the white smoke is not great. There is a problem that the cost is high, such as the cost of the heat exchanger reaches 200-300% of the cost of a typical general cooling tower.

Conventional techniques for recovering water from a stack and reducing white smoke are a method of directly spraying cold water onto saturated steam to condense the water vapor and then passing through a desert filter to remove fine water particles. The method of heating saturated steam to make it unsaturated, releasing it into the atmosphere, and reducing white smoke has been carried out individually. When condensing steam by spraying cold water with hot saturated steam, the sprayed cold water rises close to the temperature of saturated steam, so the sprayed water must be re-cooled by using a freezer. The heater has a problem in practical application because the electric consumption is high.

The present invention is to solve the above-described problems, for example, by heating the saturated air discharged from the stack of the factory or the saturated air discharged from the cooling tower with the air flowing from the air, a separate heating device or heat exchanger It is an object of the present invention to provide a white lead reduction and evaporated water recovery device using a condensation device for removing water vapor contained in saturated steam or saturated air by condensation without using the same.

In addition, during the condensation process, saturated steam or saturated air having a reduced water content and temperature is mixed with air introduced from the air whose temperature is increased by heat exchange with the saturated steam or saturated air and discharged in a state of lowering relative humidity. It is an object of the present invention to provide a white lead reduction and evaporated water recovery apparatus and a control method thereof to reduce the occurrence of.

In addition, by allowing the saturated steam discharged from the stack of the plant or the saturated air discharged from the cooling tower to exchange heat with the air flowing from the atmosphere, the vaporized water to recover the saturated steam or the steam contained in the saturated air by the condensation process. It is an object to provide a recovery method and apparatus.

The present invention, in order to achieve the above object, the white lead reduction and evaporated water recovery apparatus according to the first aspect of the present invention, condensed saturated steam discharged from the stack or duct to recover water and reduce white lead and An evaporated water recovery apparatus, comprising: a deceleration unit for reducing a flow rate of saturated steam discharged from the stack or the duct; And a plurality of condensation tubes into which atmospheric air flows and flows therein, and the saturated steam passing through the deceleration section flows to the outer surfaces of the condensation tubes to condense high temperature saturated steam and condensation outside the condensation tubes. A condensation unit for heat-exchanging low-temperature atmospheric air inside the tube; A first discharge pipe discharging air of the atmosphere inside the condensation tube heated by the latent condensation of saturated steam outside the condensation tube during a heat exchange process in the condensation unit; A second discharge pipe discharging saturated steam which discharges latent heat of condensation into air of the atmosphere inside the condensation tube during a heat exchange process in the condensation unit; And a mixing unit for mixing the air of the air discharged through the first discharge pipe and the saturated steam discharged through the second discharge pipe.

The second aspect of the present invention, the fan is installed on the top of the cooling tower, a pair of wet air inlet, the cooling water injection unit, the cooling water injection unit disposed in the lower portion of both sides of the cooling tower to exchange heat with the cooling water Filler, a pair of dry air inlets arranged on the top of the cooling tower, an external damper that controls the amount of air flowing into the dry air inlet, an internal damper that moves upward through the filler to flow into the dry section Damper; A condenser for heat exchange of saturated air passing through the air and air in the air introduced through the dry air inlet; And a mixing unit in which the condenser condensed in the condenser and the humidity is lowered and the air passing through the condenser and the air of which the temperature rises are mixed with each other. A saturated air flow path through which air flows and a condensation air flow path through which the outside air introduced through the dry air intake port flows. It relates to a reduction in white lead and evaporated water recovery cooling tower.

The saturated air flow path and the condensation air flow path of the condenser are formed of a sheet of thin material, and a plurality of concave button fasteners and a plurality of convex button fasteners corresponding thereto are formed at edges of the sheet, and the opposite sheets After applying the adhesive to the junction of the edge of the field, the plurality of concave button fastener and the plurality of convex button fasteners corresponding to the saturated air flow path and the condensation air flow path can be formed.

In the whitening reduction and evaporated water recovery cooling tower according to the second aspect of the present invention, when the temperature of the atmosphere is 28 ° C. or more, the external damper is closed, the internal damper is opened, and the temperature is 24 to 28 ° C. The external damper and the internal damper are opened. If the ambient temperature is less than 24 ° C., the external damper is opened and the internal damper is closed.

A third aspect of the present invention includes a wetted portion in the lower portion and a dry portion in the upper portion, and the whitening reduction and evaporated water recovery cooling tower which condenses saturated air to recover water vapor and reduces white smoke, wherein the saturated air inside the cooling tower. A first fan for introducing the; A hermetic or open heat exchanger for reducing the temperature of the saturated air by heat exchange with cooling water; It consists of a condensation air flow passage through which the air of the air flowing through the air inlet of the dry portion passes, and a saturated air flow passage through the saturated air passing through the heat exchange unit, and the condensation air flow passage and the saturated air flow passage are disposed adjacent to each other. A condenser for exchanging heat between atmospheric air in the condensation air flow path and saturated air in the saturated air flow path; A second fan for introducing atmospheric air into the condenser flow path of the condenser; An air mixer disposed above the condenser; And an induction pipe for discharging the air of the air discharged from the condenser to the air mixer, wherein the temperature is increased while passing through the saturated air passage of the condenser and the saturated air of which the humidity is low and the condensation air passage of the condenser. It relates to a white reduction cooling tower in which the air of the atmosphere is raised and discharged through the induction pipe is mixed in the air mixer.

The air mixer may include a plurality of mixing tubes, and the mixing tube may include an outlet.

According to a fourth aspect of the present invention, in the method of recovering white lead and evaporated water in which saturated steam is heat-exchanged with air in the air, condensing and recovering steam contained in the saturated steam to reduce white lead, discharge from stack or duct. A first heat exchange step of heat-exchanging saturated water vapor with cooling water; Passing atmospheric air into the condenser tube of the condenser; By passing the saturated water vapor passed through the first heat exchange step outside the condenser tube and exchanging heat with atmospheric air passing into the condenser tube of the condenser, the high temperature saturated steam outside the condenser tube and the low temperature atmosphere inside the condenser tube A second heat exchange step in which the air heat exchanges; And a third heat exchange step of mixing and heat-exchanging the atmospheric air passing through the condenser tube of the condenser and the saturated steam passing through the outside of the condenser tube.

According to the present invention, by condensing and removing saturated steam or steam contained in saturated air by heat exchange between saturated steam or saturated air and air in the atmosphere, white smoke is reduced by reducing the amount of steam discharged from the stack or cooling tower to the outside. Has an effect.

In addition, the white smoke is reduced by mixing the air of which the temperature is increased by heat exchange with water vapor having reduced water content and saturated water vapor and then lowering the humidity.

In addition, it has the effect of recycling after collecting the water removed by condensation in saturated steam or saturated air monitoring.

1 is a schematic longitudinal sectional view of a conventional white reduction cooling tower.
Figure 2a is a cross-sectional view showing the configuration of the white lead reduction and evaporated water recovery apparatus according to the first embodiment of the present invention.
Figure 2b is a view showing the configuration of the condensation tube used in the condensation apparatus of the white lead reduction and evaporated water recovery apparatus according to the first embodiment of the present invention.
3 is a diagram showing the temperature and absolute humidity of saturated steam or saturated air passing through the condensation apparatus in the apparatus for reducing white smoke and evaporated water according to the present invention.
4 is a view showing the configuration of a cooling tower equipped with white lead reduction and evaporated water recovery apparatus according to a second embodiment of the present invention.
5 is a perspective view showing the condenser used in the apparatus for reducing white smoke and evaporated water according to the second embodiment of the present invention.
FIG. 6 is a view showing an inner surface configuration of a condensation air flow path of a condenser used in a white lead reduction and evaporation water recovery device according to a second embodiment of the present invention.
7 is a diagram showing the results obtained through the empirical test by applying the white lead reduction and evaporated water recovery apparatus according to the present invention to the induction ventilation cooling tower.
8 is a diagram showing the percentage of the saturated air condensed by the air temperature.
9 is a view showing the configuration of a cooling tower equipped with a white lead reduction and evaporated water recovery apparatus according to a third embodiment of the present invention.
10 is a view showing the configuration of a cooling tower equipped with white lead reduction and evaporated water recovery apparatus according to a fourth embodiment of the present invention.
11 is a view showing the configuration of a water collector used in a cooling tower equipped with white lead reduction and evaporated water recovery apparatus according to the third and fourth embodiments of the present invention.
12 is a perspective view showing the configuration of the air mixer used in the third and fourth embodiments of the present invention.
13 is a cross-sectional view of the condenser of FIG. 5.
14 is a view showing a bonding process of the condensation sheet of the condenser of FIG.
FIG. 15 is a view illustrating a joint and a slope of the condensation sheet of the condenser of FIG. 5.

The objects, features and advantages of the present invention will be more readily understood by reference to the accompanying drawings and the following detailed description.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the configuration of the embodiment of the present invention and its effects.

First Embodiment

2A is a cross-sectional view showing the configuration of the white lead reduction and evaporated water recovery apparatus 10 according to the first embodiment of the present invention.

As shown in FIG. 2A, the apparatus for reducing white smoke and evaporated water according to the first exemplary embodiment of the present invention may include a deceleration part 13, a condensation part 21, and a speed increasing part 16. Can be.

In the case of the stack 11, the flow rate of saturated steam is usually very high, such as 20-30 m / s. Therefore, when the condenser is installed at the flow rate, the saturated water vapor passes through the condenser, causing about 20-50 mmAq of air pressure loss. The problem occurs in the fan, so it is necessary to reduce the flow rate as much as possible, and the deceleration part is necessary because the temperature of the condensed air can be increased by increasing the contact time of the saturated steam and the condenser tube.

Therefore, the saturated water vapor having a high flow rate of 20-30 m / s discharged from the stack 11 is introduced into the white smoke reduction and evaporation water recovery system 10 and passed through the deceleration section 13 to 2-7.5 m / s. The flow rate is lowered and then flowed to the outer surface of the condensation tube 22 of the condenser 21, and on the other hand, for example, an axial fan 18 is used to draw atmospheric air into the condenser 21. By forcibly flowing into the condensation tube 22, the high temperature saturated steam outside the condensation tube 22 and the low-temperature atmospheric air inside the condensation tube 22 allows heat exchange. In this heat exchange process, the saturated water vapor outside the condensation pipe 22 is condensed, dropped by gravity, collected in the condensation tank 25, and sent to the water collecting device through the drain hole 24 for reuse. One saturated water vapor flows to the second discharge pipe 17 through the speed increasing part 16 while the water content and the temperature are lowered, and is heated by the latent heat of condensation of the saturated water vapor during the heat exchange process, so that the first discharge pipe 19 is reduced. By mixing with the atmospheric air discharged to the lower, the relative humidity of the exhaust air is lowered to release to the atmosphere through the discharge port (c) does not form white smoke. Here, the first discharge pipe 19 is connected to the second discharge pipe 17 at an angle of incidence of 30 to 40 °, thereby discharging the air discharged to the first discharge pipe 19 and the second discharge pipe 17. Atmospheric air can be mixed well inside the duct without a separate mixing device.

 The reduction unit 13 in the white lead reduction and evaporated water recovery device 10 reduces the saturated water vapor having a high flow rate of 20-30 m / s to 2-7.5 m / s emitted from a stack (chimney) of a factory. It has a function, the shape of the deceleration portion 13, for example, is configured in a cylindrical shape, so that the cross-sectional area is gradually increased from the inlet through which the saturated steam is introduced to the outlet through which the saturated steam is discharged, the ball at the end Has a trapezoidal cross-sectional structure as a whole (see FIG. 2A).

FIG. 2B is a diagram showing the internal configuration of the air-cooled condensing unit 21 for condensing saturated steam discharged from the stack using atmospheric air, and arranged horizontally across the condensation tube 22 made of metal pipes. Air flows into the interior 26 of the metal pipe 22 and saturated water vapor flows into the space 23 between the condensation tubes 22. In this way, the low-temperature atmospheric air inside the condensation tube 22 and the high temperature saturated steam outside the wall of the condensation tube 22 exchange heat so that the saturated water vapor condenses on the outer surface of the wall of the condensation tube 22. In order to effectively condense on the outer surface of the condensation tube 22, it is preferable that the flow rate of saturated water vapor passing through the space 23 between the condensation tubes 22 is 2-7.5 m / s. Most preferably, the flow rate of saturated steam is 6 m / s. For example, the flow rate of saturated steam in the space 23 between the condensation tubes 22 is determined by determining the length of the condensation tube, the pitch of the condensation tubes, the pitch of the condensation tubes, and the number of condensation tubes per row. Can be set to m / s. In addition, it is preferable to determine the diameter of the condensation tube 22 and the number of condensation tubes so that the flow rate of atmospheric air flowing through the inside 26 of the condensation tube 22 becomes 10-15 m / s. In addition, the thinner the thickness of the condensation tube 22, the greater the thermal conductivity, so that the condensation amount of saturated water vapor is increased, the thickness of the condensation tube 22 is preferably 1.2 to 2.5 mm, the condensation tube is 50 to 150A copper tube or aluminum alloy steel This is preferred.

The speed increaser 16 in the white lead reduction and evaporated water recovery device 10 increases the flow rate of saturated water vapor passing through the condensation unit 21, and increases the inlet cross-sectional area of the speed increaser 16 larger than the outlet cross-sectional area. While water vapor flows toward the outlet, the cross-sectional area is reduced to increase the flow rate. The longitudinal cross-sectional shape of the speed increasing unit 16 may be formed in a cross-sectional structure of an inverted trapezoid.

Next, the operation of the apparatus for reducing white smoke and evaporated water according to the first embodiment will be described.

When the white lead reduction and evaporated water recovery apparatus 10 according to the first embodiment is operated, saturated water vapor discharged from the stack is introduced into the condenser 21 through the deceleration unit 13, and the introduced saturated water vapor is introduced into the condensation tube. Passes through the space 23 formed between the (22). On the other hand, when the white lead reduction and the evaporated water recovery device 10 is operated, the fan 18 is operated to introduce air in the atmosphere into the interior 26 of the condensation tube 22. The air introduced into the inside 26 of the condensation tube 22 condenses the saturated water vapor by heat exchange with the saturated water vapor, and then is discharged through the first discharge pipe 19. The air discharged to the first discharge pipe 19 is heated by the latent heat of condensation of saturated steam in the condensation pipe 22, and the saturation discharged to the second water discharge pipe 17 passing through the condensation pipes 22. Water vapor is in a state where humidity and temperature are lowered.

The first discharge pipe 19 is connected to the inside of the second discharge pipe 17, so that the atmospheric air discharged through the first discharge pipe 19 is mixed with the air discharged through the second discharge pipe 17, the saturated steam When the relative humidity is further lowered and saturated steam having the lowered relative humidity is released to the atmosphere, the generation of white smoke may be reduced.

3 is a, of the saturated water vapor passing through the white lead reduction and evaporated water recovery device 10 of FIG. 2a when the white lead reduction and evaporated water recovery device according to the first embodiment of the present invention is applied to a stack (chimney), It is a temperature-absolute humidity plot (tx plot) showing the temperature and absolute humidity of the air at points a ', b, b' and c.

Point a on the diagram indicates the temperature and absolute humidity of the saturated steam discharged from the stack, and point a 'indicates that some of the saturated steam is condensed by the condensation air after passing through the condensation unit 21 and the latent heat of condensation is released. The temperature and absolute humidity are shown, and the line a-a 'shows the change in temperature and absolute humidity of saturated steam.

Point b on the diagram represents the temperature and absolute humidity of the atmospheric air, b 'represents the temperature of the heated air receives the latent heat of condensation from saturated steam as the atmospheric air passes through the condenser 21, Since air passes through the condenser 21 and there is no change in moisture) line b-b 'represents only the temperature of the atmospheric air.

Point c on the diagram shows the temperature and absolute humidity of the mixed air at point c of FIG. 2A where two air in different states meet and mix. Line cb shows that the air discharged from the second discharge pipe (17) meets and dilutes the air discharged from the first discharge pipe (19) to return to the state b of the atmospheric air state. If line cb does not exceed the air saturation curve, it indicates that white smoke does not occur since water vapor in the exhaust air is not condensed.

Second Embodiment

Figure 4 is a view showing the configuration of the induction vent type cooling tower 30 is installed with a white lead reduction and evaporated water recovery apparatus according to a second embodiment of the present invention.

Referring to FIG. 4, the cooling tower 30 in which the white lead reduction and the evaporated water recovery device according to the second embodiment of the present invention is installed is a fan 31 installed at the upper end of the cooling tower, and a pair disposed at both lower sides of the cooling tower. Air volume of the air flowing into the wet air inlet 34, the filler 33, the cooling water injection pipe 40, a pair of dry air inlet 41, the dry air inlet 41 disposed on the upper portion of the cooling tower. External air damper (43) for controlling the air, through the air inlet of the dry portion 41, the air flowing in the air through the air-cooled condenser 50, and the filling material 33 passing through the inside and the flow to the dry portion It may include an internal damper 37 for adjusting the amount of saturated air to be. In addition, the cooling tower 30 preferably includes a scattering eliminator 32, an atmospheric temperature sensor (not shown). Although the fan 31 uses the axial flow type of the fan 31, other types of fans may be used according to the needs of the user.

In the cooling tower 30 in which the white lead reduction and the evaporated water recovery device is installed according to the second embodiment of the present invention, the air flow of the air is operated by operating the axial fan 31 mounted on the upper portion of the cooling tower 30. ) Is forced through (suction) the inside of the cooling tower 30 through the wet part air inlet 34 of the lower portion, and through the plurality of injection nozzles 39 mounted on the cooling water injection pipe 40, preferably Is injected into the filler 33, which is a heat transfer medium, with particles of the size of 3-5 mm. The cooling water flowing downward through the filler 33 by gravity is directly contacted with the air of the air flowing upward through the filler 33, and part of the cooling water is evaporated to release the latent heat of evaporation. Cooling water is cooled by sensible heat exchange due to the temperature difference, and heat removed by evaporation and sensible heat exchange from the cooling water is transferred to the atmospheric air forcibly flowing into the cooling tower, and the air passing through the filling material 33 is saturated in the process. The state is reached. The scattering eliminator 32 mounted on the top of the filler 33 reduces the discharge of the cooling water passing through the filler 33 into the cooling tower forcibly riding on the rising air flow.

An air-cooled condenser 50 is mounted on top of the fugitive remover 32 to condense water vapor in saturated air passing through the filler 33 and reduce white smoke. An external damper 43 for adjusting the air amount of the air introduced through the dry air inlet 41 is disposed in front of the condenser 50, and the degree of opening and closing is determined according to the air temperature of the air. In addition, the internal damper 37 is mounted at the lower end of the condenser 50 to adjust the amount of saturated air flowing through the filler 33 into the condenser 50.

The hot saturated air (a) passing through the filling material (33) is condensed by the low-temperature atmospheric air while passing through the condenser (50), and then condensed into an air of unsaturated state (a ') having reduced water content and temperature. The air 50 of the air passing through the condenser 50 leaves the condenser 50 in a state (b ′) heated by the latent condensation heat released while the saturated air condenses. These two air is mixed in the air buffer space 44 of the cooling tower 30 is released to the atmosphere in a relatively low relative humidity (c), so that water vapor in the exhaust air does not fall below the dew point, so that white smoke does not occur. .

Next, the configuration of the air-cooled condenser 50 will be described in more detail.

Referring to FIG. 5, the condenser 50 used in the apparatus for reducing white smoke and evaporated water according to the second embodiment of the present invention condenses saturated air discharged from the filling material 33 of the cooling tower 30 into atmospheric air. As a function to perform, it includes a condensed air (air air) flow path 54 and a saturated air flow path (51). The saturated air flow passage 51 flows in saturated air introduced through the filler 33, and the condensation air flow passage 54 flows in atmospheric air introduced through the dry air suction port 41. Saturated air is condensed on the inner surface of the saturated air passage 51 by the temperature difference between atmospheric air and saturated air passing through the two flow passages 51 and 54, and water falls by gravity to the scattering eliminator 32. Falling or collecting in the water collecting passage 121 of the water collector 120 and then reused through the drain 122 located at the bottom of the water collecting tank 123 or discharged to the water tank 38 of the cooling tower (see Figs. 4 and 10). .

The saturated air passage 51 is vertically disposed to facilitate the inflow of saturated air passing through the internal damper 37, and the condensed air passage 54 is horizontally disposed so that the dry air suction port 43 is provided. It is preferable to facilitate the inflow of the outside air supplied through (that is, the saturated air flow path 51 and the condensation air flow path 54 are approximately perpendicular to each other).

The saturated air flow path 51 and the condensation air flow path 54 are each formed to have a predetermined width, length, and height, and the width of the saturated air flow path 51 is the length of the condensation air flow path 54 and the saturated air flow path 51. The length of) is preferably equal to the width of the condensation air flow path (54). In addition, as shown in FIG. 5, the outer wall of the saturated air flow passage 51 is disposed to contact the outer wall of the condensation air flow passage 54, whereby the saturated air flowing through the saturated air flow passage 51 and the condensation air flow passage 54. Heat exchange of the outside air flowing through is made. In order to efficiently exchange heat, the plurality of saturated air flow passages 51 and the condensation air flow passages 54 are preferably alternately arranged.

The saturated air flow path 51 and the condensation air flow path 54 of the condenser 50 of FIG. 5 are formed by, for example, forming a thin sheet of vinyl chloride resin to face each other, and then the top and bottom of the sheet of the condenser 50. Pressing the assembly button 56 formed at regular intervals on the flat surface of the edge to form a plurality of tanks (sets) of the condensed air flow path (54), these are formed at regular intervals on the edges of both sides (53) The assembly button 56 is continuously pressed to create a saturated air flow passage 51. The assembly button 56 is, for example, a convex button fastener (female slot) 56 having a width of 7 to 9 mm and a length of 200 mm and a concave button type having a width of 8 to 10 mm and a length of 200 mm corresponding thereto. It may be made of a male slot 56. When bonding the condenser sheet of the condenser 50, as shown in Figure 14, first by applying an adhesive to the upper and lower edge joining surfaces of the two condensation sheet (see (a) of Figure 14), both condensation sheet Convex button fasteners 56 formed at the edges of the concave button fasteners 56 and the corresponding concave button fasteners 56 are aligned and pressed to form a condensed air flow path or a saturated air flow path (see FIG. 14B). . Two condensed air flow paths or two saturated air flow paths combined with two condensate sheets are first applied with adhesive on the joint surface in the manner described above, and then the convex button fasteners and the concave button fasteners are fitted. When pressed by pressing can be assembled as shown in (c) of FIG. When the condenser sheet is continuously joined in this manner, a plurality of condensed air passages 54 and a plurality of saturated air passages 51 can be formed. When the condenser sheet is joined in the above manner, the convex button fastener and the concave button fastener are self-fixed, so that there is no need to fix the joint surface for a predetermined time after applying the adhesive.

The projections 59 in both the vertical and horizontal directions of the vacuum-formed condenser 50 sheet with a minimum of air resistance while each flow path maintains a constant interval (eg, 30-60 mm) have a constant interval (eg For example, it is formed to about 75 mm), so that the water condensed on the wall of the saturated air flow path 51 can flow down quickly by gravity, and the strength and surface area of the condenser 50 is increased. For example, at the bottom of the sheet of the condenser 50, a wave-shaped protrusion 58 having a height of 3-5 mm is provided, for example, at intervals of 10-20 mm. In this case, the bonding of the sheet may be made by adhesion, and in addition to the above, it is not limited in a specific manner and may be made in various ways by the manufacturer.

Since the sheet used for the production of the saturated air flow path 51 and the condensation air flow path 54 has a thinner thickness, the heat transfer amount increases and the condensation amount of saturated air increases, so that the sheet thickness is as thin as possible. The thickness of the sheet is preferably 0.3 to 0.4 mm to prevent deformation due to the weight, air flow rate and saturated steam.

On the other hand, in order to effectively condense the saturated air on the surface of the saturated air passage 51 of the condenser 50, the flow rate of the air passing through the saturated air passage 54 and the condensation air passage 51 is 2-7.5 m / It is preferable to make it s. Most preferably, the air flow rate is 2-6 m / s.

The air pressure loss in the flow path is calculated by the following equation.

Air pressure loss in the flow path = K * ρm * V ² * D / (2 * g)

Where K is the air pressure loss coefficient, ρm is the average density of air (kg / m ² ), V is the average flow velocity of air (m / s), g is the gravitational acceleration (m / s ² ).

As can be seen from the above equation, since the pressure loss in the flow path is proportional to the square of the velocity of air, 7.5 m / s or less is appropriate to reduce the pressure loss of the fluid. Most preferably, it is 6 m / s or less (the reason for maintaining the flow velocity of saturated air passing through the condenser at 7.5 m / s or less is the same in the case of the first embodiment). In this way, the flow rate of the saturated air to less than 7.5m / s to reduce the flow resistance of the air passing through the saturated air flow path can be prevented from requiring additional power.

In addition, as shown in Table 1 below, the condensation rate of saturated air on the surface of the condensation tube is low when the flow rate is high. As a result, the fan speed was increased to increase the flow rate of saturated air (i.e., to increase the flow velocity), but the air pressure loss rapidly increased, and the amount of air passing through the flow path did not increase significantly.

(In the experiment shown in Table 1 below, the temperature of the saturation air discharged from the cooling tower is 8.5 ° C and the temperature of the saturated air is 32.5 ° C. (The evaporation rate is maintained at 1.2%.) The amount of condensation divided by the amount of water evaporated from the cooling tower was converted to the condensation rate while changing the flow rate of the saturated air passing through.)

Saturated Air Flow Rate 5 m / s 7.5 m / s 10 m / s 15 m / s Condensation rate 32.7% 32.1% 18.6% 12.25

 On the other hand, when the velocity of the fluid is 2 m / s or less, the heat exchange efficiency in the condenser is lowered.

In addition, the inlet and outlet of the saturated air passage 51 and the condensed air passage 54 is preferably formed with guiders 55 to guide inflow and outflow of saturated air and air to both sides. It is preferable that the formation angle of the guider 55 is 50-80 degrees with respect to the flow direction of air. The guiders 55 on both sides may be formed to face each other in a V-shape. In addition, reinforcing wrinkles 57 may be formed on the guider 55 to reinforce the strength of the guider 55 (see FIG. 15). The reinforcing pleats may be arranged, for example, with a spacing of 8-10 mm wide at intervals of 30-50 mm.

Next, the operation of the apparatus for reducing white smoke and evaporated water according to the second embodiment will be described.

When the fan 31 is operated in the cooling tower 30 having the reduced white smoke and the evaporated water recovery device according to the second embodiment, the atmospheric air introduced into the cooling tower 30 through the wet air inlet 34 is filled with a filler ( 33), it becomes saturated air, and this saturated air passes through the saturated air flow passage 51 of the air-cooled condenser 50. The air passing through the saturated air flow passage 51 is introduced through the dry air suction port 43 to exchange heat with the air in the air passing through the condensation air flow passage 54 of the condenser 50, thereby allowing the air to flow into the saturated air flow passage 51. Saturated air is condensed on the surface of the saturated air flow path (51). At this time, in order for the condensation rate of saturated air to become optimal, it is preferable to set the flow velocity of the air which passes through the saturated air flow path 51 and the condensation air flow path 54 to 2-7.5 m / s. Most preferably, the air flow rate is set at 6 m / s or less. By this process, the temperature and humidity of saturated air can be reduced without a separate heating device or heat exchanger. When the condensation amount of water in the condensation process in the condenser 50 is increased, the water drops to the bottom and falls to the scattering remover 32 or collects in the water collecting passage 121 of the water collecting unit 120 and then at the bottom of the water collecting tank 123. Can be recycled through a drain 122. Alternatively, the cooling tower may be discharged to the tank 38.

In the above process, the saturated air passing through the saturated air flow passage 51 is discharged from the condenser 50 in an unsaturated state (a ') in which water content and temperature are reduced by condensation, and passes through the condensation air flow passage 54. The air of one atmosphere is discharged from the condenser 50 in a heated state (b ') by the latent heat of condensation discharged from saturated air, and these two types of air are mixed in the air mixing space 44 to significantly lower the relative humidity. The discharged to the outside of the cooling tower 30 through the fan 31 in the advanced state (c). At this time, the discharged air is low in relative humidity, and the temperature does not fall below the dew point, so that white smoke does not occur.

FIG. 7 is a diagram showing the results obtained through an empirical experiment by applying the white lead reduction and evaporated water recovery device according to the second embodiment of the present invention to an induction ventilation cooling tower 30, and the white lead reduction and evaporated water recovery of FIG. It is a temperature-absolute humidity plot (tx plot) showing the temperature and absolute humidity of air at points a, a ', b, b' and c in the cooling tower 30 in which the apparatus is installed.

B in the diagram represents the temperature and absolute humidity of the air flowing into the cooling tower and the condenser 50 from the cooling tower wet air inlet 34 and the dry air intake 41, and a denotes the discharge from the cooling tower filler 33. The temperature and absolute humidity of the saturated air are shown, and the line ba represents the temperature and absolute humidity change of the air passing through the filler 33.

A 'in the diagram represents the temperature and absolute humidity in which a part of the saturated air is condensed by the atmospheric air after passing through the condenser 50 and the latent heat of condensation is released. Line a-a 'shows the temperature and absolute humidity change of saturated air.

B 'in the diagram shows the temperature of the heated air by receiving the latent heat of condensation from saturated air while the atmospheric air passes through the condenser 50, and there is no change in moisture while passing through the condenser 50. 'Represents only the temperature change of the condensed air.

The c on the diagram represents the temperature and absolute humidity in the state where two air in different states are mixed together. Line c-b shows that the mixed air leaving the cooling tower 30 meets the atmospheric air and is diluted to return to the b state indicating the atmospheric air state. If line c-b does not exceed the air saturation curve, it means that water vapor in the exhaust air is not condensed, so no white smoke is produced.

Next, an operation mode for each atmospheric temperature of the cooling tower 30 in which the white lead reduction and the evaporated water recovery device according to the second embodiment of the present invention is installed will be described.

In the apparatus according to the second embodiment, a temperature sensor (not shown) for measuring the temperature of the atmosphere for the operation of the external damper 43 and the internal damper 37 is preferably provided.

FIG. 8 is a graph showing the percentage of saturated air condensed at each atmospheric temperature, and the diagram of the diagram illustrates the condensation rate expected through an empirical experiment.

As shown in FIG. 8, when using the cooling tower 30 according to the second embodiment, when the atmospheric temperature is a high temperature of 28 ° C. or more, the external damper 43 at the front of the condenser is completely closed and the internal damper 37 is closed. The cooling tower must be operated in the fully opened state to cool down to the temperature required by the cooling tower. When the air temperature is in the range of 24 to 28 ° C., when the cooling tower is operated while the external damper 43 and the internal damper 37 are completely open, saturated air can be condensed by about 5 to 10%. In addition, when the air temperature is less than 24 ° C., the external damper 43 is completely opened and the internal damper 37 is closed to allow all of the saturated air to pass through the condenser, thereby condensing the saturated air and reducing white smoke. The condensation amount of the cooling tower 30 in which the white lead reduction and the evaporated water recovery device according to the second embodiment is installed increases as the temperature of the air is low, and the annual average condensation rate is about 20-30% of the evaporation amount.

Third Embodiment

9 is a view showing the configuration of a pressurized air blowing type hermetic cooling tower 60 according to a third embodiment of the present invention. The pressurized air blowing type closed cooling tower 60 uses the tube bundle 63 as a heat transfer medium, and is applied when the cooling water is not directly contacted with air flowing into the cooling tower.

Referring to FIG. 9, the cooling tower according to the third embodiment of the present invention includes a first fan 64 that is an axial or centrifugal fan at the bottom, a second fan 31 disposed at the dry air inlet, and a tube bundle 63. ), An injection nozzle 39, a condenser 50a, an induction pipe 61, and an air mixer 90.

In the cooling tower 60 in which the white lead reduction and the evaporated water recovery device according to the third embodiment is installed, the cooling tower 60 is operated through the air inlet 65 by operating the axial flow type or centrifugal fan 64 mounted below. Forced blow inside. In addition, the spray bundle or sprayed coolant is sprayed onto the tube bundle 63, which is a heat transfer medium, by spraying particles having a size of Φ 3-5 mm through the spray nozzle 39 mounted on the water spray pipe 40. The heat of the flowing cooling water is indirectly transferred to the sprayed water, and then the heat transferred to the sprayed water is directly introduced into the cooling tower and directly contacted with the air in the air flowing upward through the tube bundle 63, whereby the sprayed water or the cooling water is partially The evaporation takes away the latent heat of evaporation and cools the cooling water by sensible heat exchange due to the temperature difference of the air. Heat removed from the cooling water is transferred to the air forcibly flowing into the cooling tower 60, in which the air is saturated.

In the press-fitting airtight cooling tower 60 of the third embodiment, unlike the induction draft cooling tower 30 of the second embodiment, the second fan 31 is a separate axial flow fan to supply atmospheric air to the condenser 50a. One end of this condenser 50a is provided outside.

In the third embodiment, the induction pipe 61 guides the unsaturated air discharged from the saturated air flow passage 51 of the condenser 50a to the mixing pipe 91 of the air mixer 90 described later. The inlet of the induction pipe 61 is preferably formed to a size that can cover the whole of the saturated air flow path of the condenser (50a). In addition, the outlet of the induction pipe 61 is preferably formed to a size that can cover all of the mixing pipe 91 of the air mixer 90 to be described later. The condenser 50a in the third embodiment may be manufactured in the same manner as the manufacturing method of the condenser 50 in the second embodiment.

Referring to FIG. 11, the air mixer 90 includes a mixing tube 91 and an outlet 92. Mixing tube 91 is formed in a predetermined length and diameter, it is preferable that a plurality are arranged in parallel to each other at regular intervals. The upper portion of the mixing tube 91 is opened to form the discharge portion 92.

In addition, the scattering remover 32 is preferably installed in the cooling tower of the third embodiment. In addition, the cooling tower sump 38 is installed in the inner lower portion of the cooling tower 60, when the cooling water dispersed in the tube bundle 63 is used for cooling the tube bundle 63, it can collect it.

FIG. 10 is a view showing the configuration of the water collector 120 used in the cooling tower 60 according to the third embodiment of the present invention, and FIG. 11 is a view showing the configuration of the air mixer 90 used in the third embodiment. Perspective view. Referring to FIG. 10, the water collector 120 may be installed below the condenser 50a to collect water generated by the condensation of saturated air in the condenser 50a and falling. The water collector 120 may be formed in a V-shaped cross-sectional structure and may have a plurality of water collecting passages 121 having a predetermined length arranged in parallel to collect water falling from the upper portion. A water collecting tank 123 may be disposed at one end of the water collecting passage 121 to collect water collected by the water collecting passage 121. A drain hole 122 is formed at the bottom of the sump 123 to discharge or reuse the collected water. The drain hole 122 may be connected to the cooling tower water tank 38.

Next, the operation of the apparatus for reducing white smoke and evaporated water according to the third embodiment is as follows.

In the press-fitted airtight type closed cooling tower 60 having the reduced white smoke and the evaporated water recovery device according to the third embodiment, the saturated air (a) passing through the tube bundle (63), which is a heat transfer medium, is saturated air flow path of the condenser (50a). Condensed by atmospheric air (b) passing through condensation air passage 51 while passing through (54), leaving condenser 50a to unsaturated air (a ') with reduced water content and temperature and rising vertically In addition, the air (b) of the atmosphere passing through the condensation air flow passage 51 leaves the condenser in a heated state (b ') by the latent condensation heat released while the saturated air condenses. The air of the heated atmosphere that has left the condenser 50a flows to the air mixer 90 through a separate induction pipe 61, and is discharged through the outlet 92 of the mixing pipe 91 of the air mixer 90. When vortex occurs. Due to this vortex, the unsaturated air of the state imagined vertically through the saturated air flow path 54 of the condenser 50a and the air of the air discharged through the outlet 92 of the air mixer 90 are well mixed, and then By discharging to the atmosphere with the humidity lowered significantly, the water vapor in the exhaust air does not fall below the dew point, so that white smoke is not generated.

The condensation amount of the cooling tower 60 in which the white lead reduction and the evaporated water recovery device according to the third embodiment is installed increases as the temperature of the air is low, and the annual average condensation rate is about 20-30% of the evaporation amount.

Fourth Embodiment

12 is a view showing the configuration of a pressurized air blowing type open cooling tower 80 in which a white lead reduction and evaporated water recovery device is installed according to a fourth embodiment of the present invention.

The press-injection type open cooling tower 80 is a cooling tower in which cooling water is cooled by directly contacting the air flowing into the cooling tower with the filler 33.

Referring to FIG. 12, the cooling tower according to the fourth embodiment of the present invention includes a first fan 84 which is an axial or centrifugal fan at the bottom, a second fan 31 disposed at the dry air suction port, and a tube bundle 63. ), An injection nozzle 39, a condenser 50a, an induction pipe 61, and an air mixer 90.

Comparing the press-injection type open cooling tower 80 according to the fourth embodiment of the present invention with the press-injection type closed cooling tower 60 according to the third embodiment, the tube bundle whose heat transfer medium that heat-exchanges with the cooling water in the wet part is sealed. The remaining components and functions are the same except that the open filling filler 33 is used instead of the 63 and the injection nozzle 39, and the heat exchange with the coolant in the filling 33 is performed in the second embodiment of FIG. Since the heat exchange with the cooling water in the filler 33 of the embodiment is the same, further detailed description is omitted.

The condensation amount of the cooling tower 80 in which the white lead reduction and the evaporated water recovery system according to the fourth embodiment is installed increases as the temperature of the air is lowered, and the annual average condensation rate is about 20-30% of the evaporation amount.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions, modifications, and alterations are possible within the scope without departing from the technical spirit of the present invention. It will be evident to those who have knowledge of.

10: white lead reduction and evaporated water recovery device
21: condensation unit
30, 60, 80: cooling tower
31, 35, 65: fan
33: filling material
50, 50a: condenser
51: saturated air flow path
54: condensed air flow path
90: air mixer

Claims (28)

In the white lead reduction and evaporated water recovery device for condensing saturated steam discharged from the stack or duct to recover water and reduce white lead,
Reduction unit 13 for reducing the flow rate of the saturated steam discharged from the stack or duct;
And a plurality of condensation tubes 22 into which atmospheric air flows and flows therein, and the saturated water vapor passing through the deceleration section 13 flows to the outer surfaces of the condensation tubes 22 to condense the condensation. A condenser 21 for exchanging high temperature saturated steam outside the tube and low temperature atmospheric air inside the condenser tube;
A first discharge pipe (19) for discharging the air of the atmosphere inside the condensation tube heated by the latent condensation of saturated steam outside the condensation tube during the heat exchange process in the condensation unit (21);
A second discharge pipe (17) for discharging saturated steam which discharges latent heat of condensation into air of the atmosphere inside the condensation tube during a heat exchange process in the condensation unit (21);
A mixing unit mixing air of atmospheric air discharged through the first discharge pipe 19 and saturated steam discharged through the second discharge pipe 17; And
A speed increasing unit 16 disposed between the condensing unit 21 and the second discharge pipe 17 to increase the flow rate of the saturated water vapor passing through the condensation pipe 22 outside of the condensing unit 21;
White plume relief and evaporated water recovery apparatus comprising a. delete The method of claim 1,
Flue gas reduction and evaporated water recovery apparatus, characterized in that the flow rate of the saturated steam discharged from the deceleration unit 13 is 2-6 m / s. The method according to claim 1 or 3,
White smoke reduction and evaporated water recovery apparatus, characterized in that the flow rate of the air flowing in the condensation tube (22) of the condensation unit 21 is 10-15 m / s. The method according to claim 1 or 3,
The first exhaust pipe (19) is white lead reduction and evaporated water recovery apparatus, characterized in that connected to the second discharge pipe (17) at an angle of incidence of 30-40 °. The method according to claim 1 or 3,
A plurality of condensation tube (22) of the condensation unit (21) is white lead reduction and evaporated water recovery apparatus, characterized in that arranged perpendicular to the flow direction of the saturated steam in the condensation unit body. delete Air and cooling water flowing into the fan 31 installed at the upper end of the cooling tower, a pair of wet air inlets 34, cooling water injection units 40, and wet air inlets 34 disposed at lower portions of both sides of the cooling tower. Filler 33 for heat exchange, an external damper 43 for adjusting the amount of air flowing into the dry part air inlet 41, the dry part air inlet 41 disposed in the upper portion of the cooling tower, the filler ( An internal damper (37) for adjusting the amount of saturated air flowing upward through the 33 and flowing to the dry part; A condenser 50 for exchanging heat from atmospheric air introduced through the dry part air inlet 41 and saturated air passing through the filler 33; In the condensate condenser 50 and the saturated air and the humidity through the condenser 50 passing through the condenser 50, the mixture comprising a mixture of the air of the atmospheric temperature rises with each other, the white reduction and evaporated water recovery cooling tower,
The condenser 50 includes a saturated air flow passage 51 through which the saturated air flowing through the filler 33 flows, and a condensation air flow passage 54 through which outside air introduced through the dry air intake port 41 flows. The saturated air flow passage 51 and the condensation air flow passage 54 are disposed perpendicular to each other, and a plurality of the saturated air flow passages 51 and the condensation air flow passages 54 are alternately disposed.
The saturated air flow path 51 and the condensation air flow path 54 of the condenser 50 are made of a thin sheet,
A plurality of concave button fasteners 56 and a plurality of convex button fasteners 56 corresponding thereto are formed at the edge of the sheet,
Adhesive is applied to the joints of the edges of the opposing sheets, and then the plurality of concave button fasteners 56 and the corresponding convex button fasteners 56 are fixed to each other so that the saturated air flow path ( 51 and condensed air flow path 54 are formed,
The white smoke reduction and evaporated water recovery cooling tower, characterized in that the flow rate of the air passing through the saturated air flow passage (51) and the condensation air flow passage (54) is 2-6 m / s. delete 9. The method of claim 8,
A white lead reduction and evaporated water recovery cooling tower, characterized in that a guider (55) having an acidic structure of 35-40 ° is formed at the inlet and the outlet of the saturated air passage (51) and the condensed air passage (54). The method of claim 10,
Whitening relief and evaporated water recovery cooling tower, characterized in that the corrugated surface 57 is formed on the inclined surface of the saturated air flow path (51) and the condensation air flow path (54) and the slope of the mountain guide (55). 9. The method of claim 8,
White lag and evaporation, characterized in that a plurality of projections (59) are formed on both sides of the condenser sheet vertically and horizontally to maintain a constant distance between the saturated air passage (51) and the condensation air passage (54). Water recovery cooling tower. 9. The method of claim 8,
The white lead relief and evaporated water recovery cooling tower, characterized in that the wave-shaped protrusions 58 are formed on the condenser sheet forming the saturated air flow path 51 and the condensation air flow path 54. 9. The method of claim 8,
White smoke reduction and evaporated water recovery cooling tower, characterized in that it further comprises a scattering eliminator (32) to prevent the cooling water injected into the filler (33) to be discharged to the atmosphere. delete 9. The method of claim 8,
Further comprising a temperature sensor for measuring the temperature of the atmosphere,
When the temperature of the air is 28 ° C. or more, the external damper 43 is closed and the internal damper 37 is opened.
If the air temperature is 24-28 ℃ the external damper 43 and the internal damper 37 is opened,
When the temperature of the atmosphere is less than 24 ℃ the external damper (43) is opened, the internal damper (37) characterized in that the white lead reduction and evaporated water recovery cooling tower. delete In the white water reduction and evaporated water recovery cooling tower comprising a wet part of the lower part and a dry part of the upper part, condensed saturated air to recover water vapor and reduce white smoke,
A first fan (64) for introducing saturated air into the cooling tower;
A hermetic or open heat exchanger for reducing the temperature of the saturated air by heat exchange with cooling water;
Condensed air passage 54 through which the air of the atmosphere introduced through the air inlet 65 of the dry portion and the saturated air passage 51 through which the saturated air passing through the heat exchange unit passes, the condensed air passage ( 54) and a condenser 50a disposed adjacent to each other so that the air of the atmosphere in the condensation air passage and the saturated air in the saturated air passage exchange heat.
A second fan (31) for introducing atmospheric air into the condensation air flow passage (54) of the condenser (50a);
An air mixer (90) disposed above the condenser (50a); And
It includes an induction pipe 61 for discharging the air of the atmosphere discharged from the condenser 50a to the air mixer 90,
The temperature is raised while passing through the saturated air passage 51 of the condenser 50a and the condensed air passage 54 of the condenser 50a by condensation while the humidity is lowered, and through the induction pipe 61. The air of the discharged air is mixed in the air mixer 90,
In the condenser 50a, the saturated air flow passage 51 and the condensation air flow passage 54 are made of a thin sheet.
A plurality of concave button fasteners 56 and a plurality of convex button fasteners 56 corresponding thereto are formed at the edge of the sheet,
An adhesive is applied to the joints of the edges of the opposing sheets, and then the plurality of concave button fasteners 56 and the corresponding convex button fasteners 56 are coupled to each other so that the saturated air flow path 51 ) And condensed air flow path (54) is formed,
The air mixer 90 includes a plurality of mixing pipes 91 whose upper portion is opened to form an outlet 92.
The white smoke reduction and evaporated water recovery cooling tower, characterized in that the flow rate of the air passing through the saturated air flow passage (51) and the condensation air flow passage (54) is 2-6 m / s. delete delete 19. The method of claim 18,
The plurality of mixing pipes (91) is white lead reduction and evaporated water recovery cooling tower, characterized in that arranged in a direction perpendicular to the flow direction of saturated air in the air mixer (90) body. delete 19. The method of claim 18,
White water reduction and evaporated water recovery cooling tower, characterized in that it further comprises a water collecting tank (123) having a drain 22 for collecting the water condensed by the condenser (50a) and draining the collected water to the outside. delete delete delete delete delete

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