KR101947545B1 - Cooling tower - Google Patents

Abstract

The present invention relates to a cooling tower. A cooling tower housing has an inner space, formed on a side thereof with an inlet for sucking external air, formed at an upper side thereof with an outlet for exhausting inner air, and formed with an air supply port adjacent to the inlet to receive fresh air for preventing white smoke. At least one blower sucks the external air from the inlet into the cooling tower housing and sends the external air to the outlet. An inlet-side heat exchanger is disposed toward the inlet to cool an internal heat medium by exchanging heat with the external air sucked from the inlet. A water injector sprays water from an upper side of the inlet-side heat exchanger to cool the heating medium in the inlet-side heat exchanger. A water tank receives the water falling through the inlet-side heat exchanger. A damper is installed in the air supply port to regulate the flow rate of the fresh air supplied into the cooling tower through the air supply port. Accordingly, the white smoke is prevented.

Description

Cooling tower [0002]

The present invention relates to a cooling tower, and more particularly to a cooling tower for cooling a heating medium having a high temperature after being used for various mechanical devices and the like for reuse.

Generally, heat generated in various mechanical devices is transferred to a cooling heat medium such as water, a mixture of antifreeze liquids, oil, and a transformer oil, and the cooling heat medium having a high temperature is cooled through heat exchange with the outside air.

When pure water which can be brought into direct contact with air is used as the heating medium for cooling, an open cooling tower is used in which water is sprayed onto the heat transfer medium such as a filler and the sprayed water is brought into contact with external air introduced into the cooling tower do.

On the other hand, when the antifreeze water, oil, transformer oil, or the like, which can not be brought into direct contact with air, is used as the heating medium for cooling, the cooling heat medium flows into the tube of the heat exchanger, And a sealed cooling tower for spraying water onto the surface of the tube and performing heat exchange with the cooling heat medium by evaporation is used.

As described above, in the case of a cooling tower using a wet cooling method, when water evaporates into gaseous steam and is discharged into the atmosphere, gaseous steam is liquefied by the cold atmosphere and visible white smoke appears. Since the white smoke from the cooling tower originates from the evaporation and scattering of pure water, it does not have the environmental hazard due to the composition like the existing air pollutant. However, it is recognized as pollution to the residents in the surrounding area. Freezing, and the like. Therefore, measures for preventing the occurrence of white smoke have been proposed.

Registered Patent No. 10-1349114 (published on Apr. 16, 2014)

The object of the present invention is to provide a cooling tower capable of preventing the occurrence of white smoke.

According to an aspect of the present invention, there is provided a cooling tower including a cooling tower housing, at least one blower, an intake side heat exchanger, a water injector, a water tank, and a damper. The cooling tower housing has an inner space, an intake port for sucking outside air at the side, an exhaust port for exhausting the inner air at the upper side, an air supply port for supplying fresh air for preventing white smoke at the intake port side, . At least one blower sucks the outside air from the inlet port into the cooling tower housing in the cooling tower housing and sends it to the exhaust port. The intake-side heat exchanger is arranged on the side of the intake port so as to cool the internal heat medium by exchanging heat with the external air sucked from the intake port. The water injector injects water at the upper side of the intake side heat exchanger to cool the heating medium in the intake side heat exchanger. The water tank receives water falling through the intake-side heat exchanger. The damper is installed in the air supply port to regulate the flow rate of the fresh air supplied into the cooling tower through the air supply port.

According to the present invention, it is possible to prevent the generation of complaints of the residents of the surrounding area due to pollution concerns by effectively preventing the occurrence of white smoke, and to prevent the problem of visually impaired roads and water freezing on the road surface at airports and airports.

1 is a side view of a cooling tower according to an embodiment of the present invention.
Fig. 2 is a schematic plan view of Fig. 1. Fig.
Fig. 3 is a front view of the intake-side heat exchanger according to an example in Fig. 1;
4 is a partial cross-sectional view of Fig.
5 is an exploded perspective view of FIG.
Fig. 6 is an exploded perspective view showing the attachment / detachment mechanism for tubes taken in Fig. 5; Fig.
Fig. 7 is a front view of Fig. 5;
FIG. 8 is a view for explaining an example of setting the flow path of the fluid by the partition walls of the distribution header, in FIG.
Figure 9 is a front view of the blower in accordance with an example in Figure 1;
Fig. 10 is a side sectional view of Fig. 9; Fig.
11 is an enlarged view of the area A in Fig.
Fig. 12 is a side cross-sectional view showing a partially exploded view in Fig. 10;
Fig. 13 is a side cross-sectional view of the height adjusting unit shown in Fig. 10; Fig.

The present invention will now be described in detail with reference to the accompanying drawings. Here, the same reference numerals are used for the same components, and a detailed description of known functions and configurations that may unnecessarily obscure the gist of the present invention will be omitted. Embodiments of the present invention are provided to more fully describe the present invention to those skilled in the art. Accordingly, the shapes and sizes of the elements in the drawings and the like can be exaggerated for clarity.

1 is a side view of a cooling tower according to an embodiment of the present invention. Fig. 2 is a schematic plan view of Fig. 1. Fig.

1 and 2, a cooling tower according to an embodiment of the present invention includes a cooling tower housing 100, at least one blower 200, an intake-side heat exchanger 300, a water injector 400, A water tank 500, and a damper 600.

The cooling tower housing 100 has an internal space 110. The cooling tower housing 100 is provided with an intake port 120 for sucking outside air on its side and an exhaust port 130 for exhausting internal air on its upper side and is provided adjacent to the intake port to supply fresh air for preventing white smoke Receiving air supply port 140 is formed. The inner space 110 of the cooling tower housing 100 can be partitioned into the first and second inner space portions 110a and 110b by the vertical partition wall 111. [

The first internal space portion 110a is formed with an intake port 120 on the side and supports the intake side heat exchanger 300 on the intake port 120 side. The first internal space 110a mounts and supports the water injector 400 on the upper side of the intake-side heat exchanger 300. The first inner space portion 110a can mount and support the water tank 500 on the lower side. An air supply port 140 is formed on the upper side of the first inner space portion 110a and a damper 600 is mounted on the air supply port 140 side.

The second internal space 110b is formed with an exhaust port 130 on the upper side and an exhaust side heat exchanger 700 to be described later mounted on the exhaust port 130 to support the second internal space 110b. The second internal space portion 110b accommodates and supports the blower 200. [ The vertical partition 111 has a through hole for allowing air to flow from the first inner space 110a to the blower 200. [

At least one blower 200 sucks outside air from the inlet 120 in the cooling tower housing 100 into the cooling tower housing 100 and sends it to the outlet 130. Thus, the outside air can be sucked into the cooling tower housing 100 through the intake-side heat exchanger 300 disposed at the intake port 120 side, and then can be advanced to the exhaust port 130. The blower 200 may draw fresh air from the air supply port 140 into the cooling tower housing 100 and send it to the exhaust port 130.

The plurality of blowers 200 may be horizontally arranged in parallel with the air inlet 120 in the second inner space portion 110b of the cooling tower housing 100. The blower 200 can be driven and controlled by a controller that controls the cooling tower as a whole.

The intake-side heat exchanger 300 is arranged on the side of the intake port 120 so as to cool the internal heat medium by exchanging heat with the external air sucked from the intake port 120. The internal heat medium of the intake side heat exchanger 300 may correspond to a cooling heat medium such as water, antifreeze mixed water, oil, transformer oil, etc., which is transmitted heat generated in various mechanical devices and the like. The intake-side heat exchanger (300) is disposed so as to be in contact with the outside air sucked from the inlet (120) with a maximum heat transfer area. The intake-side heat exchanger 300 can be driven and controlled by a controller.

The water injector 400 injects water at the upper side of the intake-side heat exchanger 300 to cool the heating medium in the intake-side heat exchanger 300. The water injected from the water injector 400 contacts the outside air in the process of flowing along the surface of the intake-side heat exchanger 300 and is partially evaporated, so that the heating medium in the intake-side heat exchanger 300 can be cooled have. The water injector 400 may be configured such that the injection nozzle 410 disposed on the upper side of the intake side heat exchanger 300 receives the water pressure-fed by the pump 420 and injects the water to the intake side heat exchanger 300 .

The water tank 500 receives water falling through the intake-side heat exchanger 300. The pump 420 may pump the water stored in the water tank 500 to the injection nozzle 410 and circulate the water. In another example, the water tank 500 drains the water contained in the intake-side heat exchanger 300 through the drain port, and the pump 420 may transport the water stored in the separate water tank to the injection nozzle 410.

The damper 600 is installed in the air supply port 140 to regulate the flow rate of the fresh air supplied to the inside of the cooling tower housing 100 through the air supply port 140. The fresh air is mixed with the inside air in a relatively dry state relative to the inside air of the cooling tower housing 100 through the intake side heat exchanger 300 to lower the relative humidity of the inside air, thereby preventing the occurrence of white smoke. The fresh air may be supplied through the air supply port 140 in a variety of ways, such as being made by dehumidifying the outside air. Fresh air can be sucked into the cooling tower housing 100 by the blower 200 or fed into the cooling tower housing 100 by a separate blower and supplied.

The damper 600 can prevent the occurrence of white smoke by controlling the flow rate of the fresh air introduced in accordance with the humidity of the internal air of the cooling tower housing 100. For example, a hygrometer may be provided in the cooling tower housing 100. The controller can adjust the flow rate of the fresh air by the damper 600 so as to adjust the humidity of the inside air to the target humidity based on the humidity information of the inside air of the cooling tower housing 100 measured by the hygrometer.

The damper 600 may include a damper tube mounted around the air supply port 140 and a flap installed on the damper tube to adjust the opening degree of the damper tube by a rotating method or a sliding method. The dampers 600 may be installed in the air supply port 140 in a number corresponding to the number of the air supply ports 140.

On the other hand, the cooling tower may further include an exhaust-side heat exchanger 700. The exhaust-side heat exchanger 700 is arranged on the side of the exhaust port 130 so that the internal air sent out by the blower 200 is heat-exchanged with the internal heat medium. The exhaust-side heat exchanger 700 heats the internal air sent out by the blower 200 to further lower the relative humidity of the internal air and discharge it to the atmosphere through the exhaust port 130, thereby further enhancing the effect of preventing the occurrence of white smoke I will.

For this purpose, the internal heat medium of the exhaust-side heat exchanger 700 is set at a temperature at which the air flowing on the surface of the exhaust-side heat exchanger 700 can be heated. For example, the exhaust-side heat exchanger 700 may receive a part of the heating medium supplied to the intake-side heat exchanger 300, or may receive the heating medium at a high temperature separately. The exhaust-side heat exchanger 700 can be driven and controlled by a controller. The exhaust-side heat exchanger is disposed so as to be in contact with the internal air traveling to the exhaust port (130) with a maximum heat transfer area.

FIG. 3 is a front view of the intake-side heat exchanger according to an example in FIG. 4 is a partial cross-sectional view of Fig. 5 is an exploded perspective view of FIG. Fig. 6 is an exploded perspective view showing the attachment / detachment mechanism for tubes taken in Fig. 5; Fig. Fig. 7 is a front view of Fig. 5; FIG. 8 is a view for explaining an example of setting the flow path of the fluid by the partition walls of the distribution header, in FIG.

3 to 8, the intake-side heat exchanger 300 includes tubes 310, radiating fins 320, end plates 330, a tube attaching / detaching mechanism 340, The distribution headers 350, and the attachment / detachment mechanisms 360 for the header.

The tubes 310 are arranged side by side with each other having an internal passage through which the heating medium flows. The tubes 310 may be arranged long in the left-right direction on the basis that the end plates 330 are arranged to face each other at left and right intervals. Here, the tubes 310 may be arranged in a plurality of rows in the vertical direction. Further, the tubes 310 may be arranged in a plurality of rows in the front-rear direction in which the outside air passes. The tubes 310 may be equally configured as tubes each having a circular cross-sectional area. Each of the tubes 310 may be made of a metal material having excellent thermal conductivity.

The radiating fins 320 are disposed on the outer surface of each tube 310. The heat dissipation fins 320 increase the respective heat dissipation areas of the tubes 310, thereby enhancing the heat exchange effect. Each of the heat radiating fins 320 may have a shape in which annular fins having a predetermined outer diameter are arranged at regular intervals along the longitudinal direction of the tube 310 on the outer surface of the tube 310.

Alternatively, each of the heat radiating fins 320 may be formed on the outer surface of the tube 310 in a spiral direction with a predetermined outer diameter along the longitudinal direction of the tube 310. Each of the radiating fins 320 may be integrally formed on the outer surface of the tube 310 or may be a separate member and coupled to the tube 310. The radiating fins 320 may all be constructed identically. Each of the radiating fins 320 may be made of a metal material having excellent thermal conductivity.

The end plates 330 are arranged at intervals on both sides of the tubes 310 to draw out both ends of the tubes 310 through the drawing holes 331. The end plates 330 support the tubes 310 while the tubes 310 are mounted by the attachment / detachment mechanisms 340 for the tubes, respectively. The end plates 330 may be configured to be paired. The end plates 330 may be made of a metal such as stainless steel. The drawing hole 331 may be formed in a circular shape. The lead-out hole 331 may have a screw groove on the inner surface thereof for screwing with the first fastening member 341 of the tube attachment / detachment mechanism 340.

The inner diameter D1 of the drawing hole 331 is set to be larger than the outer diameter D2 of the radiating fin 320 so that the tube 310 having the radiating fin 320 disposed on the outer surface thereof can pass through. Therefore, when some of the tubes 310 are damaged due to the use of the heat exchanger, only the damaged tubes 310 are removed from the end plates 330 A new tube can be attached to the end plates 330 by the attachment / detachment mechanisms 340 for the tubes, thereby facilitating the replacement of the damaged tube 310. [

The tube attaching / detaching mechanisms 340 attach and detach both ends of each tube 310 to and from the end plates 330. Each of the attachment / detachment mechanisms 340 for the tubes allows the end portion of the tube 310 to be attached to or detached from the end plate 330. For example, each tube attaching / detaching mechanism 340 includes a first fastening member 341, a second fastening member 342, a fixed washer 343, a first tube sealing member 344, And may include a tube sealing member 345.

The first fastening member 341 is screwed into the lead-out hole 331 of the end plate 330 while the exit end of the first fastening member 341 is supported through the end of the tube 310 through the hollow 3411 having a wider width than the entrance do. The first fastening member 341 may include a threaded portion 3412 and a head portion 3413. The screw portion 3412 is formed to be screwed into the lead-out hole 331. The head portion 3413 can be connected to the screw portion 3412 with a wider cross-sectional area than the screw portion 3412 so as to have a step with the screw portion 3412. [ The head portion 3413 may be hexagonal so as to be rotatable by a hexagonal wrench.

The first fastening member 341 is disposed on the outer side of the end plate 330 so that the head portion 3413 is engaged with the periphery of the take-out hole 331 along the direction in which the screw portion 3412 is screwed into the take- And can be tightened or loosened to the end plate 330. [0054] A sealing member is disposed between the periphery of the drawing hole 331 and the head portion 3413 so as to maintain airtightness so that leakage of the heating medium to the space between the drawing hole 331 and the screw portion 3412 can be prevented. Here, the sealing member has an O-ring shape and may be made of a material such as rubber.

The hollow 3411 of the first fastening member 341 is formed with a support hole 3411a at the entrance side and a screw hole 3411b at the exit side and a support hole 3411a and a screw hole 3411b at the center A connection hole portion 3411c may be formed. The support hole portion 3411a is sized to fit the tube 310 within the allowable tolerance range, so that the tube 310 can be inserted and supported. The screw hole portion 3411b is formed to be screwed with the screw portion 3422 of the second fastening member 342. [

The inner wall of the connection hole 3411c is tapered from the screw hole 3411b toward the support hole 3411a so as to connect the screw hole 3411b and the support hole 3411a. A first seating groove 3411d for seating the first tube sealing member 344 may be formed at a boundary between the connection hole 3411c and the support hole 3411a. A second seating groove 3411e for seating the second tube sealing member 345 may be formed around the outlet of the screw hole 3411b. The first fastening member 341 may be made of a metal such as stainless steel.

The second fastening member 342 is inserted into the first fastening member 341 while the end portion of the tube 310 passing through the hollow 3411 of the first fastening member 341 is passed through the hollow 3421, And is screwed to the hollow 3411 at the outlet portion of the pipe. The hollow 3421 of the second fastening member 342 is sized to fit the tube 310 within an allowable tolerance range, so that the tube 310 can be inserted and supported.

The second fastening member 342 may include a threaded portion 3422, a head portion 3423, and a pressing portion 3424. The screw portion 3422 is formed to be screwed to the screw hole portion 3411b of the first fastening member 341. [ The head portion 3423 may have a wider cross-sectional area than the thread portion 3422 and may be connected to the thread portion 3422. The head portion 3423 may be hexagonal so as to be rotatable by a hexagonal wrench. The pressing portion 3424 is protruded along the boundary portion between the screw portion 3422 and the head portion 3423 so as to have an outer diameter larger than that of the screw portion 3422 but smaller than the inner diameter of the second seating groove 3411e, The second tube sealing member 345 in the second seating groove 3411e can be pressed as the fastening member 342 is tightened by the first fastening member 341. [

The second fastening member 342 is disposed on the outer side of the first fastening member 341 so that the threaded portion 3422 is fastened to the first fastening member 341 in the direction of screwing to the threaded hole 3411b, And can be tightened or loosened by the member 341. At this time, the pressing portion 3424 can press or release the second tube sealing member 345. The second fastening member 342 may be made of a metal such as stainless steel.

The fixing washer 343 is compressed by being pinched by the first fastening member 341 while the second fastening member 342 is tightened by the first fastening member 341 in a state in which the end portion of the tube 310 is supported through the hollow, In the hollow 3411 of the first fastening member 341 so as to be fixed. The stationary washer portion 343 may include a first washer 3431 and a second washer 3432. The first washer 3431 has a hollow 3431a which penetrates and supports the end portion of the tube 310. [ The hollow portion 3431a of the first washer 3431 is sized to fit the tube 310 within an allowable tolerance range, so that the tube 310 can be inserted and supported.

The first washer 3431 may have a tapered shape in which the outer circumferential surface thereof abuts the inner surface of the connection hole portion 3411c of the first fastening member 341. [ The first washer 3431 can be pressed through the second washer 3432 to fix the tube 310 as the second fastening member 342 is tightened by the first fastening member 341. [

The second washer 3432 is disposed between the first washer 3431 and the second fastening member 342. The second washer 3432 has a hollow 3432a which penetrates and supports the end portion of the tube 310. [ The hollow 3432a of the second washer 3432 is sized to fit the tube 310 within an allowable tolerance range so that the tube 310 can be inserted and supported. The second washer 3432 may have a shape having a predetermined outer diameter so as to abut the inner surface of the threaded hole 3411b of the first fastening member 341. [ The second washer 3432 can be pressed to fix the tube 310 while pressing the first washer 3431 as the second fastening member 342 is tightened by the first fastening member 341. [

The first washer 3431 may be formed with a concave groove 3431b having a shape deeper toward the center on a surface facing the second washer 3432. [ In this case, the second washer 3432 may be formed with a protrusion 3432b to abut the inner surface of the concave groove 3431b of the first washer 3431 as a whole on the surface facing the first washer 3431. Therefore, the area in which the second washer 3432 presses the first washer 3431 can be increased. The first and second washers 3431 and 3432 may be made of a metal material such as stainless steel. Meanwhile, the stationary washer portion 343 is not limited to the illustrated one, but may be configured in various ways to perform the functions described above.

The first tube sealing member 344 is disposed in the hollow 3411 of the first fastening member 341 to maintain the airtightness between the first fastening member 341 and the tube 310. [ The first tube sealing member 342 can be seated in the first seating groove 3411d formed between the connection hole portion 3411c and the support hole portion 3411a. The first tube sealing member 345 is compressed through the fixing washer 343 as the second fastening member 342 is tightened by the first fastening member 341 in a state of being seated in the first seating groove 3411d, The airtightness between the first fastening member 341 and the tube 310 can be maintained. Accordingly, the first tube sealing member 344 can prevent the leakage of the heat medium to the space between the first fastening member 341 and the tube 310. [ The first tube sealing member 344 has an O-ring shape and may be made of a material such as rubber.

The second tube sealing member 345 is disposed in the hollow 3411 of the first fastening member 341 so as to maintain the airtightness between the first fastening member 341 and the second fastening member 342. [ The second tube sealing member 345 can be seated in the second seating groove 3411e formed around the outlet of the screw hole portion 3411b. The second tube sealing member 345 is compressed and deformed as the second fastening member 342 is tightened by the first fastening member 341 while being seated in the second seat groove 3411b, 341 and the second fastening member 342 can be maintained. Therefore, the second tube sealing member 345 can prevent the leakage of the heating medium between the first fastening member 341 and the second fastening member 342. [ The second tube sealing member 345 has an O-ring shape and may be made of rubber or the like.

The distribution headers 350 are disposed on the end plates 330 so as to cover both ends of each tube 310 so as to communicate with the tubes 310. [ The distribution headers 350 distribute the heat medium supplied through the heat medium supply port 351 through the internal passages of the tubes 310 and through the heat medium outlet 352.

The distribution header 350 may have an internal space and a portion facing the end plate 330 may be opened. The distribution header 350 may be flanged along the perimeter of the aperture and held in abutment with the end plate 330 by a flange. A heating medium supply port 351 for receiving a heating medium is formed in one of the distribution headers 350 and a heating medium discharge port 352 for discharging a heating medium is formed in the other distribution header 350. As another example, it is needless to say that the heat medium supply port 351 and the heat medium discharge port 352 may be formed in either one of the distribution headers 350 according to the flow path setting of the heat medium. The distribution headers 350 may be made of a metal such as stainless steel.

The distribution headers 350 may have partitions 353 arranged to set the flow path of the heat medium through the internal passageway of each tube 310. For example, the partition walls 353 pass through the tubes 310 in a staggered manner and the heat medium flowing through the heat medium supply port 351 formed below the one distribution header 350 flows through the tubes 310, The flow path of the heating medium can be set in such a manner as to be discharged through the heating medium outlet 352 formed in the heating medium.

Thus, the partition walls 353 can set the flow path of the heating medium depending on the arrangement position. Accordingly, the distribution headers 350 can be easily assembled to the end plates 330 by having the partition walls 353 that set the flow path of the heating medium to a desired shape, thereby easily setting the flow path of the heating medium to a desired shape.

The partition walls 353 may be formed integrally with the distribution header 350. Although not shown, each of the partition walls 353 may be hermetically sealed with the end plate 330 by mounting a gasket at a portion where the partition plate 353 abuts the end plate 330. Here, the gasket has a shape that covers the end portion of the partition wall 353 and may be made of a material such as rubber. As another example, the partition walls 353 may be detachable to the distribution header 350, and the flow path of the heating medium may be freely set to a desired shape.

The attachment / detachment mechanisms for the header 360 attach / detach the distribution headers 350 to / from the end plates 330. The attachment / detachment mechanisms 360 for the header enable the distribution headers 350 to be detached from the mounted state or mounted on the end plates 330. For example, the header attaching / detaching mechanism 360 may include bolt members 361 and nut members 362. The bolt members 361 are fitted into the fastening holes formed in the distribution header 350 and the end plate 330, respectively. In this state, the distribution headers 350 can be mounted on the end plate 330 as the nut members 362 are fastened to the bolt members 351 and tightened, and the nut members 362 are fixed to the bolt members 351 so that the dispensing headers 350 are separated from the end plates 330. [0052]

Although not shown, a gasket is disposed between the flange of the distribution header 350 and the end plate 330 to maintain the airtightness, thereby preventing leakage of the heating medium between the distribution header 350 and the end plate 330. Here, the gasket has a closed loop shape and may be made of a material such as rubber.

Meanwhile, the exhaust-side heat exchanger 700 may be configured in the same manner as the intake-side heat exchanger 300. Here, the exhaust heat exchanger 700 may be horizontally disposed at the exhaust port 140 side so as to maximize the heat transfer area in contact with the air flowing to the exhaust port 130. Of course, the exhaust-side heat exchanger 700 and the intake-side heat exchanger 300 are not limited to those illustrated, but may be configured as a conventional heat exchanger.

FIG. 9 is a front view of the blower in FIG. 1 according to an example. Fig. 10 is a side sectional view of Fig. 9; Fig. 11 is an enlarged view of the area A in Fig. Fig. 12 is a side cross-sectional view showing a partially exploded view in Fig. Fig. 13 is a side cross-sectional view of the height adjusting unit shown in Fig. 10; Fig.

9 to 13, the blower 200 according to an exemplary embodiment includes a duct 210, an impeller 220, a rotary motor 230, a shaft coupling member 240, a bearing 250, A bearing housing 260, and a first bearing seal member 271 and a second bearing seal member 272.

The duct 210 guides the air introduced through the air inlet 211 to flow out through the air outlet 212 through the internal space. The air inlet 211 is arranged to be connected to the connection hole of the vertical partition wall 111 and the air outlet 212 is arranged toward the air outlet 130. The duct 210 is supported on the duct support 201. The duct support 201 can be mounted on the inner bottom of the cooling tower housing 100.

The impeller 220 flows air through the air inlet 211 and flows out through the air outlet 212 as the impeller 220 rotates about the horizontal rotation axis in the duct 210. The impeller 220 can sweep the air as it rotates with wings arranged at regular intervals on the circumference.

The rotation motor 230 generates rotational force by the drive shaft 231. The rotation motor 230 is configured such that the drive shaft 231 is drawn out from the motor body 232 and is rotatable with respect to the motor body 232. The rotating motor 230 is arranged such that the driving shaft 231 is coaxial with the rotational center axis of the impeller 220 at the rear of the impeller 220. The rotary motor 230 provides rotational force to the impeller 220 via the shaft coupling member 240, thereby enabling the impeller 220 to rotate.

The shaft coupling member 240 is pulled rearward from the duct 210 while the front portion of the shaft coupling member 240 is fixed to the rotation center portion of the impeller 220 at the rear side of the impeller 220. [ The shaft coupling member 240 may include a shaft coupling body 241 having a circular outer periphery and a shaft coupling flange 242 extending along the front portion of the shaft coupling body 241. The shaft coupling flange 242 may be formed of a circular flange having a larger diameter than the shaft coupling body 241.

The shaft coupling flange 242 may be bolted to the impeller 220 while the front surface thereof is in contact with the rear surface of the impeller 220 while being coaxial with the rotation center axis of the impeller 220. The shaft coupling member 240 fixes the drive shaft 231 through the shaft hole 243 formed in the rear end portion of the shaft coupling member 240 so as to transmit the rotational force of the drive shaft 231 to the impeller 220. Accordingly, the driving shaft 231 may be fixed to the shaft coupling member 240 in a state of being coaxial with the rotational center axis of the impeller 220. The front portion of the drive shaft 231 can be bolted to the shaft coupling flange 242.

The shaft hole 243 is formed at a certain depth from the rear end of the shaft coupling body 241. The shaft hole 243 may be dimensioned to interference fit the drive shaft 231. Keyholes are formed in the shaft hole 243 and the drive shaft 231 and a sunk key 244 is inserted into the key grooves to prevent relative rotation slippage between the drive shaft 231 and the shaft coupling member 240 .

The bearing 250 supports the rotation of the shaft coupling member 240 as the drive shaft 231 rotates. Accordingly, the bearing 250 can disperse the weight of the impeller 220 fixed to the shaft coupling member 240. The bearing 250 may be a ball bearing. The ball bearings are constructed such that balls are received between the inner ring and the outer ring. The inner ring is fixed to the shaft coupling member 240 and the outer ring is fixed to the bearing housing 260 so that the shaft coupling member 240 is supported by the bearing housing 260 by the rolling motion of the balls when the shaft coupling member 240 rotates. As shown in Fig.

The bearing 2250 may be disposed on the shaft coupling body 241 of the shaft coupling member 240. The shaft coupling body 241 has an outer diameter smaller than that of the other portions of the bearing 250, so that the shaft coupling body 241 can have a stepped portion. The bearing 250 may be caught by the jaw and be supported with limited forward movement.

The bearing housing 260 is fixed to the duct 210 while supporting the outer periphery of the bearing 250. The bearing housing 260 may include a housing body 261 and a housing cover 262. The housing body 261 can be bolted to the front surface of the duct 210 while being in contact with the rear surface of the duct 210. The housing body 261 has a structure in which a central portion is horizontally penetrated and an insertion groove for partially inserting the bearing 250 is formed on the inner circumferential surface along the inner circumferential direction. The insertion groove is open at the rear portion. The housing cover 262 is bolted to the periphery of the rear opening of the insertion groove while covering the rear opening of the insertion groove, thereby supporting the bearing 250 in the insertion groove.

Accordingly, after the bearing housing 260 with the bearing 250 mounted thereon is assembled to the shaft coupling member 240, the shaft coupling member 240 is bolted to the impeller 220, and the bearing housing 260 is rotated by the rotation motor And the driving shaft 231 of the rotary motor 230 is fixed to the shaft coupling member 240 by bolting to the motor body 232 of the rotary shaft 230 so that the assembly of the blower can be completed.

The bearing housing 260 can mount a motor support 266 for supporting the rotation motor 230. The motor support 266 is mounted on the bearing housing 260 while being fixed to the motor body 232 of the rotation motor 230 to thereby stably support the rotation motor 230. The motor support 266 can be bolted to the front surface of the housing body 261 while being in contact with the rear surface of the housing body 261. Further, the motor support 266 can be bolted to the motor body 232 with its back surface abutted against the front surface of the motor body 232.

The housing body 261 may be formed with a support groove on the back surface thereof and a support block 266a protruding from the motor support table 266 may be formed on the front surface of the housing body 261. The motor support member 266 is fixed to the housing body 261 in a state where the support block 266a is fitted in the support groove and thus can more stably support the motor body 232. [

Since the rotary motor 230 can be mounted on the bearing housing 260 via the motor support table 266, the size of the rotary motor 230 can be changed according to the type of the rotary motor 230, The operator can easily replace the rotary motor 230 even if the motor 230 fails. On the other hand, the motor support member 266 is omitted, and the motor body 232 of the rotation motor 230 can be supported in a height-adjusted state on the duct support 201 by the height adjustment unit 280 of the embodiment have.

The first bearing sealing member 271 is mounted on the bearing housing 260 so as to maintain airtightness between the bearing housing 260 and the shaft coupling member 240 in front of the bearing 250. [ The first bearing sealing member 271 is pressed onto the shaft coupling body 241 while being fitted in the mounting groove formed in the inner circumferential surface of the housing body 261 to thereby maintain the airtightness between the housing body 261 and the shaft coupling body 241 . The first bearing seal member 271 may be formed in an O-ring shape.

The second bearing sealing member 272 is mounted to the bearing housing 260 so as to maintain airtightness between the bearing housing 260 and the shaft coupling member 240 at the rear of the bearing 250. [ The second bearing sealing member 272 is pressed onto the shaft coupling body 241 in a state of being fitted in a mounting groove formed in the inner circumferential surface of the housing cover 262 to thereby maintain the airtightness between the housing cover 262 and the shaft coupling body 241 . The second bearing sealing member 272 may be in the form of an O-ring.

Since the first and second bearing sealing members 271 and 272 can maintain the airtightness between the bearing housing 260 and the shaft coupling member 240 at the front and rear of the bearing 250, It is possible to protect the bearing by blocking the inflow of moisture or foreign matter.

The rotary motor 230 is directly connected to the impeller 220 via the shaft coupling member 240 so that the rotational force of the rotary motor 230 is transmitted to the impeller 220 by the shaft coupling member 240. [ It is possible to prevent the occurrence of fine dust due to the friction between the pulleys and the belt during operation and to prevent the occurrence of fine dust particles generated in the transverse direction The risk of burning of the bearing due to the tension can be eliminated, and the structure can be made compact with a simple structure.

The blower may include a height adjustment unit 280. The height adjusting unit 280 supports the motor body 232 of the rotary motor 230 in a height-adjusted state on the duct support 201. The height adjustment unit 280 may include an adjustment base 281, a lifting bracket 282, and a locking mechanism 286.

The adjustment base 281 is arranged to face the motor body 232 on the duct support 201. Here, a vibration proof member 283 may be provided between the adjustment base 281 and the duct support 201. The anti-vibration member 283 can block or mitigate transmission of vibration generated during operation of the rotary motor 230 to the duct support 201. The anti-vibration member 283 may be formed in a shape in which a spring is embedded in a rubber pad.

The lift bracket 282 is disposed on the upper side of the adjustment base 281 and fixed to the motor body 132. The lifting bracket 282 can be bolted to the motor body 232 with the motor body 232 mounted on the upper surface. The lifting bracket 282 may be formed in a plate shape.

The lock mechanism 286 locks the lift bracket 282 against the adjustment base 281 with the height of the motor body 232 adjusted as the lift bracket 282 moves up and down. The locking mechanism 286 may include height adjusting bolts 287 and first and second height adjusting nuts 288 and 289.

The height adjusting bolts 287 are fixed vertically on the upper surface of the adjustment base 281 with the respective screw portions facing upward. The height adjustment bolts 287 are arranged to stably lock the lift bracket 282 to the adjustment base 281. The height adjusting bolt 287 passes through the upper portion of the adjustment base 281 and is pulled upward. The fixing nut 287a is screwed to the height adjusting bolt 287 on the upper side of the adjusting base 281 and is screwed to the upper surface of the adjusting base 281 so that the height adjusting bolt 287 is moved upward from the adjusting base 281 As shown in Fig.

The lifting bracket 282 has fastening holes for passing the height adjusting bolts 287, respectively. The first height adjusting nut 288 is screwed to the height adjusting bolt 287 at a temporary height. In this state, after the height adjusting bolt 287 passes through the fastening hole of the lifting bracket 282, the first height adjusting nut 288 is rotated in the forward and reverse directions to adjust the lifting position, The height of the lifting and lowering bracket 282 can be finely adjusted and supported by the set height.

The second height adjusting nut 289 is screwed to the height adjusting bolt 287 on the upper side of the lifting bracket 282 while the lifting bracket 282 is adjusted to the set height with respect to the adjusting base 281, The lifting bracket 282 can be fixed to the first height adjusting nut 288 by tightening it on the upper surface of the first height adjusting nut 282. Thus, the lifting bracket 282 can be locked in a condition adjusted to the set height with respect to the adjustment base 281. [

Even if the size of the rotating motor 230 changes according to the type of the rotating motor 230, the height adjusting unit 280 flexibly copes with the height change of the rotating motor 230, As shown in Fig. Therefore, the replacement operation of the rotation motor 230 can be performed conveniently. In addition, even when the rotation motor 230 fails, the rotation motor 230 can be easily replaced. On the other hand, the blower 200 is not limited to the illustrated example, and may be constituted by a conventional blower.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation and that those skilled in the art will recognize that various modifications and equivalent arrangements may be made therein. It will be possible. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

100 .. Cooling Tower Housing
200. Blower
300. An intake-side heat exchanger
400 .. Water Injector
500 .. Tank
600 .. damper
700 .. Exhaust-side heat exchanger

Claims (4)

An air inlet for sucking outside air is formed on the side, an air outlet for discharging the inner air is formed, and an air supply port for receiving fresh air for preventing white smoke is formed adjacent to the air inlet A cooling tower housing;
At least one blower for sucking outside air from the inlet port into the cooling tower housing in the cooling tower housing and sending the outside air to the outlet;
An intake-side heat exchanger arranged on the intake port side to heat-exchange an internal heat medium with external air sucked from the intake port to cool the internal heat-exchanger;
A water injector for injecting water at an upper side of the intake-side heat exchanger to cool the heating medium in the intake-side heat exchanger;
A water tank receiving water falling through the intake-side heat exchanger; And
And a damper installed in the air supply port to adjust a flow rate of fresh air supplied into the cooling tower through the air supply port,
The internal space of the cooling tower housing is partitioned into first and second internal spaces by vertical partition walls,
Wherein the first internal space portion has the air inlet formed on the side thereof, the air inlet side heat exchanger is mounted on the air inlet port and the air inlet port is formed on the upper side, and the damper is mounted on the air supply port side,
Wherein the second internal space part is formed with the exhaust port on the upper side and receives and supports the blower,
Wherein the vertical partition has a through hole for allowing air to flow from the first inner space to the blower,
The intake-side heat exchanger includes:
Tubes each having an internal passage through which the heating medium flows and arranged in parallel with each other;
Radiating fins disposed on outer surfaces of the tubes;
End plates spaced apart on both sides of the tubes to draw out both ends of the tubes through the draw-out holes;
A tube attaching / detaching mechanism for attaching / detaching both ends of each tube to / from the end plates;
The heat transfer tubes are disposed on the end plates in such a manner as to cover both ends of the tubes so as to communicate with the tubes. The heat medium supplied through the heat medium supply port is discharged through the internal passages of the tubes, Distribution headers; And
And a header attaching / detaching mechanism for attaching / detaching the distribution headers to / from the end plates. The method according to claim 1,
Further comprising an exhaust-side heat exchanger disposed on the side of the exhaust port for heat-exchanging the internal air delivered by the blower with the internal heat medium. delete delete

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