JP2016080312A - cooling tower - Google Patents

Abstract

PROBLEM TO BE SOLVED: To increase a surface area of an eliminator in a cooling tower.SOLUTION: A cooling tower includes a tower body having a framework, an air intake port formed on a side face, an exhaust port formed on a top face, and a gas-liquid contact region positioned on a cooling air flow channel from the air intake port to the exhaust port, a filler material disposed on the gas-liquid contact region, a fan disposed on the exhaust port, a water spray nozzle disposed on an upper part of the gas-liquid contact region, a lower water tank disposed at a lower part of the gas-liquid contact region, and an eliminator disposed on the cooling air flow channel from the gas-liquid contact region to the exhaust port, and having the bellows shape including at least two trough-folded portions and at least one crest-folded portion and formed by repeating the trough-folded portions and the crest-folded portions in a horizontal direction.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a cooling tower that cools hot water by exchanging heat with cooling air.

  Conventionally, a cooling tower is used to cool warm circulating water (hot water) discharged from a cooler provided in a factory facility, a building air conditioner, or the like. There are two types of cooling towers: a “cross flow method” in which the flow of hot water and the flow of cooling air are orthogonal to each other, and a “counter flow method” in which the flow of hot water and cooling air are opposed to each other.

  The cross-flow type cooling tower is, for example, a fan provided at the top of the tower, a hot water tank provided at the top of the tower, a cold water tank provided at the bottom of the tower, and between the upper and lower sides of the hot water tank and the cold water tank. And a eliminator provided on the center side of the tower of the filler (see Patent Document 1). And by operation | movement of a cooling fan, while supplying cooling air to the center part of a tower through a filler and an eliminator from the side part of a tower, warm water is sprinkled from a warm water tank to a filler. In this manner, the hot water is cooled by the contact between the hot water flowing through the filler from the upper side to the lower side and the cooling air. The cooled water is collected in a cold water tank.

  In the cooling tower as described above, the eliminator functions as a baffle plate (filter) for preventing the hot water from being scattered from the fan to the outside of the tower accompanying the cooling air. Conventionally, the eliminator has been arranged along the center side of the tower of the packing material, but there has been a concern that the floating efficiency in the warm water will adhere to the eliminator and the ventilation efficiency will deteriorate and the heat exchange efficiency will decrease. . In view of this, the applicants of the present application proposed a cooling tower according to the prior art that includes a groove-shaped eliminator spanned between the upper ends of a pair of left and right fillers (see Patent Document 1).

JP 2012-163266 A

  The groove-shaped eliminator of the cooling tower according to the prior art has a groove shape having left and right groove side portions inclined to the vertical and horizontal groove bottom portions. Since there is a space between the groove sides on the left and right sides of this eliminator and the filler, it is possible to delay the time until the eliminator is clogged with deposits, and the eliminator can be attached and detached using this space. The maintenance work of the eliminator and the filler can be performed without doing. However, on the other hand, in order to secure this space, the surface area of the eliminator is limited.

  The present invention has been made in view of the above circumstances, and an object thereof is to alleviate at least one of the problems of the cooling tower according to the prior art.

The cooling tower according to one embodiment of the present invention is
A tower body having a framework, an air intake opening on a side surface, an exhaust opening opened on an upper surface, and a gas-liquid contact region located on a flow path of cooling air from the air intake port to the exhaust port;
A filler disposed in the gas-liquid contact area;
A fan provided at the exhaust port;
A watering nozzle provided above the gas-liquid contact area;
A lower water tank provided below the gas-liquid contact area;
Provided on the flow path of the cooling air from the gas-liquid contact area to the exhaust port, including at least two valley folds and at least one mountain fold, and the valley fold and the mountain fold are horizontal. And an eliminator having a bellows shape repeated in the direction.

  In the cooling tower having the above configuration, since the eliminator has a bellows shape, the surface area of the eliminator can be increased as compared with the cooling tower according to the prior art provided with the groove-like eliminator. By increasing the surface area of the eliminator, the flow rate of the cooling air passing through the eliminator is reduced. Thereby, for example, the pressure loss due to the cooling air can be reduced, and when the deposits are mixed in the cooling air, the time taken for the eliminator to be blocked by the deposits can be delayed. In the above and the following, the “surface area of the eliminator” refers to the total area of the eliminator flow path inlet (or outlet, or inlet and outlet).

  In the cooling tower, it is preferable that the eliminator is connected to the frame at least in the mountain fold portion and the valley fold portion.

  In the cooling tower configured as described above, the eliminator has a bellows shape, and the eliminator is connected to the framework at the valley fold and the mountain fold, so the prior art includes an eliminator installed to form a groove shape. Compared with the cooling tower which concerns on this, the buckling strength of an eliminator can be raised. Accordingly, the deposit adheres with use, and the weight of the eliminator increases due to the deposit, whereby the eliminator can be prevented from buckling when the vertical load applied to the eliminator increases.

  In the cooling tower, the eliminator is composed of a plurality of eliminator blocks arranged in a horizontal direction, and the lower ends of the adjacent eliminator blocks are abutted so as to form the valley fold, and the upper ends of the adjacent eliminator blocks are May be abutted so as to form the mountain-folded portion. Here, the plurality of eliminator blocks include a pair of side blocks positioned at both ends of the eliminator, and a plurality of intermediate blocks positioned between the pair of side blocks, each of the pair of side blocks being It is desirable that the panel has a main surface that is inclined from the horizontal by a predetermined first angle so that one end approaches the gas-liquid contact region and the other end leaves the gas-liquid contact region. The first angle is preferably in the range of more than 30 ° and less than 90 °.

  According to the above configuration, the eliminator block is inclined so that one end of the eliminator block is separated from the gas-liquid contact area (filler), so there is a space between the eliminator and the gas-liquid contact area (filler). The eliminator can be maintained. Also, in the space between the gas-liquid contact area and the eliminator, part of the adhering material accompanying the cooling air from the gas-liquid contacting area falls by its own weight before reaching the eliminator, so that the adhering substance adhering to the eliminator The amount of can be reduced. Therefore, the time until the eliminator is blocked by the deposit can be delayed.

  In the cooling tower, each of the plurality of intermediate blocks may have a panel shape having a main surface inclined from the horizontal by a predetermined second angle. The second angle is preferably an angle in a range of 30 ° to 90 °.

  According to the said structure, the buckling strength of an eliminator can be raised compared with the cooling tower based on the prior art provided with the groove-shaped eliminator.

  In the cooling tower, the frame includes a first beam member and a second beam member positioned below the first beam member, and upper ends of the plurality of eliminator blocks are connected to the first beam member. The lower ends of the plurality of eliminator blocks may be connected to the second beam member. Here, the first beam member and the second beam member may be adjacent to each other in the vertical direction, and at least one or more other beam members exist between the first beam member and the second beam member. May be.

  Alternatively, in the cooling tower, the frame includes a first beam member, a second beam member positioned below the first beam member, and a third beam member positioned below the second beam member. The upper ends of a pair of eliminator blocks located at both ends of the eliminator among the plurality of eliminator blocks are connected to the first beam member, and the upper ends of the other eliminator blocks are the first eliminator blocks. Two beam members may be connected, and lower ends of the plurality of eliminator blocks may be connected to the third beam member. In this case, in order to eliminate interference between the second beam member and the eliminator block whose upper end is connected to the first beam member and whose lower end is connected to the third member, for example, the second beam member is inserted into the eliminator block. Or an eliminator may be divided up and down via the second beam member, and the divided ends may be connected to the second beam member, respectively.

  According to the said structure, compared with the cooling tower which concerns on the prior art provided with the groove-shaped eliminator, it can implement | achieve that the surface area of an eliminator is increased and the buckling strength of an eliminator is raised.

  The said cooling tower WHEREIN: The corridor may be provided in the said trough part of the said eliminator.

  According to the above configuration, the eliminator can be maintained using the walkway.

  According to the present invention, the surface area of the eliminator of the cooling tower can be increased as compared with the cooling tower according to the prior art provided with the eliminator installed so as to form a groove shape.

FIG. 1 is a diagram showing an overall configuration of a cross-flow type cooling tower according to a first embodiment of the present invention. FIG. 2 is an enlarged view of the eliminator and its vicinity. FIG. 3 is an enlarged view of part III of FIG. FIG. 4 is an enlarged view of a portion IV in FIG. FIG. 5 is an enlarged view of a portion V in FIG. FIG. 6 is a diagram showing an overall configuration of a counter flow type cooling tower according to a second embodiment of the present invention. FIG. 7 is a diagram for explaining a modification of the eliminator, FIG. 7 (a) is a diagram showing an eliminator according to modification 1, FIG. 7 (b) is a diagram showing an eliminator according to modification 2, and FIG. ) Is a diagram showing an eliminator according to Modification 3, FIG. 7D is a diagram showing an eliminator according to Modification 4, and FIG. 7E is a diagram showing an eliminator according to Modification 5.

  Embodiments of the present invention will be described below with reference to the drawings. Here, the cooling tower according to the first embodiment of the present invention in which the cooling tower according to the present invention is applied to a cross-flow cooling tower, and the cooling tower according to the present invention is applied to a counter-flow cooling tower. Each of the cooling towers according to the second embodiment of the present invention will be described.

[First Embodiment]
FIG. 1 is a diagram showing an overall configuration of a crossflow type cooling tower 1A according to a first embodiment of the present invention, and FIG. 2 is an enlarged view of an eliminator and its vicinity. As shown in FIGS. 1 and 2, the cooling tower 1A according to the first embodiment includes a tower body 2 that forms an outer shell of the cooling tower 1A. The tower body 2 includes a skeleton 20, an air intake port 25 opened on the side surface, an exhaust port 29 opened on the upper surface, and a gas-liquid contact region 30 located on the cooling air flow path from the air intake port 25 to the exhaust port 29. Etc. The cooling tower 1A includes a filler 4 disposed in the gas-liquid contact area 30, a fan 3 provided in the exhaust port 29, a water spray nozzle 17 provided above the gas-liquid contact area 30, and a gas-liquid A lower water tank 13 provided below the contact area 30 and an eliminator 5 provided on the cooling air flow path from the gas-liquid contact area 30 to the exhaust port 29 are further provided.

  The frame 20 of the tower body 2 is configured by assembling a plurality of column members 21, a plurality of beam members 22, a plurality of brace members 23, and the like. A walkway 27 used for inspection and maintenance is provided below the framework 20.

  The tower body 2 has four side surfaces, and an air inlet 25 is provided on each of the pair of side surfaces facing the first horizontal direction (the left-right direction in FIG. 1) among the four side surfaces. Of the four side surfaces of the tower body 2, the remaining two side surfaces are covered with an exterior plate (not shown). In the following, for convenience of explanation, the first direction is the left-right direction, and the horizontal second direction orthogonal to the first direction is the front-back direction.

  On the left and right side surfaces of the tower body 2, a plurality of louvers 24 are arranged in the vertical direction for guiding the outside air introduced into the tower from the air intake 25. In the tower of the tower body 2, left and right gas-liquid contact areas 30 are provided with the ventilation space 28 interposed therebetween. The filler 4 is disposed in these gas-liquid contact regions 30.

  There are various types of fillers 4 such as a film mold and a splash mold, and a filler of a type corresponding to the SS concentration (floating matter concentration) in warm water is employed. The filler 4 according to the present embodiment is formed by a plurality of splash-type filler units 40 arranged in the vertical direction, and the sprinkled hot water is scattered into small-diameter particles by the filler 4, thereby Contact with air can be increased.

  An exhaust port 29 is provided above the ventilation space 28 and in the center of the top of the tower body 2. The exhaust port 29 is provided with a fan 3 for discharging the air in the tower to the outside. The blades of the fan 3 are housed in a fan stack 31 provided at the top of the tower body 2. A motor 32, which is a driving device for the fan 3, is installed at the top of the tower body 2, and power is transmitted from the motor 32 to the fan 3 through a transmission shaft 33 and a speed reducer 34.

  An upper water tank 12 is provided at the top of the tower body 2, and hot water is supplied to the upper water tank 12 from a hot water supply pipe 16. A large number of watering nozzles 17 are provided on the bottom surface of the upper water tank 12, and hot water stored in the upper water tank 12 is sprinkled through the filler 4 through the watering nozzles 17. The hot water flows downward through the filler 4 and flows into a lower water tank 13 provided at the lower part or the lower part of the tower body 2.

  When the fan 3 is driven in the cooling tower 1 </ b> A configured as described above, air outside the tower is introduced as cooling air from the air intake 25 into the tower body 2, and this cooling air is used as the filler 4 in the gas-liquid contact region 30. It flows to the ventilation space 28 through. The cooling air passing through the filler 4 in the left-right direction comes into contact with the hot water flowing down the filler 4 and exchanges heat with the hot water. Thereby, the hot water is cooled by the cooling air and becomes cold water and flows into the lower water tank 13. The cold water stored in the lower water tank 13 is sent, for example, to a cooler of various facilities by a pump or a pipe (not shown) and used again as a refrigerant there.

  The cooling air after passing through the filler 4 is discharged from the ventilation space 28 to the outside of the tower body 2 through the fan 3. Here, in order to prevent the hot water from being discharged out of the tower body 2 along with the flow of the cooling air, between the gas-liquid contact region 30 and the exhaust port 29 in the flow path of the cooling air in the tower body 2. An eliminator 5 is provided. When the cooling air passes through the eliminator 5, the gas can pass through the eliminator 5, but water droplets accompanying the gas collide with the walls of the flow path of the eliminator 5 and are captured. In this way, the cooling air is discharged from the tower body 2 after moisture is removed by the eliminator 5. Since suspended matters contained in the water droplets captured by the eliminator 5 adhere to the eliminator 5 and block the flow path, periodic maintenance of the eliminator 5 is performed in order to remove the adhering substances.

  Here, the installation structure of the eliminator 5 in the cooling tower 1A will be described. When viewed from the front-rear direction, the eliminator 5 according to the present embodiment includes at least two valley folds V and at least one mountain fold M, and the valley fold V and the mountain fold M are in the left-right direction. It has a bellows shape repeated 1.5 times or more. In other words, the eliminator 5 has a shape in which a plurality of V-shaped portions are continuous in the left-right direction when viewed from the front-rear direction. In the above description, “the bellows shape in which the valley fold portion V and the mountain fold portion M are repeated 1.5 times in the left-right direction” means that the valley fold portion V, the mountain fold portion M, and the valley fold portion V are sequentially left and right. Refers to the bellows shape lined up. Further, for example, “the bellows shape in which the valley fold portion V and the mountain fold portion M are repeated 2.5 times in the left-right direction” means the valley fold portion V, the mountain fold portion M, the valley fold portion V, and the mountain fold portion M. -It points out the bellows shape where the trough part V was located in order in the left-right direction.

  The eliminator 5 according to the present embodiment has a W shape in which two V-shapes are arranged in the left-right direction, and has an accordion shape including two valley fold portions V and one mountain fold portion M as a whole. doing. The eliminator 5 is connected to the skeleton 20 at least at the mountain fold portion M and the valley fold portion V at the left and right ends in the present embodiment.

  The eliminator 5 is composed of a plurality of eliminator blocks 50 arranged in the left-right direction. Each eliminator block 50 is formed in a panel shape having two main surfaces, a surface where the inlet of the flow channel is opened and a surface where the outlet of the flow channel is opened, and a flow channel penetrating the two main surfaces is formed. Has been. The eliminator block 50 can be composed of, for example, a large number of zigzag flow path forming plates arranged at predetermined intervals and a connector that holds the large number of flow path forming plates. The flow path of the eliminator block 50 has a labyrinth structure that is bent so that gas passes but liquid contacts the wall surface of the flow path.

  The lower ends of the eliminator blocks 50 adjacent to the left and right are butted so as to form a valley fold V of the eliminator 5. Further, the upper ends of the eliminator blocks 50 adjacent to the left and right are abutted so as to form a mountain-folded portion M of the eliminator 5. The upper end of each eliminator block 50 is directly or indirectly connected to the ceiling beam 221 (first beam member) among the plurality of beam members 22 constituting the framework 20. Further, the lower end of each eliminator block 50 is directly or indirectly connected to a first intermediate beam 222 (second beam member) that is a beam member 22 provided immediately below the ceiling beam 221.

  Here, a connection structure between the eliminator block 50 and the skeleton 20 will be described. Hereinafter, the pair of eliminator blocks 50 located at the left and right ends of the eliminator 5 may be referred to as side blocks 50S, and the plurality of eliminator blocks 50 located between the pair of side blocks 50S in the left-right direction are referred to as intermediate blocks 50C. There is something to say.

  FIG. 3 is an enlarged view of a part III in FIG. 2 and shows a connecting portion between the skeleton 20 and the upper end 50a of the eliminator block 50 (side block 50S). As shown in FIG. 3, the end frame 7 is connected to the ceiling beam 221, and the upper end of the eliminator block 50 is held by the end frame 7, whereby the ceiling beam 221 and the eliminator block 50 are indirectly connected. Yes. More specifically, the gusset plate 61 is fixed to the ceiling beam 221, and the upper end of the column member 21 is connected to the gusset plate 61. The end frame 7 is connected to the column member 21 via a gusset plate 63, and the end frame 7 is connected to the gusset plate 61 via a gusset plate 64. Here, the gusset plate 63 is fixed to the end frame 7 and the column member 21 (frame 20) by fastening or welding. The gusset plate 64 is fixed to the gusset plate 61 and the end frame 7 by fastening or welding. In order to support the eliminator block 50 extending in the front-rear direction with a good balance, a plurality of end frames 7 are distributed in the front-rear direction for each eliminator block 50.

  The end frame 7 is a member having a channel-like or groove-like cross-sectional shape and extending in the front-rear direction. The end frame 7 according to the present embodiment includes a base portion 71 that faces the peripheral surface of the eliminator block 50, an upper wall portion 72 that faces the upward main surface of the eliminator block 50, and a downward main surface of the eliminator block 50. It generally has a lower wall portion 73 that abuts. The eliminator block 50 is held by the end frame 7 by fitting the upper end portion 50 a of the eliminator block 50 between the upper wall portion 72 and the lower wall portion 73 of the end frame 7. In order to make it easier to fit the eliminator block 50 into the end frame 7, the length from the base portion to the tip portion of the upper wall portion 72 is shorter than the length from the base portion to the tip portion of the lower wall portion 73. Yes.

  FIG. 4 is an enlarged view of a part IV in FIG. 2, and shows a connecting portion between the upper end portion 50 a of the two eliminator blocks 50 (intermediate block 50 C) butted and the skeleton 20. As shown in FIG. 4, the end frame 7 is connected to the ceiling beam 221, and the upper end of the eliminator block 50 is held by the end frame 7, whereby the ceiling beam 221 and the eliminator block 50 are indirectly connected. Yes. More specifically, a gusset plate 65 is fixed to the ceiling beam 221, and the upper ends of the two brace members 23 are connected to the gusset plate 65. The two end frames 7 are fixed to the frame 20 so as to straddle the two brace members 23. One of the two end frames 7 is connected to one of the two brace members 23 via a gusset plate 66, and the other of the two end frames 7 is connected to the other of the two brace members 23. They are connected via a plate 66. Further, the two end frames 7 are connected by a connecting plate 67 straddling them. Here, the gusset plate 66 is fixed to the end frame 7 and the brace member 23 (frame 20) by fastening or welding. The connecting plate 67 is fixed to each of the two end frames 7 by fastening or welding.

  FIG. 5 is an enlarged view of a portion V of FIG. 2, and shows a connecting portion between the lower end portion 50 b and the framework 20 of two eliminator blocks 50 (side block 50 S and intermediate block 50 C, or intermediate blocks 50 C) that are abutted. Show. As shown in FIG. 5, two end frames 7 are connected to the first intermediate beam 222, and the lower ends of the eliminator blocks 50 are held by these end frames 7, so that the first intermediate beam 222 and the eliminator block 50 are Are indirectly linked. More specifically, each end frame 7 is connected to the first intermediate beam 222 via the gusset plate 68, and the two end frames 7 are connected by a connecting plate 69 straddling them. Here, the gusset plate 68 is fixed to the end frame 7 and the first intermediate beam 222 (frame 20) by fastening or welding. The connecting plate 69 is fixed to each of the two end frames 7 by fastening or welding.

  In the eliminator 5 connected to the skeleton 20 as described above, as shown in FIGS. 1, 2, and 5, the main surface of the side block 50 </ b> S approaches the gas-liquid contact region 30 at the upper end and the gas-liquid contact region at the lower end. It is inclined from the horizontal by a predetermined angle θ 1 so as to be away from 30. Further, the main surface of the intermediate block 50C is inclined from the horizontal by a predetermined angle θ2.

  The inclination angle θ1 of the side block 50S and the inclination angle θ2 of the intermediate block 50C may be the same or different, and are designed according to the size of the width in the left-right direction of the area where the eliminator 5 is installed. However, it is desirable that the tilt angle θ1 is not less than 30 ° and less than 90 °, and the tilt angle θ2 is not less than 30 ° and not more than 90 °. When the inclination angle θ1 and the inclination angle θ2 are less than 30 °, the attached material adheres to the eliminator block 50 and the weight of the eliminator block 50 increases with use, and the eliminator block 50 may be bent downward. Further, when the inclination angle θ1 is 90 ° or more, a space cannot be provided between the filler 4 and the side block 50S. In addition, when the tilt angle θ2 exceeds 90 °, the cooling air rising up the tower body 2 may double pass through the eliminator 5 and increase the flow resistance. That is, in order to ensure the buckling strength of the eliminator 5, the angle θ1 and the inclination angle θ2 are values included in the above range. In order to further increase the buckling strength of the eliminator 5, a support rod 51 that supports each eliminator block 50 from below may be provided on the framework 20.

  As described above, in the present embodiment, the end frame 7 is fixed to the skeleton 20 by a gusset plate or the like at each connection point between the upper end and the lower end of the eliminator block 50 and the skeleton 20, and the eliminator block 50 is attached to the end frame 7. The end is held. Providing the end frame 7 between the skeleton 20 and the eliminator block 50 in this manner is desirable because the eliminator block 50 can be easily attached and detached. However, the end of the eliminator block 50 may be directly connected to the framework 20 by a gusset plate or the like without using the end frame 7.

  Moreover, in this embodiment, the air attracted | sucked from the outside bypasses the eliminator 5 by providing a gusset plate in the connection location of the eliminator block 50 and the skeleton 20, and the connection location of the eliminator blocks 50, respectively. (Ie, without passing through the eliminator 5) to prevent the air from flowing to the exhaust port 29. However, instead of the metal plate-like gusset plate, a film or other airtight member may be used.

[Second Embodiment]
Next, a second embodiment will be described. FIG. 6 is a diagram showing an overall configuration of a counterflow type cooling tower 1B according to the second embodiment of the present invention. In the description of the present embodiment, the same or similar members as those of the above-described embodiment may be denoted by the same reference numerals in the drawings, and description thereof may be omitted.

  As shown in FIG. 6, the cooling tower 1B according to the second embodiment includes a tower body 2 that forms an outer shell of the cooling tower 1B. The tower body 2 includes a skeleton 20, an air intake port 25 opened on the side surface, an exhaust port 29 opened on the upper surface, and a gas-liquid contact region 30 located on the cooling air flow path from the air intake port 25 to the exhaust port 29. Etc. The cooling tower 1B includes a filler 4 arranged in the gas-liquid contact area 30, a fan 3 provided in the exhaust port 29, a water spray nozzle 17 provided above the gas-liquid contact area 30, and a gas-liquid A lower water tank 13 provided below the contact area 30 and an eliminator 5 provided on the cooling air flow path from the gas-liquid contact area 30 to the exhaust port 29 are further provided.

  The frame 20 of the tower body 2 is configured by assembling a plurality of column members 21 and a plurality of beam members 22. The tower body 2 has four side surfaces, and an air intake 25 is provided at the lower part of a pair of side surfaces facing the first horizontal direction (left and right direction in FIG. 6) among the four side surfaces. Of the four side surfaces of the tower body 2, the remaining two side surfaces are covered with an exterior plate (not shown). In the following, for convenience of explanation, the first direction is the left-right direction, and the horizontal second direction orthogonal to the first direction is the front-back direction.

  On the left and right side surfaces of the tower body 2, a plurality of louvers 24 are arranged in the vertical direction for guiding the outside air introduced into the tower from the air intake 25. In the tower of the tower main body 2, a gas-liquid contact region 30 is provided in the upper and lower central part and above the air intake 25. These gas-liquid contact regions 30 are filled with the filler 4.

  Above the gas-liquid contact area 30, a water spray pipe 18 to which hot water is supplied is provided, and a plurality of water spray nozzles 17 are connected to the water spray pipe 18. The hot water sent to the water spray pipe 18 through the water spray nozzle 17 is sprinkled on the filler 4. The hot water flows downward through the filler 4 and flows into a lower water tank 13 provided at the lower part or the lower part of the tower body 2.

  An exhaust port 29 is provided at the center of the top of the tower body 2. The exhaust port 29 is provided with a fan 3 for discharging the air in the tower to the outside. A motor 32, which is a driving device for the fan 3, is installed at the top of the tower body 2, and power is transmitted from the motor 32 to the fan 3 through a transmission shaft 33 and a speed reducer 34.

  In the cooling tower 1B configured as described above, when the fan 3 is driven, air outside the tower is introduced into the tower body 2 from the air intake 25 as cooling air, and this cooling air is used as the filler 4 in the gas-liquid contact region 30. Pass from bottom to top. The cooling air passing through the filler 4 from the bottom to the top contacts the warm water flowing down the filler 4 and exchanges heat with the warm water. Thereby, the hot water is cooled by the cooling air and becomes cold water and flows into the lower water tank 13.

  The cooling air after passing through the filler 4 is discharged out of the tower body 2 through the fan 3. Here, in order to prevent the hot water from being discharged out of the tower body 2 along with the flow of the cooling air, between the gas-liquid contact region 30 and the exhaust port 29 in the flow path of the cooling air in the tower body 2. An eliminator 5 is provided. When the cooling air passes through the eliminator 5, the gas can pass through the eliminator 5, but water droplets accompanying the gas collide with the walls of the flow path of the eliminator 5 and are captured.

  Here, the installation structure of the eliminator 5 in the cooling tower 1B will be described. When viewed from the front-rear direction, the eliminator 5 according to the present embodiment includes at least two valley folds V and at least one mountain fold M, and the valley fold V and the mountain fold M are in the left-right direction. It has a bellows shape repeated 1.5 times or more. In other words, the eliminator 5 has a shape in which a plurality of V-shaped portions are continuous in the left-right direction when viewed from the front-rear direction. The eliminator 5 is connected to the skeleton 20 at least at the mountain fold portion M and the valley fold portion V at the left and right ends in the present embodiment.

  The eliminator 5 is composed of a plurality of eliminator blocks 50 arranged in the left-right direction. The lower ends of the eliminator blocks 50 adjacent to the left and right are butted so as to form a valley fold V of the eliminator 5. Further, the upper ends of the eliminator blocks 50 adjacent to the left and right are abutted so as to form a mountain-folded portion M of the eliminator 5. The upper end of each eliminator block 50 is connected to a beam member 225 located above the water spray pipe 18 among the plurality of beam members 22 constituting the framework 20. Further, the lower end of each eliminator block 50 is connected to a beam member 226 that is located above the sprinkling pipe 18 and is provided immediately below the beam member 225 described above. Since the connection structure between the eliminator block 50 and the skeleton 20 is the same as that in the first embodiment, the description thereof is omitted.

  As described above, in the cooling towers 1A and 1B according to the first and second embodiments, the eliminator 5 includes at least two valley folds V and at least one mountain folds M, and the valley folds V and It has a bellows shape in which the mountain folds M are repeated in the horizontal direction. Thereby, the surface area of the eliminator 5 can be increased as compared with the cooling tower according to the prior art including the eliminator installed so as to form a groove shape. Further, the surface area of the eliminator 5 can be adjusted by increasing or decreasing the number of times the valley fold portion V and the mountain fold portion M are repeated, or by changing the joining angle of the valley fold portion V or the mountain fold portion M. It is.

  And in cooling tower 1A, 1B which concerns on 1st and 2nd embodiment, the flow velocity of the cooling air which passes the eliminator 5 reduces by the increase in the surface area of the eliminator 5, compared with the cooling tower which concerns on a prior art. Since the pressure loss is proportional to the square of the flow velocity, the pressure loss of the cooling air can be reduced by reducing the flow velocity of the cooling air. Therefore, it can contribute to energy saving. In addition, when deposits are mixed in the cooling air from the gas-liquid contact region 30, part of the deposits accompanying the cooling air reaches the eliminator 5 in the space between the gas-liquid contact region 30 and the eliminator 5. Since it falls by its own weight before it is done, the amount of deposits adhering to the eliminator 5 can be reduced. The amount of deposits falling in the space can be expected to increase as the distance from the gas-liquid contact region 30 to the eliminator 5 increases. Therefore, the time taken for the eliminator 5 to be blocked by the deposit can be delayed.

  In the cooling towers 1 </ b> A and 1 </ b> B according to the first and second embodiments, the eliminator 5 is connected to the framework 20 at least in the mountain fold part M and the valley fold part V. Thereby, compared with the cooling tower which concerns on the prior art provided with the eliminator installed so that it may form groove shape, the buckling strength of the eliminator 5 can be raised. Therefore, it is possible to prevent the eliminator 5 from buckling when the weight in the vertical direction applied to the eliminator 5 increases due to an increase in the weight of the eliminator 5 due to the deposit.

  In the cooling towers 1A and 1B according to the first and second embodiments, the eliminator 5 is composed of a plurality of eliminator blocks 50 arranged in the horizontal direction, and the lower ends of the adjacent eliminator blocks 50 form a valley fold V. The upper ends of the adjacent eliminator blocks 50 are abutted so as to form a mountain-folded portion M.

  In the above, the plurality of eliminator blocks 50 include a pair of side blocks 50S located at both ends of the eliminator 5, and a plurality of intermediate blocks 50C located between the pair of side blocks 50S. Each of the pair of side blocks 50S has a panel shape having a main surface inclined from the horizontal by a predetermined first angle θ1 so that one end approaches the gas-liquid contact region 30 and the other end separates from the gas-liquid contact region 30. is there. The first angle θ1 is an angle in a range larger than 30 ° and smaller than 90 °.

  Since the side block 50S installed as described above is away from the gas-liquid contact region 30, it is possible to delay the time until the flow path of the eliminator 5 is clogged with deposits, and lengthen the maintenance cycle. it can. In particular, in the cooling tower 1A according to the first embodiment, a space exists between the side block 50S and the gas-liquid contact region 30, and the eliminator block 50 is not detached from the end frame 7 using this space. Can be maintained.

  In the cooling towers 1A and 1B according to the first and second embodiments, each of the plurality of intermediate blocks 50C has a panel shape having a main surface inclined from the horizontal by a predetermined second angle θ2. And 2nd angle (theta) 2 is an angle of the range of 30 degrees or more and 90 degrees or less. Thereby, the buckling intensity | strength of the eliminator 5 can be raised compared with the cooling tower which concerns on the prior art provided with the groove-shaped eliminator.

[Modification]
The preferred embodiments of the present invention (the first embodiment and the second embodiment) have been described above. However, the installation mode of the eliminator 5 in the above-described embodiment can be changed as follows, for example. In each of FIGS. 7A to 7D, modifications of the installation mode of the eliminator 5 are shown. In the description of these modified examples, the same or similar members as those in the above-described embodiment may be denoted by the same reference numerals in the drawings, and description thereof may be omitted. Further, although not particularly shown or described in these modifications, the end portions of the eliminator blocks 50 constituting the eliminator 5 are directly or indirectly connected to the skeleton 20 as in the above-described embodiment. .

  FIG. 7A shows a schematic configuration viewed from the front of the eliminator 5A according to the first modification. The eliminator 5A according to Modification 1 has a bellows shape in which three V-shaped portions are continuous in the left-right direction. Specifically, the eliminator 5A according to the modified example 1 includes left and right side blocks 50S and four intermediate blocks 50C arranged therebetween, and as a whole, three valley folds V and two peaks It has a bent part M.

  The eliminator 5 is not limited to the above-described embodiment and its modifications, and the eliminator 5 has a bellows shape in which the valley fold portion V and the mountain fold portion M are repeated 1.5 times or more in the horizontal direction, and has at least two valley fold portions. V and at least one mountain fold part M should just be included. In other words, the eliminator 5 may have more than two V-shaped repetitions as long as the eliminator 5 has a bellows shape in which at least two V-shaped portions are connected in the horizontal direction. In this way, it is possible to increase the surface area of the eliminator 5 and increase the buckling strength of the eliminator 5 as compared with the cooling tower according to the prior art provided with the groove-shaped eliminator.

  The number of valley folds V and mountain folds M included in the eliminator 5 (that is, the number of repetitions of the V-shape) is the size of the space in which the eliminator 5 is installed and the fan 3 arranged above the eliminator 5. It is desirable to be determined according to the number. For example, the number and positions of the valley folds V of the eliminator 5 may be determined so that the valley folds V of the eliminator 5 are arranged below the fans 3 included in the cooling towers 1A and 1B.

  FIG. 7B shows a schematic configuration viewed from the front of the eliminator 5B according to the second modification. An eliminator 5B according to Modification 2 has a bilaterally asymmetric bellows shape in which two V-shaped portions are continuous in the left-right direction. In the eliminator 5B according to the modification 2, the lengths of the two intermediate blocks 50C included in the eliminator 5 are different. Therefore, when the eliminator 5B is viewed from the front, the angle of the V-shaped valley formed by the right side block 50S and the intermediate block 50C adjacent thereto, and the left side block 50S and the intermediate block 50C adjacent thereto are determined. The angle of the V-shaped valley formed is different. According to the eliminator 5B according to the modification example 2, the length of each intermediate block 50C can be adjusted to adapt the size of the space in which the eliminator 5B is installed.

  FIG. 7C shows a schematic configuration viewed from the front of the eliminator 5C according to Modification 3. The eliminator 5C according to the modified example 3 has a bellows shape in which two V-shaped portions are continuous in the left-right direction, and a corridor 56 is provided at each valley folding portion V. Specifically, in the eliminator 5C according to the modified example 3, the walkway 56 is formed by connecting the lower end of the side block 50S and the lower end of the intermediate block 50C substantially horizontally with a steel plate or a frame. Has been. According to the eliminator 5C according to the third modification, the eliminator 5 can be maintained using the walkway 56.

  FIG. 7D shows a schematic configuration viewed from the front of the eliminator 5D according to Modification 4. The eliminator 5D according to the modified example 4 has a bellows shape in which two V-shapes straddling the three beam members 22 are connected in the left-right direction. Specifically, the upper end of the side block 50S is connected directly or indirectly to the ceiling beam 221 (first beam member) or the frame 20 in the vicinity thereof, and the lower end of the side block 50S is connected to the first intermediate beam 222 (second The second intermediate beam 223 (third beam member), which is the beam member 22 provided immediately below the beam member), is directly or indirectly connected. At the intersection of the side block 50S and the first intermediate beam 222, an opening through which the first intermediate beam 222 passes is formed in the side block 50S, and the first intermediate beam 222 passes through the side block 50S. . Further, in the eliminator 5D according to the modified example 4, the lower end of the intermediate block 50C is directly or indirectly connected to the second intermediate beam 223, and the upper end of the intermediate block 50C is directly or indirectly connected to the first intermediate beam 222. It is connected. According to the eliminator 5D according to the modification 4, the surface area of the eliminator 5 can be further increased. In the eliminator 5D according to the fourth modification, the first intermediate beam 222 passes through the side block 50S. However, the side block 50S is divided into an upper member and a lower member at a location where the first intermediate beam 222 intersects. The lower end of the upper member and the upper end of the lower member may be connected to the first intermediate beam 222, respectively.

  FIG. 7E shows a schematic configuration viewed from the front of the eliminator 5E according to Modification 5. In the eliminator 5 according to the above-described embodiment, the upper end of each eliminator block 50 is connected to the ceiling beam 221, and the lower end of the eliminator block 50 is connected to the first intermediate beam 222 that is a beam member immediately below the ceiling beam 221. Has been. However, at least one beam member may exist between the upper end and the lower end of the eliminator block 50. For example, in the eliminator 5E according to the modified example 5, the upper end of each eliminator block 50 is connected to the ceiling beam 221 and the lower end of each eliminator block 50 is provided immediately below the first intermediate beam 222. 223. That is, the eliminator 5E according to the modified example 5 has a W-shape straddling up and down three or more beam members when viewed from the front. An opening for avoiding interference is formed in a portion of each eliminator block 50 that intersects the first intermediate beam 222, and the first intermediate beam 222 is inserted through this opening. However, each eliminator block 50 is divided into an upper member and a lower member at a portion intersecting the first intermediate beam 222, and the lower end of the upper member and the upper end of the lower member are connected to the first intermediate beam 222, respectively. May be.

1A, 1B Cooling tower 2 Tower body 3 Fan 31 Fan stack 32 Motor 33 Transmission shaft 34 Reducer 4 Filler 40 Filler unit 5, 5A, 5B, 5C, 5D Eliminator 50 Eliminator block 50C Intermediate block 50S Side block 7 End frame 71 Base portion 72 Upper wall portion 73 Lower wall portion 12 Upper water tank 13 Lower water tank 16 Hot water supply pipe 17 Water spray nozzle 20 Frame 21 Column member 22 Beam member 221 Ceiling beam 222 First intermediate beam 223 Second intermediate beam 23 Brace member 24 Louver 25 Air intake 28 Ventilation space 30 Gas-liquid contact area 27, 56 Walkway 61, 63, 64, 65, 66, 68 Gusset plate 67, 69 Connection plate

Claims (10)

A tower body having a framework, an air intake opening on a side surface, an exhaust opening opened on an upper surface, and a gas-liquid contact region located on a flow path of cooling air from the air intake port to the exhaust port;
A filler disposed in the gas-liquid contact area;
A fan provided at the exhaust port;
A watering nozzle provided above the gas-liquid contact area;
A lower water tank provided below the gas-liquid contact area;
Provided on the flow path of the cooling air from the gas-liquid contact area to the exhaust port, including at least two valley folds and at least one mountain fold, and the valley fold and the mountain fold are horizontal. An eliminator having a bellows shape repeated in the direction,
Equipped with a cooling tower.   The cooling tower according to claim 1, wherein the eliminator is connected to the frame at least in the mountain fold and the valley fold.   The eliminator is composed of a plurality of eliminator blocks arranged in the horizontal direction, the lower ends of the adjacent eliminator blocks are abutted so as to form the valley fold, and the upper ends of the adjacent eliminator blocks are the mountain folds. The cooling tower according to claim 1, which is abutted so as to form The plurality of eliminator blocks include a pair of side blocks located at both ends of the eliminator, and a plurality of intermediate blocks located between the pair of side blocks,
Each of the pair of side blocks has a panel shape having a principal surface inclined from the horizontal by a predetermined first angle so that one end approaches the gas-liquid contact region and the other end separates from the gas-liquid contact region. The cooling tower according to claim 3.   The cooling tower according to claim 4, wherein the first angle is an angle in a range greater than 30 ° and less than 90 °.   The cooling tower according to claim 4 or 5, wherein each of the plurality of intermediate blocks has a panel shape having a main surface inclined from the horizontal by a predetermined second angle.   The cooling tower according to claim 6, wherein the second angle is an angle in a range of 30 ° to 90 °. The frame includes a first beam member and a second beam member positioned below the first beam member;
The upper ends of the plurality of eliminator blocks are connected to the first beam member, and the lower ends of the plurality of eliminator blocks are connected to the second beam member. Cooling tower. The frame includes a first beam member, a second beam member positioned below the first beam member, and a third beam member positioned below the second beam member;
Of the plurality of eliminator blocks, upper ends of a pair of eliminator blocks positioned at both ends of the eliminator are connected to the first beam member, and among the plurality of eliminator blocks, the upper end of the other eliminator block is the second eliminator block. The cooling tower according to any one of claims 3 to 7, wherein the cooling tower is connected to a beam member, and lower ends of the plurality of eliminator blocks are connected to the third beam member.   The cooling tower as described in any one of Claims 1-9 by which the corridor is provided in the said valley fold part of the said eliminator.

Images