CN117647150A - Low wind resistance packing module and cooling tower - Google Patents

Abstract

The invention relates to ase:Sub>A low wind resistance filler module, which is characterized by comprising rectangular filler sheets A and filler sheets B which are alternately stacked at ase:Sub>A prescribed interval to form ase:Sub>A first flow path and ase:Sub>A second flow path which are alternately arranged, wherein an upper-stage guide part and ase:Sub>A lower-stage guide part are respectively arranged at the upper section and the lower section, ase:Sub>A heat exchange part is arranged between the upper-stage guide part and the lower-stage guide part, and the low wind resistance filler module comprises ase:Sub>A first heat exchange part which is alternately stacked in the stacking direction and is formed between the filler sheets B-A and takes ase:Sub>A flat cavity; and a second heat exchange part formed between the packing sheets A-B and having a flat cavity, wherein the first flow path is used as a water spraying channel, the second flow path is used as a gas introducing channel, the upper guide part comprises a plurality of first upper end openings and second upper end openings which are arranged on the upper surface of the packing module, the first upper end openings are positioned on one side of the stacking direction and are arranged in parallel along the stacking direction and communicated with the first flow path; the second upper end opening is positioned at the other side of the stacking direction, is arranged in parallel along the stacking direction and is communicated with the second flow path, the lower section guide part comprises a plurality of first lower end openings and second lower end openings which are arranged on the lower surface of the filler module, and the first lower end openings are positioned at one side of the stacking direction, are arranged in parallel along the stacking direction and are communicated with the first flow path; the second lower end opening is located on the other side in the stacking direction, is arranged in parallel in the stacking direction, communicates with the second flow path, and the upper guide portion is provided with a first fin for guiding shower water from the first upper end opening to the first heat exchange portion having substantially the entire width of the filler module only in the first upper end opening. It further simplifies the construction, facilitates the installation, reduces the cost, and has little wind resistance for attracting cold air.

Description

Low wind resistance packing module and cooling tower

Technical Field

The invention relates to a module of a cooling tower, in particular to a filler module in the cooling tower.

Background

As a heat exchange packing sheet technology of a cooling tower, a packing module separating a downstream hot water flow path and an upstream cold air flow path is disclosed in prior patent 201910877463.9 of the applicant, which has a filing date of 2019, 7, 15. In the packing module, hot water flows in from an opening formed at a part of the width of the upper end of the packing module, and an opening through which air flows is formed at another part of the width of the upper end of the packing module. The 4 kinds of packing sheets A, B, C, D are needed for manufacturing the packing module, and the cooling effect on hot water is quite high.

In order to further simplify the construction, facilitate the installation and reduce the costs, the applicant has not stopped further development of the product.

Disclosure of Invention

The present invention has been made in view of the above-mentioned prior art, and an object of the present invention is to provide a packing sheet using the principle that can further simplify the structure, facilitate the installation, and reduce the cost without reducing the heat exchange efficiency.

The low wind resistance filler module is characterized by comprising rectangular filler pieces A and filler pieces B which are alternately stacked at ase:Sub>A prescribed interval to form ase:Sub>A first flow path and ase:Sub>A second flow path which are alternately arranged, wherein an upper guide part and ase:Sub>A lower guide part are respectively arranged at the upper section and the lower section, and ase:Sub>A heat exchange part is arranged between the upper guide part and the lower guide part, and the low wind resistance filler module comprises ase:Sub>A first heat exchange part which is alternately stacked in the stacking direction and is formed between the filler pieces B-A and has ase:Sub>A flat cavity; and a second heat exchange part formed between the packing sheets A-B and having a flat cavity, wherein the first flow path is used as a water spraying channel, the second flow path is used as a gas introducing channel, the upper guide part comprises a plurality of first upper end openings and second upper end openings which are arranged on the upper surface of the packing module, the first upper end openings are positioned on one side of the stacking direction and are arranged in parallel along the stacking direction and communicated with the first flow path; the second upper end opening is positioned at the other side of the stacking direction, is arranged in parallel along the stacking direction and is communicated with the second flow path, the lower section guide part comprises a plurality of first lower end openings and second lower end openings which are arranged on the lower surface of the filler module, and the first lower end openings are positioned at one side of the stacking direction, are arranged in parallel along the stacking direction and are communicated with the first flow path; the second lower end opening is located on the other side in the stacking direction, is arranged in parallel in the stacking direction, communicates with the second flow path, and the upper guide portion is provided with a first fin for guiding shower water from the first upper end opening to the first heat exchange portion having substantially the entire width of the filler module only in the first upper end opening.

The low wind resistance filler module of the invention is preferably characterized in that: the lower guide portion is provided with a second fin for guiding shower water from the first heat exchange portion having substantially the entire width of the packing module to the first lower opening only in the first lower opening.

The low wind resistance filler module of the invention is preferably characterized in that: the widths of the first upper end opening and the second upper end opening are approximately the same, the widths of the first lower end opening and the second lower end opening are approximately the same, and the first rectifying sheet and the second rectifying sheet are the same component.

The low wind resistance filler module of the invention is preferably characterized in that: the first upper end opening and the first lower end opening are located on the same side of the filler module, and the first fairing and the second fairing are the same component.

The low wind resistance filler module of the invention is preferably characterized in that: the first upper end opening and the first lower end opening are positioned on the same side of the packing module, and an edge sealing part is formed at the outer side edge of the packing module in the width direction of the first upper end opening.

The low wind resistance filler module of the invention is preferably characterized in that: the edge sealing portion is configured such that an upper end portion of the packing sheet a is offset rearward at a first upper end opening and is offset forward at an edge, and the packing sheet B on the front side in the stacking direction is offset forward at the first upper end opening and is gathered with the first upper end opening of the packing sheet a on the further front side and is offset rearward at an edge and gathered with an edge of the packing sheet a.

The low wind resistance filler module of the invention is preferably characterized in that: the transverse cross section of each first rectifying piece and each second rectifying piece is in a bent shape, and two sides of the bent shape are respectively abutted with the packing pieces.

The low wind resistance filler module of the invention is preferably characterized in that: and d is the distance between the packing sheet A and the packing sheet B, so that the bending amplitude of the first rectifying sheet and the second rectifying sheet at the upper end opening and the lower end opening of the first rectifying sheet and the second rectifying sheet is large, the bending span is small, and the bending amplitude is gradually reduced and the bending span is gradually increased in the process of extending towards the heat exchange part.

In addition, the present invention provides a cooling tower, characterized in that: the low wind resistance packing module as described above sprays hot water into the first flow path, flows in through the first upper end opening of a part of the packing module in the width direction, exchanges heat with cold air in the second heat exchange part of the adjacent second flow path through the packing sheet A, B in the first heat exchange part of substantially the full width, and flows out from the first lower end opening of a part of the packing module in the width direction; in the second flow path, cool air is introduced into the second heat exchange portion only from the first lower end opening of a part in the width direction, and after heat exchange is performed in the second heat exchange portion having a substantially full width, the cool air is extracted from the second upper end opening of a part in the width direction.

According to the invention, the structure of the filler module can be greatly simplified, the cost is reduced on the premise of ensuring the heat exchange efficiency, and the wind resistance for sucking cold air is extremely small.

Drawings

Fig. 1 is a structural view of a filler module according to a first embodiment of the present invention;

FIG. 2 is an exploded view of a filler module according to a first embodiment of the present invention;

fig. 3 is a perspective view of a packing sheet a in the first embodiment of the present invention;

fig. 4 is a perspective view of a packing sheet B in the first embodiment of the present invention;

fig. 5 is a perspective view of a rectifier according to a first embodiment of the invention;

fig. 6 is a perspective view of a laminated rectifying sheet on the front side of a packing sheet a in the first embodiment of the present invention;

fig. 7 is a perspective view of the filler sheet B and the rectifying sheet further laminated on the front side on the basis of fig. 6;

FIG. 8 is a top exploded view of a filler module of the first embodiment of the present invention;

fig. 9 is a top view of a packing module of a first embodiment of the present invention;

FIG. 10 is an exploded view of a filler module according to a second embodiment of the present invention;

FIG. 11 is a top exploded view of a packing module of a second embodiment of the present invention;

FIG. 12 is a top view of a packing module according to a second embodiment of the present invention;

FIG. 13 is one embodiment of a cooling tower employing the filler module of the present invention;

FIG. 14 is another embodiment of a cooling tower employing the filler module of the present invention.

Symbol description

1. Filler module

A. A filler sheet; B. packing sheet

R1, a first flow path; r2, second flow path

200. An upper guide part;

210. a first upper end opening; 220. a second upper end opening

201. An upper left guide section; 202. right upper segment guide part

230. Upper left rectifier; 240. right upper road rectifying sheet

300. Lower guide part

310. A first lower end opening; 320. a second lower end opening

301. A left lower guide section; 302. lower right segment guide

330. Left lower path rectifier sheet; 340. right lower road rectifying sheet

400. Heat exchange part

401. A first heat exchange section; 402. a second heat exchange part

10. A cooling tower; 101. an air inlet layer; 102. a damper; 103. a filler layer;

104. a spraying part; 105. a partition plate; 105a, spraying space; 105b, bleed air space;

106. an exhaust layer; 107. a blower; 108. an air outlet; 109. a cover plate;

20. a cooling tower; 205a, spraying space; 205b, bleed air space

215. Left edge sealing; 215A, 215B, left edge seal

Detailed Description

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

[ first embodiment ]

The packing module 1 according to the first embodiment of the present invention will be described in detail.

[ Filler Module 1 ]

In the present embodiment, the packing module 1 includes the packing sheets a and B alternately stacked at a predetermined interval d, and the stacked packing sheets A, B form the first and second flow paths R1 and R2 alternately arranged in the packing module 1.

An upper stage guide portion 200 and a lower stage guide portion 300 are formed at the upper and lower stages of the packing module 1, respectively, and a heat exchange portion 400 is formed at the middle stage.

[ upper guide 200 ]

The upper ends of the upper guide portions 200 are alternately arranged with the upper ends of the rectangular packing sheets A, B to form guide openings, as follows.

The upper end portions of the filler pieces ase:Sub>A on the side perpendicular to the stacking direction (left side in the drawing) are offset to the stacking direction side (back side in the drawing), and the upper end portions of the filler pieces B are offset to the opposite direction side (front side in the drawing), so that the left upper end portions of the filler pieces ase:Sub>A-B are formed to be fitted to each other in the stacking direction from the front side to the rear side in the drawing, and the left upper end portions of the filler pieces B-ase:Sub>A are opened to each other to become first upper end openings 210, and for the filler module 1, the plurality of first upper end openings 210 are juxtaposed in the stacking direction. Thus, the first upper end opening 210 communicates with the first flow path R1 formed between the filler pieces B-ase:Sub>A.

The upper end portions of the filler pieces ase:Sub>A on the other side (right side in the drawing) perpendicular to the stacking direction are offset to the other side (front side in the drawing) in the stacking direction, and the upper end portions of the filler pieces B are offset to the opposite side (rear side in the drawing), so that the right upper end portions of the filler pieces B-ase:Sub>A are formed to be fitted to each other in the stacking direction from the front side to the rear side in the drawing, and the right upper end portions of the filler pieces ase:Sub>A-B are opened to each other to become second upper end openings 220, and for the filler module 1, the plurality of second upper end openings 220 are juxtaposed in the stacking direction. Thus, the first upper end opening 220 communicates with the first flow path R2 formed between the filler pieces a-B.

In the upper guide portion 200, an upper left fin 230 is inserted into the first flow path R1 between the first upper end opening 210 formed by the packing B-ase:Sub>A and the heat exchanging portion 400 surrounded by the packing B-ase:Sub>A. The upper left upper fin 230 has an upper end that matches the width of the first upper opening 210, and a lower end that corresponds to the width of the heat exchanging portion 400 (the first heat exchanging portion 401 of the first flow path), and gradually increases from top to bottom.

In the present embodiment, the left upper-path fin 230 has a bent cross section perpendicular to the stacking direction, and both sides in the stacking direction, that is, the back side, of the bent cross section are in contact with the front surface of the packing sheet a sandwiched therebetween, and the front side is in contact with the rear surface of the packing sheet B sandwiched therebetween. Thus, in the first flow path R1 formed between the first upper end opening 210 and the heat exchange portion 400, which is approximately in the shape of a right trapezoid, a guide portion is formed that guides the width of the first upper end opening 210 to the full width of the heat exchange portion 400, which is approximately the width of the packing sheet A, B.

In the upper stage guide portion 200, an upper right rectifying fin 240 is inserted into a second flow path R2 between a second upper end opening 220 formed by the packing sheets a-B and the heat exchanging portion 400 surrounded by the packing sheets a-B. The upper right fin 240 has an upper end that matches the width of the second upper opening 220, and a lower end that corresponds to the width of the heat exchanging portion 400 (the first heat exchanging portion 402 of the second flow path), and gradually increases from top to bottom.

In the present embodiment, the upper right rectifier 240 has a bent cross section perpendicular to the stacking direction, and both sides in the stacking direction, i.e., the back side, of the bent cross section are in contact with the front surface of the packing sheet B sandwiched therebetween, and the front side is in contact with the rear surface of the packing sheet a sandwiched therebetween. Thus, in the second flow path R2 formed between the second upper end opening 220 and the heat exchange portion 400, which is approximately in the shape of a right trapezoid, a guide portion is formed that guides the entire width of the heat exchange portion 400 from the width of the second upper end opening 220 to approximately the width of the packing sheet A, B.

[ lower stage guide 300 ]

The lower ends of the lower guide portions 300 are alternately arranged with the lower ends of the packing sheets A, B to form guide openings, as follows.

The lower end portions of the filler pieces ase:Sub>A on the side perpendicular to the stacking direction (left side in the drawing) are offset to the stacking direction side (back side in the drawing) and the lower end portions of the filler pieces B are offset to the opposite direction side (front side in the drawing), so that the left lower end portions of the filler pieces ase:Sub>A-B are formed to be fitted to each other in the stacking direction from the front side to the rear side in the drawing while the left lower end portions of the filler pieces B-ase:Sub>A are opened to each other as first lower end openings 310. Thus, the first lower end opening 310 communicates with the first flow path R1 formed between the filler pieces B-ase:Sub>A.

The lower end portions of the filler pieces ase:Sub>A on the side perpendicular to the stacking direction (right side in the drawing) are offset to the other side in the stacking direction (front side in the drawing), and the lower end portions of the filler pieces B are offset to the opposite side (rear side in the drawing), so that the lower left end portions of the filler pieces B-ase:Sub>A are formed to be fitted to each other in the stacking direction from the front side to the rear side in the drawing, and the lower left end portions of the filler pieces ase:Sub>A-B are opened to each other to become the second lower end openings 320. Thus, the first lower end opening 320 communicates with the first flow path R2 formed between the filler pieces a-B.

In the lower guide 300, ase:Sub>A left lower fin 330 is inserted into the first flow path R1 between the first lower opening 310 formed by the packing B-ase:Sub>A and the heat exchanging portion 400 surrounded by the packing B-ase:Sub>A. The lower end of the left lower fin 330 is matched with the width of the first lower opening 310, and gradually increases from bottom to top, and the upper end corresponds to the width of the heat exchanging part 400.

In the present embodiment, the left lower fin 330 has a refractive cross section perpendicular to the stacking direction, and the refractive back side abuts against the front surface of the packing sheet a and the front side abuts against the rear surface of the packing sheet B. Thus, in the first flow path R1 formed between the first lower end opening 310 and the heat exchange portion 400 in an approximately inverted right trapezoid shape, a guide portion is formed that guides the entire width of the heat exchange portion 400 from the width of the first lower end opening 310 to approximately the width of the packing sheet A, B.

In the lower guide 300, a right lower fin 340 is inserted into the second flow path R2 between the second lower opening 320 formed by the packing sheets a-B and the heat exchanging portion 400 surrounded by the packing sheets a-B. The lower end of the right lower fin 340 matches the width of the second lower opening 320, gradually increases from the top to the bottom, and the lower end corresponds to the width of the heat exchanging part 400.

In the present embodiment, the right lower rectifier 340 has a refractive cross section perpendicular to the stacking direction, and the refractive back side abuts against the front surface of the packing sheet B, and the front side abuts against the rear surface of the packing sheet a. So that a guide portion for guiding the width of the second lower end opening 320 to the full width of the heat exchanging portion 400 of substantially the width of the packing sheet A, B is formed in the second flow path R2 formed between the second lower end opening 320 and the heat exchanging portion 400 in an approximately inverted right trapezoid shape.

The filler module 1 is formed by alternately stacking the filler sheets a and B, and the first flow paths R1 and the second flow paths R2, which are isolated from each other and alternately stacked, are formed in the filler module 1. The configuration of the first flow path R1 and the second flow path R2 will be described in detail below.

[ Unit of first flow passage R1 ]

In the present embodiment, with respect to the packing module 1, ase:Sub>A unit of the first flow path R1 is formed between the adjacent packing sheet B and the packing sheet ase:Sub>A located on the rear side of the packing sheet B, that is, the packing sheet B-ase:Sub>A, in the stacking direction from the front side to the rear side in the drawing.

As shown, the first flow path R1 includes, from top to bottom, a first upper end opening 210 located on the left side of the upper end of the packing module 1; an upper left segment guide 201 of the upper segment guide 200 filled with upper left segment straightening pieces 230 and supported between the filler pieces B, A; ase:Sub>A first heat exchange portion 401 having ase:Sub>A flat cavity formed between the filler sheets B-ase:Sub>A in the stacking direction at the heat exchange portion 400; a left lower stage guide 301 of the lower stage guide 300 filled with the left lower stage fairing 330 and supported between the filler pieces B, A; and a first lower end opening 310 located at the left side of the lower end of the packing module 1.

Thus, in the present embodiment, one unit of the first flow path R1 having a flat cavity is formed between the adjacent filler pieces B and a, and the first upper end opening 210 as the upper end opening thereof and the first lower end opening 310 as the lower end opening thereof are located on the same side perpendicular to the stacking direction.

[ Unit of second flow passage R2 ]

In the present embodiment, with respect to the filler module 1, a unit of the second flow path R2 is formed between the adjacent filler piece a and the filler piece B located on the rear side of the filler piece a, that is, the filler pieces a-B, in the stacking direction from the front side to the rear side in the drawing.

As shown, the second flow path R2 includes, from top to bottom, a second upper end opening 220 located on the right side of the upper end of the packing module 1; an upper right segment guide 202 of the upper segment guide 200 filled with upper right segment fairings 240 and supported between the packing segments A, B; a second heat exchange portion 402 having a flat cavity formed between the filler sheets a-B in the stacking direction at the heat exchange portion 400; a right lower guide 302 of the lower guide 300 filled with the right lower fairing 340 and supported between the filler pieces A, B; and a second lower end opening 320 located at the right side of the lower end of the packing module 1.

Thus, in the present embodiment, one unit of the first flow path R1 having a flat cavity is formed between the adjacent filler pieces a and B, and the second upper end opening 220 as the upper end opening thereof and the second lower end opening 320 as the lower end opening thereof are located on the same side perpendicular to the stacking direction.

[ Heat exchange section 400 ]

The first heat exchange portions 401 and the second heat exchange portions 402 are alternately stacked to form the heat exchange portions 400 in which the first flow paths R1 and the second flow paths R2 are alternately stacked to perform heat exchange at intervals.

[ Upper and lower end openings of flow passage ]

As described above, the first flow paths R1 and the second flow paths R2 of the flat cavities are formed between the filler pieces B-ase:Sub>A and ase:Sub>A-B, respectively, in the stacking direction of the filler pieces A, B, whereby the first flow paths R1 and the second flow paths R2 are alternately stacked. So that, for the filler module 1, first and second upper end openings 210, 220 juxtaposed in a direction perpendicular to the stacking direction are formed at the upper end edges.

In the present embodiment, as shown in the drawing, the first upper end opening 210 is formed on the left side, and since the left upper end portion of the packing sheet ase:Sub>A is offset to the back side in the drawing and the left upper end portion of the packing sheet B is offset to the opposite front side in the drawing, the left upper end portions of the packing sheets ase:Sub>A-B are fitted to each other and the left upper end portions of the packing sheets B-ase:Sub>A are opened to each other. Thus, the left upper end portions of the packing sheets B-ase:Sub>A are opened to each other and arranged side by side in the stacking direction viase:Sub>A the attached left upper end portions of the packing sheets ase:Sub>A-B to form the complete first upper end opening 210. The first upper end opening 210 is formed to be open in the entire area corresponding to one side (left side in the drawing) of the upper end of the filler module 1 perpendicular to the stacking direction, regardless of the filler sheet thickness.

Likewise, the second upper end opening 220 is formed on the right side, opposite to the first upper end opening 210, the right upper end portion of the packing sheet B is offset to the back side in the drawing, and the right upper end portion of the packing sheet ase:Sub>A is offset to the front side in the opposite drawing, so that the right upper end portions of the packing sheets B-ase:Sub>A are fitted to each other, and the right upper end portions of the packing sheets ase:Sub>A-B are open to each other. Thus, the right upper end portions of the packing sheets ase:Sub>A-B are opened to each other and arranged in parallel in the stacking direction viase:Sub>A the right upper end portions of the bonded packing sheets B-ase:Sub>A to form the complete second upper end opening 220. The second upper end opening 220 is formed to be opened in the entire area corresponding to the other side (right side in the drawing) of the upper end of the filler module 1 perpendicular to the stacking direction, regardless of the thickness of the filler sheet.

On the other hand, the first and second upper end openings 210, 220 are formed at the lower end edges so as to be juxtaposed in a direction perpendicular to the stacking direction.

In the present embodiment, as shown in the drawing, the first lower end opening 310 is formed on the left side, and since the left lower end portion of the packing sheet ase:Sub>A is offset to the back side in the drawing and the left lower end portion of the packing sheet B is offset to the opposite front side in the drawing, the left lower end portions of the packing sheets ase:Sub>A-B are fitted to each other and the left lower end portions of the packing sheets B-ase:Sub>A are opened to each other. Thus, the left lower end portions of the packing sheets B-ase:Sub>A are opened to each other and arranged in parallel in the stacking direction viase:Sub>A the left lower end portions of the bonded packing sheets ase:Sub>A-B to form the complete first lower end opening 310. The first lower end opening 310 is formed to be open in the entire area corresponding to one side (left side in the drawing) of the lower end of the filler module 1 perpendicular to the stacking direction, regardless of the filler sheet thickness.

Likewise, the second lower end opening 320 is formed on the right side, opposite to the first lower end opening 310, the right lower end portion of the packing sheet B is offset to the back side in the drawing, and the right lower end portion of the packing sheet ase:Sub>A is offset to the front side in the opposite drawing, so that the right lower end portions of the packing sheets B-ase:Sub>A are fitted to each other, and the right lower end portions of the packing sheets ase:Sub>A-B are opened to each other. Thus, the right lower end portions of the packing sheets ase:Sub>A-B are opened to each other and arranged in parallel in the stacking direction viase:Sub>A the right lower end portions of the bonded packing sheets B-ase:Sub>A to form the complete second lower end opening 320. The second lower end opening 320 is formed to be opened in the entire area corresponding to the other side (right side in the drawing) of the lower end of the filler module 1 perpendicular to the stacking direction regardless of the thickness of the filler sheet.

[ opening of flow passage ]

The first flow path R1 will be described in further detail in the top-down direction.

As described above, the first flow path R1 is divided into a plurality of units at the upper end of the packing module 1, corresponding to the first upper end opening 210 formed in the entire left region perpendicular to the stacking direction, and at the first upper end opening 210, the portions bonded to each other by the left upper end portions of the packing sheets a-B. After passing down through the portion where the left upper end portions of the filler pieces ase:Sub>A-B are bonded to each other, the cells of the first flow path R1 are separated from each other in the stacking direction, and on the one hand, gradually decrease in size in the stacking direction and on the other hand, gradually increase in size in the direction perpendicular to the stacking direction to approximately the width of the filler pieces A, B, thereby forming ase:Sub>A flat shape, i.e., ase:Sub>A smaller thickness and ase:Sub>A larger width, and enter the cells of the first heat exchange portion 401 of the flat heat exchange space defined by the filler pieces B-ase:Sub>A of the heat exchange portion 400 from the upper guide portion 200.

As continuing from the heat exchange portion 400 down to the lower stage guide portion 300, contrary to the case in the upper stage guide portion 200, the cells of the first flow path R1 gradually increase in size in the stacking direction on the one hand, gradually decrease in size in the direction perpendicular to the stacking direction to the width of the second lower end opening 220, that is, the thickness-increasing width becomes smaller, and merge from the portion where the left lower stage guide portion 301 is bonded to each other by the left lower end portions of the filler pieces a-B to reach the first lower end opening 310, downward from the flat shape of the width of the substantially filler pieces A, B.

Thus, in the first flow path R1, the flow path cross-sectional area of the entire flow path from the first upper end opening 210 through the upper guide portion 200, the heat exchange portion 400, and the lower guide portion 300 to the first lower end opening 310 is theoretically substantially unchanged.

The second flow path R2 is rotationally symmetrical to the first flow path R1, and is described in further detail below.

As described above, the second flow path R2 is divided into ase:Sub>A plurality of units at the upper end of the packing module 1, corresponding to the second upper end opening 210 formed in the entire right side region perpendicular to the stacking direction, and at the second upper end opening 210, the portions bonded to each other by the right side upper end portions of the packing sheets B-ase:Sub>A. After passing down through the portion where the right upper end portions of the filler pieces B-ase:Sub>A are bonded to each other, the respective units of the first flow path R1 are separated from each other in the stacking direction, and on the one hand, gradually decrease in size in the stacking direction and on the other hand, gradually increase in size in the direction perpendicular to the stacking direction to approximately the width of the filler pieces A, B, thereby forming ase:Sub>A flat shape, i.e., ase:Sub>A smaller thickness and ase:Sub>A larger width, and enter the unit of the second heat exchange portion 402 of the flat heat exchange space defined by the filler pieces ase:Sub>A-B of the heat exchange portion 400 from the upper guide portion 200.

As continuing from the heat exchange portion 400 down to the lower stage guide portion 300, contrary to the case in the upper stage guide portion 200, the cells of the second flow path R2 gradually increase in size in the stacking direction on the one hand, gradually decrease in size in the direction perpendicular to the stacking direction to the width of the second lower end opening 220, that is, the thickness-increasing width becomes smaller, and merge from the portion where the right lower stage guide portion 302 is attached to each other by the right lower end portions of the filler pieces B-ase:Sub>A to reach the second lower end opening 320, downward from the flat shape of the width of the substantially filler pieces A, B.

Accordingly, in the second flow path R2, the flow path cross-sectional area of the entire flow path from the second upper end opening 220 to the second lower end opening 320 through the upper stage guide portion 200, the heat exchange portion 400, and the lower stage guide portion 300 is theoretically substantially unchanged.

As described above, in the present embodiment, the sum of the opening areas of the first and second upper end openings 210 and 220, which are the upper end openings of the first and second flow paths R1 and R2, is equal to the sum of the flow path cross-sectional areas of the respective portions from top to bottom. Similarly, the sum of the opening areas of the first and second lower end openings 310 and 320, which are the lower end openings of the first and second flow paths R1 and R2, is identical to the sum of the flow path cross-sectional areas of the respective portions from top to bottom, that is, the opening areas of the upper and lower ends of the packing module 1 are identical to the horizontal cross-sectional areas of the packing module 1, so that the flow throughput and the passing efficiency of the respective flow paths R1 and R2 can be greatly improved, and the resistance of the packing module 1 can be reduced, as will be described in further detail below.

[ rectifier piece ]

In this way, when the rectifying pieces 230, 240, 330, 340 are fitted into the guide portions 201, 202, 301, 302, that is, when the rectifying pieces 230, 240, 330, 340 are fitted into the first and second flow paths R1, R2, the rectifying pieces 230, 240, 330, 340 are formed in a bent shape, and the extending directions of the bent ridges correspond to the extending paths of the first and second flow paths R1, R2, respectively, and the thicknesses of the rectifying pieces 230, 240, 330, 340 are far from the flow path cross-sectional areas of the first and second flow paths R1, R2, so that the passing efficiency of the first and second flow paths R1, R2 is not affected.

In the present embodiment, the first upper end opening 210 and the second upper end opening 220, which are the upper end openings of the first and second flow paths R1 and R2, are arranged in parallel in the direction perpendicular to the stacking direction, and the upper left rectifier 230 and the upper right rectifier 240, which are located in the upper left guide 201 and the upper right guide 202, respectively, have substantially the same width, and the housing spaces thereof are formed in substantially the same rotational symmetry, so that the upper left rectifier 230 and the upper right rectifier 240 can be formed using the same member.

Similarly, the first lower end opening 310 and the second lower end opening 320, which are lower end openings of the first and second flow paths R1 and R2, are arranged in parallel in the direction perpendicular to the stacking direction, and the widths are substantially the same, so that the left lower rectifier 330 and the right lower rectifier 340, which are located in the left lower guide 301 and the right lower guide 302, respectively, have substantially the same configuration of the accommodation space, and are provided in a rotationally symmetrical manner, and therefore the left lower rectifier 330 and the right lower rectifier 340 can be configured using the same member.

Further, in the present embodiment, the upper-side guide portion 200 and the lower-side guide portion 300 are made to have substantially the same height, so that the housing spaces of the respective fairings 230, 240, 330, 340 are made to have substantially the same structure, and the upper-left rectifier 230, the upper-right rectifier 240, the lower-left rectifier 330, and the lower-right rectifier 340 can be formed using the same components. Thus, when the filler module 1 is manufactured, only the filler sheet A, the filler sheet B and the shared rectifying sheet are needed, so that the production cost of the filler module 1 is obviously reduced, and the assembly efficiency is obviously improved.

In the present embodiment, the same filler sheet a and filler sheet B as in the first embodiment can be used. In the first embodiment, upper left rectifier 230, upper right rectifier 240, lower left rectifier 330, and lower right rectifier 340 are provided for upper left guide 201, upper right guide 202, lower left guide 301, and lower right guide 302, respectively. While the upper left guide 201 and the lower left guide 301 are located on the same side of the packing module 1 (left side of the first embodiment), the upper right guide 202 and the lower right guide 302 are located on the other same side of the packing module 1 (right side of the first embodiment), that is, a fluid flowing into/introduced into the packing module 1 from one side (left side) of the packing module 1 in the width direction is formed, and a substantially full-width flow path R1 of the packing module 1 is formed in the heat exchanging portion 400; the flow flowing into/into the packing module 1 from the other side (right side) of the packing module 1 in the width direction forms flow paths R2, R1, and R2 of substantially the entire width of the packing module 1 in the heat exchange portion 400, the thickness of each opening in the stacking direction being half of the thickness of each opening in the stacking direction, and the sum of the thicknesses of R1 and R2 being equal to half of the thickness of the packing module 1 in the stacking direction. Thus, the same-side inflow/outflow state is formed, that is, if hot water flows in from the first upper end opening 210 at the upper left end, the hot water flows out of the packing module 1 from the first lower end opening 310 at the lower left end, and if cold air is introduced from the first lower end opening 310 at the lower left end, the hot water flows out of the packing module 1 from the first upper end opening 210 at the upper left end, and the hot water becomes the first flow path R1; the same applies to the second upper end opening 220 and the second lower end opening 320, which are upper and lower end openings on the right side, and the second flow path R2 is formed by the fluid flowing through the second upper end opening and the second lower end opening, respectively, on the left side. Of course, the packing module 1 may be configured such that the hot water is poured into the first and second upper end openings 210 and 220 at the same time as in the conventional packing module, and the cold air is sucked from the first and second lower end openings 310 and 320 at the same time, so that the hot water and the cold air in the flow paths are directly in contact with each other in reverse, and heat exchange is performed, but the discharged hot air after heat exchange may not have low saturation humidity and thus be prevented from fogging when the first flow path R1 and the second flow path R2 are respectively flown into different fluids as described above.

Of course, the first upper end opening 210 and the first lower end opening 310, which are the upper and lower end openings of the first flow path R1, may be provided on different sides of the filler module; similarly, the second upper end opening 220 and the second lower end opening 320, which are upper and lower end openings of the second flow path R2, are also provided on different sides of the filler module. The present invention is equivalent to the first embodiment in that it has no substantial influence on the function of the packing module 1 having the two flow paths R1 and R2 provided with the packing sheet A, B interposed therebetween and the openings at the upper and lower ends.

[ second embodiment ]

The filler module 1' according to the second preferred embodiment of the present invention differs from the filler module 1 according to the first preferred embodiment in that only the first flow path R1 is provided with the rectifier, that is, the upper left rectifier 230 provided in the upper left guide 201 of the first flow path R1 and the lower left rectifier 330 provided in the lower left guide 301 of the first flow path R1, and no rectifier is provided in the second flow path R2. Thus, in the present embodiment, the first flow path R1 is made to function as a shower passage, and the second flow path R2 is made to function as a bleed passage.

As shown in fig. 10 to 12, by providing the rectifying fins 230 and 330 only in the first flow path R1, the first upper end openings 210, i.e., the upper openings, which are arranged in the stacking direction from the left side of the illustrated arrow of the packing module 1 'in the first flow path R1 are partially wide, and the shower water flowing into the packing module 1' is guided by the rectifying fins 230 to the substantially entire width of the first heat exchanging portion 401 in the upper left guide 201, whereby a water film is effectively formed on the wall surfaces of the packing sheets A, B on both sides of the first flow path R1. The flow is guided by the flow straightening vane 330 in the left lower guide 301 to the first lower openings 310 provided in the direction of lamination on the left side of the arrow shown in the figure of the packing module 1', and flows out from a part of the width of the lower opening of the packing module 1'.

On the other hand, the second lower end openings 320, i.e., a part of the width of the lower openings, which are arranged in the stacking direction from the right side of the illustrated arrow of the packing module 1 'via the second flow path R2, allow the cold air introduced into the packing module 1' to enter the right lower stage guide portion 302, and then, based on the flow properties of the gas fluid itself, the lower stage guide portion 302 gradually restricts the flow path thickness in the stacking direction, gradually expands the flow path width to substantially the full width of the second heat exchange portion 402, and effectively exchanges heat with the hot water adhering to the wall portion of the first heat exchange portion 401 via the packing sheets A, B. The flow path is gradually limited in width to the second upper end opening 220 arranged in the stacking direction, that is, a part of the width of the upper opening, and gradually widened in the stacking direction to 2d at the right upper guide 202, and is led out from the second upper end opening of the packing module 1'.

It can be seen that, in the present embodiment, by removing the fairings in the upper right guide 202 and the lower right guide 302 of the second flow path R2 and using the second flow path R2 as only a cool air flow path, cool air sucked into the second flow path R2 can be made to obtain as small a windage as possible, as compared with the filler module 1 of the first embodiment of the present invention. Further, since the air flow is not affected by gravity when water flows, even if no flow straightening vane is provided, substantially the same cooling efficiency as that of the filler module 1 of the first embodiment can be obtained when the same air flow as that of the first embodiment is ensured to pass through the second flow path R2, but at this time, since no flow straightening vane is provided in the second flow path R2, the wind resistance of the air introduced into the filler module 1' is smaller. When the active exhaust cooling tower is used, the power required by the fan at the top of the cooling tower is lower, and the electric energy can be effectively saved. In addition, since the filler module 1' of the present embodiment can obtain smaller wind resistance, it is more suitable for a cooling tower that does not have a fan and adopts a passive air suction system, such as a hyperbolic cooling tower.

In the present embodiment, it is preferable that the openings at the upper and lower ends of the first flow path R1 and the second flow path R2 are located on the same side in the width direction of the packing module, and a good water blocking structure is formed by providing the packing sheet A, B, so that water in the first flow path R1 provided with the upper left rectifying piece 230 and the lower left rectifying piece 330 is prevented from entering the air flow path of the second flow path R2 through the slit. The following is a detailed description.

Further, in the present embodiment, as shown in fig. 11, the upper end portion of the packing sheet a of the packing module 1' is located at the left side of the portion where the first upper end opening 210 and the second upper end opening 220 are connected, i.e., the first upper end opening 210 side, from the base position O of the heat exchanging portion 400 of the packing sheet a _A Offset a distance d/2 to the rear side to form the rear half of the first upper end opening 210 formed by the filler piece a. Further, a distance d is formed from the rear half of the first upper end opening 210 to the front side at the left end edge of the packing sheet A, that is, from the base position O of the heat exchanging portion 400 of the packing sheet A _A At a forward offset d/2, a left edge seal 215A is formed. The left edge seal 215A extends in a straight line in the up-down direction.

Further, at the upper end portion of the packing sheet a, the right side of the portion where the first upper end opening 210 and the second upper end opening 220 are connected, that is, the second upper end opening 220 side, is offset toward the front side by a distance d/2, and the front half of the second upper end opening 210 of the second flow path R2 on the rear side constituted by the packing sheet a is formed.

Further, the upper end portion of the packing sheet B adjacent to the front side of the packing sheet a in the stacking direction is located at the left side of the portion where the first upper end opening 210 and the second upper end opening 220 are connected, i.e., the first upper end opening 210 side, from the base position O of the heat exchanging portion 400 of the packing sheet B _B Offset by a distance d/2 toward the front side to form a filled-inThe web B forms the front half of the first upper end opening 210. Further, a rearward offset distance d from the front half of the first upper end opening 210, i.e., a base position O of the heat exchanging portion 400 of the gasket B, is formed at the left end edge of the gasket B _B Offset to the rear by d/2, a left edge seal 215B is formed. The left edge seal 215B extends in a straight line in the up-down direction.

Further, at the upper end portion of the packing sheet B, the second upper end opening 210 of the front second flow path R2 formed of the packing sheet B is formed at the rear half of the second upper end opening 210 of the front second flow path R2, which is offset rearward by a distance d/2 on the right side of the portion where the first upper end opening 210 and the second upper end opening 220 are connected, that is, on the second upper end opening 220 side.

Thus, when the packing sheet a and the packing sheet B adjacent to the front side thereof are assembled in contact with each other, the left edge sealing portion 215A of the packing sheet a and the left edge sealing portion 215B of the packing sheet B are closed from top to bottom to each other at the time of forming the complete first upper end opening 210 by the rear half portion of the first upper end opening 210 of the packing sheet a and the front half portion of the first upper end opening 210 of the packing sheet B adjacent to the front side, and at the left side of the first upper end opening 210.

Thus, for the first flow path R1 formed by the packing sheet a and the packing sheet B adjacent to the front side thereof, it has an inflow port of 2d thickness, i.e., the first upper end opening 210, and its left seal edge 215 is formed by combining the left seal edge portion 215A and the left seal edge portion 215B which are offset and brought together opposite to each other. The left seal edge 215 thereof can easily form a seal structure when performing joint sealing. When the first flow path R1 is used as a flow path for spraying hot water, hot water is sprayed from the front-to-rear arranged first upper end openings 210 positioned on the left side of the filler module 1', and therefore hot water is not likely to leak out from the left seal edge 215 when the hot water is introduced into the heat exchange portion 400.

On the other hand, after the hot water is guided to the heat exchanging part 400 through the first upper end opening 210, the water flows by gravity along the rear wall surfaces of the front and rear packing sheets B and the front wall surfaces of the packing sheets a in the heat exchanging part 400, and does not easily intrude into the right edge seal of the packing module 1'. The sealing requirement for the right-hand edge seal is thus significantly reduced.

Specifically, in the present embodiment, the lower guide 300 is configured to be identical to the upper guide 200 in configuration if the lower guide 300 is rotated 180 ° about a horizontal axis perpendicular to the stacking direction. The lower guide 300 is configured such that the lower edges of the packing sheet a and the packing sheet B adjacent to the front side thereof are offset from each other, and the continuous left edge sealed portions 215A and 215B are formed on the left edges of the packing sheet a and the packing sheet B from top to bottom, including the left edges of the heat exchange portion 400, in the same manner as the upper guide 200, whereby water can be effectively prevented from oozing out from the left edge sealed portions 215, particularly from the upper guide 200 and the lower guide 300.

Further, in the present embodiment, any bonding method may be used for the edge sealing portion 215 formed by the left edge sealing portions 215A, 215B, and from the viewpoint of convenience in assembly, it is preferable to bond the edge sealing portion 210 by a pressure welding method. This is because, when the packing sheet A, B and the rectifying sheets 230 and 330 are assembled by using the apparatus, only by aligning the packing sheets B and B adjacent in the front-rear direction, at this time, since the right side portions of the upper and lower end edges of the packing sheet A, B are biased to be brought together, the welding operation of the packing sheet B-ase:Sub>A can be completed by operating the press welding apparatus to weld the edge sealing portion 215 and the right side portions of the upper and lower end edges of the packing sheet B-ase:Sub>A in this state.

The rectifier sheets 230 and 330 are interposed between the packing sheets B-ase:Sub>A, and the edge sealing portion 215 and the right side portions of the upper and lower end edges of the packing sheets B-ase:Sub>A are welded, so that the packing sheets B-ase:Sub>A before and after the stacking direction can form ase:Sub>A module having very high structural stability, and the modules formed by the plurality of packing sheets B-ase:Sub>A are combined and bonded in the stacking direction. Because the strength and stability of the single module are good, the difficulty of module assembly can be greatly reduced, and the efficiency of assembling the modules of the packing sheet B-A into the packing module 1' is improved.

In the drawings of the present embodiment, the same structure as that of the left seal 215 is not applied to the seal on the right side in terms of the assembly process and the convenience of processing. However, this is not limited to the configuration of the right edge seal, and the same configuration as that of the left edge seal 215 may be applied to the right edge seal.

[ Cooling tower 1 ]

Fig. 10 is a schematic view of a cooling tower manufactured based on the filler module 1 of the present embodiment.

The bottom layer of the cooling tower 10 is an air intake layer 101, and a plurality of dampers 102 are provided around the air intake layer 101. Above the air intake layer 101, a filler layer 103 is provided, and the filler layer 103 is arranged in a matrix form in a horizontal plane by a plurality of filler modules 1. A spraying part 104 is arranged above the packing layer 103, and the spraying part 104 sprays hot water to be treated to each packing module 1 of the packing layer 103. A partition plate 105 extending in the stacking direction of the packing modules 1 is provided substantially upright in the region between the shower portion 104 and the packing layer 103, and a plurality of space spaces 105a, 105b are defined by the partition plate 105 and the top surface of the packing modules 1, wherein the space spaces 105a serve as shower spaces for shower hot water and the space spaces 105b serve as bleed air spaces for sucking gas from bottom to top. The shower spaces 105a and the bleed spaces 105b are alternately arranged in a direction perpendicular to the stacking direction of the matrix of the packing modules 1, and each partition 105 is arranged at the junction of the first upper end opening 210 and the second upper end opening 220 of the packing module 1 so as to separate the first flow path R1 and the second flow path R2 communicating with the first upper end opening 210 and the second upper end opening 220.

Above the shower portion 104 is an exhaust layer 106, above the exhaust layer 106 is an exhaust port 108 provided with a fan 107, and air is sucked upward by the fan 107, so that cool air enters the air intake layer 101 from the damper 102 at the lower layer of the cooling tower 10, passes upward through each packing module 1 of the packing layer 103, passes through the shower space 105a and the induction space 105b, is further mixed in the exhaust layer 106, and is then discharged upward through the exhaust port 108.

On the other hand, the hot water to be treated sprayed from the spraying portion 104 to each packing module 1 of the packing layer 103 is cooled by each packing module 1, and then falls to the bottom surface of the air intake layer 101, and the cooled water is recovered by the collecting device for recycling in the factory.

The working state is as follows:

as described above, the cooling tower 10 is set to the winter operation state. At this time, the hot water to be treated sprayed from the spray portion 104 is confined in the spray space 105a to enter one of the two flow paths of the filler module 1. In the present embodiment, since the partition 105 is provided at the boundary position between the first upper end opening 210 and the second upper end opening 220 with respect to the filler modules 1, the first and second flow paths R1, R2 adjacent to each other between the adjacent two filler modules 1 each form a water flow path, and the outside flow paths R1, R2 are adjacent to the second and first flow paths adjacent to both sides, respectively, each form an air flow path.

In the water flow path, the sprayed water flows into the packing module 1, and is formed into a water film that is distributed in the flat space of substantially the entire width of the packing module 1 in the heat exchange portion 400 via the upper guide portion 200 and is adhered to both side wall surfaces in the stacking direction of the flat space. And the passages adjacent to each other on both sides in the stacking direction serve as air passages, heat exchange is performed with hot water in the water flow passage through the wall surfaces of the packing sheets A, B.

When the cooling tower 10 is operated in winter, the air sucked into the air flow path from below the filler module 1 is dry and cool air, and the air temperature and water content are low. When heat exchange with hot water occurs in the air flow path passing through the packing module 1, the heat exchange is completed in a separate flow path entirely through the packing sheet A, B, and therefore, when discharged from above the packing module 1, the temperature rises, but the water content is not changed at this time, that is, dry hot air is formed.

On the other hand, since the hot water sprayed from the upper shower portion 104 is present in the water flow path, the air sucked by the fan 107 in the water flow path receives a large resistance, and therefore, the air flow rate is very small, usually only a fraction, of the air flow rate flowing through the air flow path. While the air flowing through the air flow path will form hot saturated air, i.e. moist hot air.

The dry hot air flowing through the air flow path and the wet hot air flowing through the water flow path are mixed in the exhaust layer 106, and the amount of the wet hot air is small, so that the unsaturated hot air is formed after the dry hot air is mixed with the dry hot air, and after the dry hot air is discharged to the atmosphere through the fan 107 and the air outlet 108, the unsaturated hot air is gradually cooled down, the water precipitation is small, and the amount of the formed mist is greatly reduced.

In the present embodiment, by switching the shower portion 104, it is possible to flexibly switch between the shower space 105a and the bleed air space 105b, that is, to stop the shower space 105a from being sprayed with hot water and to switch between the hot water and the induced space 105b, so that the functions of the shower space 105a and the induced space 105b can be exchanged, whereby on the one hand, the normal operation of the cooling tower 10 can be ensured, and on the other hand, the flow path R1 or R2 of the filler module 1 communicating with the induced space 105b can be effectively cleaned and maintained, so that the normal operation of the cooling tower 10 is not affected when the cleaning and maintenance operation is performed on the cooling tower 10.

And the working state is as follows:

in the summer operation state, the hot water spray portion 104 is adjusted to spray the hot water in the same manner as in the spray space 105a in the space 105b, so that the cooling tower 10 can be ensured to have no problem of fogging in summer and the heat exchange efficiency can be improved as much as possible.

[ Cooling Tower 20 ]

In the present embodiment, the filler module 1 is used, but only the differences from the cooling tower 10 will be described in detail as the cooling tower 20, and the same components will not be described again.

The cooling tower 20 of the present embodiment is different from the cooling tower 10 described above in that a cover plate 109 along the stacking direction of the filler modules 1 is further provided substantially horizontally on the upper portion of the partition plate 105 for each shower space 105 a. A plurality of spacing spaces 205a, 205b are enclosed by the provision of the cover plate 109, the partition 105 and the filler module 1. In the present embodiment, the cover plate 109 is provided only in the shower space 205a where hot water is sprayed, and the cover plate 109 is not provided in the bleed space 205b where the exhaust is performed; of course, the cover plate 109 may be provided for both the shower space 105a and the induced space 205b, and the cover plate 109 may be formed by combining a plurality of plates, and the cover plate 109 may be turned over along the partition 105 on one side or both sides or turned over so as to be detachable or openable and closable, so that the shower space 205a and the induced air space 205b can be switched.

The working state is as follows:

this operating state is particularly suitable for winter in north China, and in this state the operation of the cooling tower 20 is similar to that of the cooling tower 10 described above, except that the shower space 205a does not in principle act as bleed air, since a cover plate 109 is provided above the shower space 205a, only hot water passes downwards through the flow path R1 or R2 of the filler module corresponding to the shower space 205a, and therefore only dry hot air from the induction space 205b is present at the exhaust layer 106 of the cooling tower 20.

Therefore, only the dry hot air in the cooling tower 20 is sucked by the fan 107 and discharged from the air outlet 108, so that the moisture in the hot air discharged from the cooling tower 20 is reduced as much as possible, thereby further improving the defogging capacity of the cooling tower 20 in winter, and the discharged air is only the dry hot air, so that the amount of the moisture discharged from the cooling tower 20 is smaller, thereby being more beneficial to water saving.

When the openable/closable (side-by-side or openable/closable) cover plate 109 is provided for both the shower space 205a and the induced space 205b, the function of the shower space 205a and the induced space 205b can be exchanged in the same manner as in the cooling tower 10 described above by opening the cover plate above the shower space 205a and closing the cover plate above the induced space 205b and adjusting the shower unit 104, and the flow path R1 or R2 of the filler module 1 corresponding to the original induced space 205b is cleaned, thereby avoiding the shutdown of the cooling tower 20.

Of course, by opening only the cover plate 109, the same operation state as the cooling tower 10 described above can be achieved, and the operation efficiency and the operation result are also substantially the same.

And the working state is as follows:

in the summer operation state, the cover plate 109 above the shower space 205a is removed or opened, and the shower portion 104 is adjusted so that hot water is sprayed to the space 205b in the same manner as the shower space 205a, thereby realizing an operation state in which the heat exchange efficiency of the cooling tower 20 is improved in summer in the same manner as the cooling tower 10.

In the cooling tower 20 of the present embodiment, the cover plate 109 provided above the space 205a, 205b is a flat plate, but the structure of the cover plate 109 is not limited to this, and may be a plate that protrudes from the partition plate 105 on both sides in the stacking direction of the filler modules 1 in the space 205a, 205b toward the middle, and is overlapped to seal the space 205a, 205b, and an upward or downward apex angle is formed at the overlapped position, that is, as long as the upper side of the space 205a, 205b can be sealed.

In the above embodiment, the rectifying fin 230 is provided in the upper left guide portion 201 of the upper drainage portion 200 of the first flow path R1 formed between the packing sheets B-ase:Sub>A in the stacking direction of the packing modules 1.

Further, the rectifying fin 240 is provided in the upper right guide 202 of the upper drainage portion 200 of the second flow path R2 formed between the packing sheets a-B in the stacking direction.

On the other hand, the rectifying fin 330 is provided in the left lower guide 301 of the lower drainage 300 of the first flow path R1 formed between the packing sheets B-ase:Sub>A in the stacking direction.

Further, the rectifying fin 340 is provided in the right upper stage guide 202 of the lower stage flow guiding portion 300 of the second flow path R2 formed between the packing sheets a-B in the stacking direction.

Since the first upper end opening 210 and the second upper end opening 220 each occupy approximately half of the width of the packing module 1, in practice, the rectifying sheet 230 is embedded in an arease:Sub>A of approximately right trapezoid surrounded by approximately the middle of the upper edge of the packing sheet ase:Sub>A (B), from the upper edge of the packing sheet B-ase:Sub>A, downward through the left side edge of the upper guide portion 200, rightward along the lower end line of the side upper guide portion 200 to the right side edge of the upper guide portion 200, and obliquely upward toward the upper edge of the packing sheet ase:Sub>A (B). With respect to the filler piece ase:Sub>A, it is offset to the rear side at the right trapezoid arease:Sub>A, and conversely, to the filler piece B, so that, in the stacking direction, ase:Sub>A close-fitting bond is formed between the front filler piece ase:Sub>A and the rear filler piece B, that is, the filler pieces ase:Sub>A-B, at the periphery of the first upper end opening 210, and thus the width of the opening between the front filler piece B and the rear filler piece ase:Sub>A in the stacking direction at the first upper end opening 210 is 2d. That is, in the right trapezoid region, the distance in the stacking direction at the first upper end opening 210 of the upper end is approximately 2d, and the distance in the stacking direction at the portion where the lower end is connected to the heat exchanging portion 400 is the interval d between the packing sheets A, B, thereby forming the space of the upper left guide portion 201.

The cross section of the rectifying fin 230 in the horizontal direction is in a bent shape extending perpendicular to the stacking direction, the bent width of the upper portion near the first upper end opening 210 is large, the bent span is small, and the bent width gradually decreases and the bent span gradually increases to fill the space of the upper left guide portion 201 during the extending process of the heat exchanging portion 400 toward the heat exchanging portion 400 from top to bottom. By forming the flow straightening fin 230 with a bend in the horizontal direction, a plurality of guide flow paths are formed from the first upper end opening 210 to the heat exchange portion 400, each of which is thick at the upper end in the stacking direction and small in width in the horizontal direction and large in thickness at the lower end, so that the hot water flowing in from the first upper end opening 210 of approximately half the width of the packing module 1 can be efficiently guided to the heat exchange portion 400 of approximately the full width of the packing module 1, and the change in the sectional area of the guide flow path from top to bottom is as small as possible regardless of the single guide flow path or the entire guide flow path, to reduce the resistance to the fluid. Good passing efficiency can be obtained for both hot water sprayed from above and air sucked from below and upwards.

The same applies to the segment 240 located in the space of the right upper guide 202, except that the segment 240 is rotationally symmetrical to the location of the segment 240 in the horizontal direction.

The fairings 330, 340 are respectively provided in the left lower guide 301 formed by the region of the inverted right trapezoid region of the lower guide 300 being offset outward in the stacking direction and the right lower guide 302 formed by the region of the inverted right trapezoid region of the lower guide 300 being offset outward in the stacking direction, as in the left upper guide 201 and the right upper guide 202 of the upper guide 200. The flow-straightening pieces 330 and 340 form a plurality of flow paths each having a small thickness at the upper end in the stacking direction and a large width at the lower end in the horizontal direction in the left lower guide portion 301 and the right lower guide portion 302, and each of the flow paths has a large thickness and a small width, so that water from the heat exchange portion 400 having substantially the entire width of the first and second flow paths R1 and R2 of the filler module 1 is guided to the first and second lower end openings 310 and 320 having substantially half the width.

That is, the rectifying sheets 330 and 340 are inverted, and have a large bending width and a small bending span at the first and second lower end openings 310 and 320, and gradually decrease in bending width and gradually increase in bending span during the extending from bottom to top toward the heat exchanging portion 400.

The rectifying piece 330 located in the space of the left lower guide portion 301 and the rectifying piece 340 located in the space of the right lower guide portion 302 are rotationally symmetrical in the horizontal direction as well.

Therefore, when the first and second upper end openings 210 and 220 and the first and second lower end openings 310 and 320 are each made to be approximately half the width of the packing module 1, if the vertical lengths of the upper and lower guide portions 200 and 300 are made to be the same, the four upper guide portions 201, the upper right guide portion 202, the lower left guide portion 301, and the lower right guide portion 302 may be formed to be rotationally symmetrical, so that the rectifying pieces 230, 240, 330, and 340 may be made to be identical members, and thus, only 3 members, that is, the packing piece a, the packing piece B, and the common rectifying piece may be required for manufacturing the packing module 1, so that not only the mold cost and the component manufacturing cost for manufacturing the packing module 1 are significantly reduced, but also the model differences of the rectifying pieces are not required for assembling the packing piece a, the packing piece B, and the rectifying pieces, and the overall manufacturing cost of the packing module 1 can be greatly reduced.

According to the preferred embodiment, the first upper end opening, the second upper end opening, the first lower end opening, and the second lower end opening are respectively laminated in the lamination direction by biasing and bonding the filler pieces a, B to the upper stage guide portion and the lower stage guide portion, respectively, and the total size of the openings in the lamination direction substantially coincides with the lamination thickness of the filler module in the lamination direction regardless of the thickness of the filler pieces A, B.

While the filler module and the cooling tower having the same according to the preferred embodiments of the present invention have been described in detail, those skilled in the art can make various modifications, alterations, combinations, etc. on the basis thereof, which are all within the scope of the claims of the present application.

Claims (9)

1. A low wind resistance filler module is characterized in that,

having rectangular filler pieces A and filler pieces B alternately stacked at predetermined intervals to form first and second flow paths alternately arranged, upper and lower guide portions provided at upper and lower stages respectively,

a heat exchange portion including, in a lamination direction, first heat exchange portions alternately laminated and formed in a flat shape between the packing sheets B and a; and a second heat exchange portion formed between the packing sheets A and B and having a flat cavity,

the first flow path is used as a water spraying channel, the second flow path is used as a bleed air channel,

the upper guide part comprises a plurality of first upper end openings and second upper end openings which are arranged on the upper surface of the packing module,

the first upper end opening is positioned at one side of the stacking direction, is arranged in parallel along the stacking direction and is communicated with the first flow path;

The second upper end opening is positioned at the other side of the stacking direction, is arranged in parallel along the stacking direction and is communicated with the second flow path,

the lower guide part comprises a plurality of first lower end openings and second lower end openings which are arranged on the lower surface of the packing module,

the first lower end opening is positioned at one side of the stacking direction, is arranged in parallel along the stacking direction and is communicated with the first flow path;

the second lower end opening is positioned at the other side of the stacking direction, is arranged in parallel along the stacking direction and is communicated with the second flow path,

the upper guide portion is provided with a first fin for guiding shower water from the first upper end opening to the first heat exchange portion having substantially the entire width of the packing module only in the first upper end opening.

2. The low wind resistance filler module of claim 1, wherein:

the lower guide portion is provided with a second fin for guiding shower water from the first heat exchange portion having substantially the entire width of the packing module to the first lower opening only in the first lower opening.

3. The low wind resistance filler module of claim 2, wherein:

the first upper end opening and the second upper end opening have substantially the same width,

The first lower end opening and the second lower end opening have substantially the same width,

the first and second fairings are the same component.

4. The low wind resistance filler module of claim 2, wherein:

the first upper end opening and the first lower end opening are on the same side of the filler module.

5. The low wind resistance filler module of claim 1 or 2, wherein:

the first upper end opening and the first lower end opening are located on the same side of the filler module,

an edge sealing portion is formed at an outer edge of the first upper end opening in the width direction of the filler module.

6. The low wind resistance filler module of claim 5, wherein:

the edge sealing part is formed by the following steps,

the upper end of the packing sheet A is offset to the rear side at the first upper end opening and to the front side at the edge,

the filler sheet B at the front side in the stacking direction,

is biased to the front side at the first upper end opening and is gathered with the first upper end opening of the filler sheet A at the front side again, and

is offset to the rear side at the edge and closes up with the edge of the pad a.

7. The low wind resistance filler module of claim 1, wherein:

The transverse cross section of each first rectifying piece and each second rectifying piece is in a bent shape, and two sides of the bent shape are respectively abutted with the packing pieces.

8. The low wind resistance filler module of claim 7, wherein:

the distance between the packing sheet A and the packing sheet B is d,

the first and second rectifying sheets have large bending amplitudes at the upper and lower openings, and have small bending spans, and the bending amplitudes gradually decrease and the bending spans gradually increase in the process of extending towards the heat exchange part.

9. A cooling tower, characterized in that:

the low wind resistance filler module according to any one of claim 1 to 8,

spraying hot water into the first flow path, flowing in through a first upper end opening of a part of the packing module in the width direction, exchanging heat with cold air in a second heat exchanging part of an adjacent second flow path through a packing sheet A, B in a first heat exchanging part of a substantially full width, and flowing out from a first lower end opening of a part of the packing module in the width direction;

in the second flow path, cool air is introduced into the second heat exchange portion only from the first lower end opening of a part in the width direction, and after heat exchange is performed in the second heat exchange portion having a substantially full width, the cool air is extracted from the second upper end opening of a part in the width direction.