JP2019002589A - Heat exchanger and corrugated fin - Google Patents

Abstract

To provide a heat exchanger capable of preventing accumulation of water on a louver of a corrugated fin.SOLUTION: A louver end portion 142 has hydrophilic concavo- convex shapes 142a formed to improve hydrophilic property of a surface of the louver end portion 142 at both sides in a plate thickness direction, of the louver end portion 142. The louver other end portion 143 has hydrophilic concavo-convex portions 143a formed to improve hydrophilic property of a surface of the louver other end portion 143 at both sides in the plate thickness direction of the louver other end portion 143. As the hydrophilic property of the surfaces of the louver end portion 142 and the louver other end portion 143 is high, condensate water attached to the louver 14 is hardly accumulated on the louver end portion 142 and the louver other end portion 143. Accordingly, the accumulation of the condensate water to the louver 14 of the corrugated fin 10 can be prevented.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a heat exchanger and a corrugated fin.

  Conventionally, heat exchangers that perform heat exchange between fluids are known. For example, this is the heat exchanger described in Patent Document 1. The heat exchanger of Patent Document 1 is a plate fin tube type heat exchanger, and is configured by inserting a flat tube into a notch formed in a flat plate fin.

  Unevenness is formed on the surface of the plate fin, and the hydrophilicity of the surface of the plate fin is improved by the unevenness. Thereby, the condensed water is quickly drained through the plate fins.

Japanese Patent No. 5661202

  If condensed water is generated in the heat exchanger and the condensed water is retained, the heat exchange performance is impaired. As a result, for example, an increase in noise, an increase in power consumption of the blower ventilating the heat exchanger, and an increase in power of the compressor connected to the heat exchanger in the refrigeration cycle may occur. Therefore, when condensed water is generated, it is preferable that the condensed water is quickly drained from the heat exchanger.

  The fact that such quick drainage of condensed water is preferable is not limited to the plate fin tube type heat exchanger of Patent Document 1, but is also the same for other heat exchangers.

  However, in the heat exchanger provided with the corrugated fin having the louver, the drainage path is different from that of the plate fin tube type heat exchanger. Moreover, in the corrugated fin, the fluid passing between the tubes is guided by the louver of the corrugated fin, thereby improving the heat exchange performance. Therefore, the technique described in Patent Document 1 cannot be used as it is for a heat exchanger provided with corrugated fins. As a result of detailed studies by the inventors, the above has been found.

  An object of this invention is to provide the heat exchanger and corrugated fin which can prevent that water retains in the louver of a corrugated fin in view of the said point.

In order to achieve the above object, the heat exchanger according to claim 1 comprises:
A heat exchanger for exchanging heat between the first fluid and the second fluid,
A plurality of tubes (20) arranged in one direction (DRst) and through which the first fluid flows;
Corrugated fins (10) provided between the tubes and formed to bend in a wave shape to promote heat exchange between the first fluid and the second fluid flowing between the tubes;
The corrugated fin has a plurality of fin main bodies (13) connected to each of the plurality of joints (12) joined to the tube and the joints adjacent to each other so as to connect the corrugated fins. And
The fin body portion has a louver (14) having a shape in which a part of the fin body portion is cut and raised,
The louver has a louver main body (141) for guiding the second fluid and a plate extending from the louver main body, and a louver one end (provided at one end in the one direction) of the louvers ( 142)
One end portion of the louver has an uneven shape (142a) formed so as to enhance the hydrophilicity of the surface of the one end portion of the louver on both sides in the plate thickness direction of the one end portion of the louver.

  According to this, since the hydrophilicity of the surface of the louver end is high, the water adhering to the louver is less likely to stagnate at the louver end, and the water is quickly drained to the corrugated fin joint or the tube surface. Will be. Therefore, it is possible to prevent water from staying in the louver of the corrugated fin. As a result, for example, the function of the louver guiding the second fluid can be prevented from being hindered by water adhering to the louver.

The corrugated fin according to claim 12 is:
In the heat exchanger that performs heat exchange between the first fluid and the second fluid, the heat exchanger is provided between a plurality of tubes arranged in one direction (DRst), is bent to form a wave shape, and flows through the tubes. A corrugated fin that facilitates heat exchange between the first fluid and the second fluid flowing between the tubes,
A plurality of joints (12) joined to the tube;
A plurality of fin main body portions (13) connected to each of the joint portions so as to connect between the joint portions adjacent to each other along the wave shape,
The fin body portion has a louver (14) having a shape in which a part of the fin body portion is cut and raised,
The louver has a louver main body (141) for guiding the second fluid and a plate extending from the louver main body, and a louver one end (provided at one end in the one direction) of the louvers ( 142)
One end portion of the louver has an uneven shape (142a) formed so as to enhance the hydrophilicity of the surface of the one end portion of the louver on both sides in the plate thickness direction of the one end portion of the louver.

  According to this, it is possible to exhibit the same effect as the heat exchanger according to the first aspect.

  In addition, each code | symbol in the bracket | parenthesis described in a claim and this column is an example which shows a corresponding relationship with the specific content as described in embodiment mentioned later.

It is a perspective view of the heat exchanger in a 1st embodiment. It is the perspective view which expanded a part of the tube and corrugated fin of the heat exchanger of FIG. It is the perspective view which extracted the corrugated fin of FIG. It is IV arrow line view in FIG. FIG. 3 is a schematic cross-sectional view of the corrugated fin of FIG. 2 cut along a plane along the plate thickness direction, showing the depth of grooves formed on the surface of the corrugated fin. FIG. 5 is a perspective view in which the corrugated fin of FIG. 2 is extracted as a single unit and a part of the corrugated fin is enlarged, and is a view of the single unit of the corrugated fin with an arrow VI in FIG. In a comparative example, while showing partially the simple substance of the corrugated fin which a heat exchanger has, it is the perspective view showing the 1st state where drainage of condensed water was stagnant. It is the figure which represented the 1st state in which the drainage of condensed water stagnated like FIG. 7 to the figure corresponded to FIG. It is sectional drawing which showed the air flow in the case where there is no condensed water in the corrugated fin which has a louver. In the corrugated fin of the comparative example, it is sectional drawing which showed the air flow when the drainage of condensed water stagnates like FIG. 7 and FIG. In the same comparative example as FIG. 7, while showing partially the single body of the corrugated fin which a heat exchanger has, it is the perspective view which showed the 2nd state in which the drainage of condensed water stagnated. It is the figure which represented the 2nd state where the drainage of condensed water stagnated like FIG. 11 in the figure corresponded to FIG. In the corrugated fin of the comparative example, it is sectional drawing which showed the air flow when the drainage of condensed water stagnates like FIG. 11 and FIG. In 1st Embodiment, the phenomenon by which condensed water is drained from a louver is the figure represented to the figure corresponded in FIG. In 1st Embodiment, it is the figure represented to the figure equivalent to FIG. 4 the phenomenon in which condensed water is drained from the curved connection part of a fin main-body part to a junction part or a tube wall surface. It is the 1st detailed drawing which expanded the XVI part of FIG. It is the 2nd detailed drawing which expanded the XVI part of FIG. FIG. 4 is a perspective view corresponding to FIG. 3, illustrating a drainage path through which condensed water is drained from the flat surface of the corrugated fin in the first embodiment. In 1st Embodiment, it is a schematic diagram for demonstrating the drainage path | route of the condensed water formed on a flat surface. In 2nd Embodiment, it is the perspective view which expanded a part of the tube and corrugated fin which a heat exchanger has. It is the schematic diagram which illustrated the modification of the some groove | channel provided in the surface of the corrugated fin of 1st and 2nd embodiment. FIG. 5 is a view showing a heat exchanger placed horizontally as a modification of the first and second embodiments, corresponding to FIG. 4.

  Hereinafter, each embodiment will be described with reference to the drawings. In the following embodiments, the same or equivalent parts are denoted by the same reference numerals in the drawings.

(First embodiment)
The heat exchanger 1 of this embodiment is used as an evaporator that constitutes a part of a refrigeration cycle that performs air conditioning in a passenger compartment, for example. The evaporator performs heat exchange between the refrigerant as the first fluid circulating in the refrigeration cycle and the air as the second fluid passing through the heat exchanger 1, and cools the air by the latent heat of vaporization of the refrigerant. An arrow DRg in FIG. 1 indicates the vertical direction DRg of the heat exchanger 1.

  As shown in FIGS. 1 and 2, the heat exchanger 1 includes a plurality of corrugated fins 10, a plurality of tubes 20, first to fourth header tanks 21 to 24, an outer frame member 25, a pipe connecting member 26, and the like. It has. These members are made of, for example, an aluminum alloy, and the members are joined to each other by brazing. In addition, although the some groove | channels 12b-15c are formed in the surface of the corrugated fin 10 so that it may mention later, in FIG. 2, illustration of the groove | channels 12b-15c is abbreviate | omitted in order to make it easy to see. .

  The plurality of tubes 20 are arranged so as to be arranged at a predetermined interval in the tube arrangement direction DRst. The air passing through the heat exchanger 1 flows between the plurality of tubes 20. Between the tubes 20, the air flows with one side in the air passage direction AF as an upstream side and the other side in the air passage direction AF as a downstream side. The air passage direction AF is one crossing direction that intersects the tube arrangement direction DRst that is one direction.

  The air passing through the heat exchanger 1 is cooled by the refrigerant and generates condensed water while flowing between the tubes 20. That is, the air passing through the heat exchanger 1 is a gas that generates condensed water by heat exchange with the refrigerant.

  Further, the plurality of tubes 20 are arranged in two rows on one side and the other side in the air passage direction AF. Each of the plurality of tubes 20 extends linearly in the tube extending direction DRt from one end to the other end. The tube stretching direction DRt does not necessarily coincide with the vertical direction DRg, but in the present embodiment, it coincides with the vertical direction DRg. In short, all the tubes 20 of the present embodiment extend in the vertical direction DRg, that is, in the vertical direction. Note that the air passage direction AF, the tube arrangement direction DRst, and the tube stretching direction DRt are directions that intersect each other, and strictly speaking, are directions that are orthogonal to each other.

  The plurality of tubes 20 are inserted into the first header tank 21 or the second header tank 22 at the upper end, and inserted into the third header tank 23 or the fourth header tank 24 at the lower end. Yes. The first to fourth header tanks 21 to 24 distribute the refrigerant to the plurality of tubes 20 and collect the refrigerant flowing in from the plurality of tubes 20.

  Since air flows between the plurality of tubes 20, a gap formed between the tubes 20 serves as an air passage through which air flows. And the corrugated fin 10 is provided in the air passage. In other words, the corrugated fin 10 is provided between the tubes 20. Therefore, the corrugated fin 10 of this embodiment is an outer fin provided on the outer side of the tube 20.

  The corrugated fin 10 promotes heat exchange between the refrigerant flowing inside the tube 20 and the air flowing between the tubes 20. Specifically, the corrugated fin 10 increases the heat exchange area between the refrigerant flowing inside the tube 20 and the air flowing outside the tube 20, thereby improving the heat exchange efficiency between the refrigerant and air. .

  In the tube arrangement direction DRst, a pair of outer frame members 25 are provided on the outer side of the portion where the plurality of tubes 20 and the plurality of corrugated fins 10 are alternately arranged. A pipe connection member 26 is fixed to one of the pair of outer frame members 25.

  The pipe connection member 26 is provided with a refrigerant inlet 27 for supplying a refrigerant and a refrigerant outlet 28 for discharging the refrigerant. The refrigerant flowing into the first header tank 21 from the refrigerant inlet 27 flows through the first to fourth header tanks 21 to 24 and the plurality of tubes 20 through a predetermined path, and flows out from the refrigerant outlet 28. At that time, the air flowing through the air passage provided with the corrugated fins 10 is cooled by the latent heat of vaporization of the refrigerant flowing through the first to fourth header tanks 21 to 24 and the plurality of tubes 20.

  As shown in FIGS. 3 and 4, the corrugated fin 10 is formed by bending a plate-like plate member or the like. Specifically, the corrugated fin 10 is bent and formed so as to form a continuous wave shape in the tube extending direction DRt.

  The corrugated fin 10 has a plurality of joint portions 12 and a plurality of fin main body portions 13. Each of the plurality of joint portions 12 constitutes a wave-shaped top portion of the corrugated fin 10 and is joined to a tube wall surface 201 which is a side surface of the tube 20 facing the tube arrangement direction DRst. That is, the surface 121 opposite to the side joined to the tube 20 among the surfaces on both sides in the plate thickness direction of the joining portion 12 is exposed to the air passage formed between the tubes 20. The joint between the joint 12 and the tube 20 is specifically brazing joint. In addition, since the junction part 12 comprises the wave-shaped top part of the corrugated fin 10, it is also called a fin TOP part.

  The fin main body part 13 is arrange | positioned between the junction parts 12 adjacent along the waveform of the corrugated fin 10, and is connected with each of the junction parts 12 so that the junction parts 12 may be connected.

  Further, the fin main body 13 is R-bent at both end portions of the fin main body 13 in the tube arrangement direction DRst. That is, the fin main body portion 13 includes a pair of curved connecting portions 131 provided at both end portions of the fin main body portion 13 in the tube arrangement direction DRst, and a main body intermediate portion 132 provided between the pair of curved connecting portions 131. It has. The pair of curved connecting portions 131 are connected to the joint portions 12 adjacent to the fin main body portion 13 while being curved.

  Note that solid lines L1, L2, L3, and L4 in FIG. 3 are virtual lines showing boundaries between the joint portion 12, the curved coupling portion 131, the main body intermediate portion 132, and the louver 14, for example, grooves It does not indicate a specific shape. The same applies to other perspective views such as FIG. 2 showing the corrugated fin 10.

  The fin main body 13 has a plurality of louvers 14 that are formed by cutting and raising a part of the fin main body 13. The plurality of louvers 14 are arranged side by side in the air passage direction AF.

  The plurality of louvers 14 are included in the main body middle portion 132 of the fin main body portion 13. The louver 14 includes a louver main body 141 including a central portion of the louver 14 in the tube arrangement direction DRst, a louver one end 142, and a louver other end 143.

  The louver main body 141 has a flat plate shape inclined with respect to the air passage direction AF, and guides air along the louver main body 141.

  The louver one end 142 has a plate shape extending from the louver main body 141 to one side in the tube arranging direction DRst, and is provided at one end of the louver 14 in the tube arranging direction DRst. The louver one end 142 is formed such that the plate thickness direction of the louver one end 142 intersects the plate thickness direction of the louver main body 141.

  Further, the louver one end 142 is connected to the curved connecting portion 131 that constitutes a portion around the louver 14 in the fin main body 13 on the side opposite to the louver main body 141 side in the tube arrangement direction DRst. The curved connecting part 131 to which the louver one end 142 is connected is one of the pair of curved connecting parts 131 arranged with the main body intermediate part 132 in between, in one tube arrangement direction DRst.

  The louver other end 143 has a plate shape extending from the louver main body 141 to the other side in the tube arranging direction DRst, and is provided at the other end of the louver 14 in the tube arranging direction DRst. The louver other end portion 143 is formed such that the plate thickness direction of the louver other end portion 143 intersects the plate thickness direction of the louver main body portion 141.

  Further, the louver other end portion 143 is connected to the curved connecting portion 131 constituting the portion around the louver 14 in the fin main body portion 13 on the side opposite to the louver main body portion 141 side in the tube arrangement direction DRst. The curved connecting portion 131 to which the other end portion 143 of the louver is connected is the other side in the tube arrangement direction DRst of the pair of curved connecting portions 131 arranged with the main body intermediate portion 132 interposed therebetween.

  Further, as shown in FIGS. 2 and 3, all the louvers 14 included in one fin main body 13 are divided into four louver groups. Each louver group includes a plurality of louvers 14 in which louver main bodies 141 are provided in parallel with each other at a predetermined interval.

  The plurality of louvers 14 constituting the four louver groups as a whole guide the air passing through the heat exchanger 1 to meander as indicated by the arrow FLf in FIG. In other words, the air flowing as indicated by the arrow FLf meanders while passing between the louvers 14. As described above, the air meanderingly flows to improve the performance of heat exchange between the refrigerant and the air.

  The main body intermediate portion 132 of the fin main body 13 includes the plurality of louvers 14 described above, but the portions other than the louvers 14 are formed in a flat plate shape. Specifically, the main body intermediate portion 132 has a plurality of flat surfaces 15 formed along the air passage direction AF. The plurality of flat surfaces 15 are arranged side by side with respect to the louver 14 in the air passage direction AF. That is, the plurality of flat surfaces 15 are the one side flat surface 151 provided at one end of the air passage direction AF in the main body intermediate portion 132 and the other side flat provided at the other end of the air passage direction AF. A surface 152 and an intermediate flat surface 153 are included. The intermediate flat surface 153 is provided between the plurality of louvers 14 included in the main body intermediate portion 132.

  As shown in FIG. 3 and FIG. 5, the hydrophilic corrugated shape, which is a corrugated shape formed so as to enhance the hydrophilicity of the surface of the corrugated fin 10 (specifically, the surfaces on both sides in the thickness direction). 12a, 131a, 141a, 142a, 143a, 15a are provided. The hydrophilic irregularities 12 a, 131 a, 141 a, 142 a, 143 a, 15 a on the surface of the corrugated fin 10 are formed over the entire surface of the corrugated fin 10. Note that the above-described uneven shape is formed so as to enhance the hydrophilicity of the surface. Specifically, the uneven shape is more hydrophilic than the surface having a smooth surface without the uneven shape. It is formed so as to enhance the property. The hydrophilic uneven shapes 12a, 131a, 141a, 142a, 143a, and 15a may be abbreviated as hydrophilic uneven shapes 12a to 15a.

  Moreover, the hydrophilic uneven | corrugated shape 12a-15a of the surface of this corrugated fin 10 is comprised from the some groove | channel 12b, 131b, 141b, 142b, 143b, 15b, 15c located in a line at predetermined intervals. The plurality of grooves 12b, 131b, 141b, 142b, 143b, 15b, and 15c include a groove extending in a predetermined first direction and a groove extending in a predetermined second direction intersecting the first direction.

  Therefore, the plurality of grooves 12b, 131b, 141b, 142b, 143b, 15b, and 15c constituting the hydrophilic uneven shapes 12a to 15a are concave shapes included in the hydrophilic uneven shapes 12a to 15a. Note that the plurality of grooves 12b, 131b, 141b, 142b, 143b, 15b, and 15c may be abbreviated as the plurality of grooves 12b to 15c. Moreover, in each drawing referred in this embodiment, the some groove | channels 12b-15c provided in the surface of the corrugated fin 10 are represented typically large for description. The same applies to each drawing described later showing the grooves 12b to 15c.

  Specifically, when each part of the corrugated fin 10 is viewed, the joint 12 has a hydrophilic concavo-convex shape 12a, which is a concavo-convex shape formed so as to increase the hydrophilicity of the surface of the joint 12. It has on the opposite side to the joining side joined to the tube 20 in the plate | board thickness direction. And the hydrophilic uneven | corrugated shape 12a is comprised from the some groove | channel 12b formed in the surface 121 on the opposite side to the joining side of the junction part 12. As shown in FIG.

  In the single corrugated fin 10, the joint portion 12 also has a hydrophilic uneven shape 12 a on the joint side joined to the tube 20 in the thickness direction of the joint portion 12. However, in the heat exchanger 1, since the joint 12 is joined to the tube 20, most of the hydrophilic uneven shape 12 a provided on the joint side of the joint 12 is covered with the tube 20.

  Further, the louver one end 142 has a hydrophilic concavo-convex shape 142a, which is a concavo-convex shape formed so as to enhance the hydrophilicity of the surface of the louver one end 142, on both sides in the plate thickness direction of the louver one end 142. ing. And the hydrophilic uneven | corrugated shape 142a is comprised from the some groove | channel 142b formed in the surface of the louver one end part 142. As shown in FIG.

  The louver other end portion 143 has hydrophilic concavo-convex shapes 143a, which are concavo-convex shapes formed so as to enhance the hydrophilicity of the surface of the louver other end portion 143, on both sides of the louver other end portion 143 in the plate thickness direction. Each has. And the hydrophilic uneven | corrugated shape 143a is comprised from the some groove | channel 143b formed in the surface of the louver other end part 143. FIG.

  The louver main body 141 has hydrophilic concavo-convex shapes 141 a that are concavo-convex shapes formed so as to enhance the hydrophilicity of the surface of the louver main body 141 on both sides in the plate thickness direction of the louver main body 141. ing. And the hydrophilic uneven | corrugated shape 141a is comprised from the some groove | channel 141b formed in the surface of the louver main-body part 141. As shown in FIG. Further, at least one of the plurality of grooves 141b provided in the louver main body 141 is formed to extend in the tube arrangement direction DRst.

  In addition, each of the pair of curved connecting portions 131 has a hydrophilic uneven shape 131 a that is an uneven shape formed so as to increase the hydrophilicity of the surface of the curved connecting portion 131, on both sides in the plate thickness direction of the curved connecting portion 131. Respectively. And the hydrophilic uneven | corrugated shape 131a is comprised from the some groove | channel 131b formed in the surface of the curved connection part 131. As shown in FIG.

  In addition, each flat surface 15 included in the fin main body 13 has a hydrophilic uneven shape 15 a that is an uneven shape formed so as to enhance the hydrophilicity of the flat surface 15. And the hydrophilic uneven | corrugated shape 15a is comprised from the some groove | channels 15b and 15c formed in the flat surface 15. FIG. And the groove | channel contained in the some groove | channels 15b and 15c formed so that the hydrophilicity of the flat surface 15 may improve mutually. Specifically, the plurality of grooves 15b and 15c included in the flat surface 15 includes a plurality of first flat surface grooves 15b and a plurality of second flat surface grooves 15c. The plurality of first flat surface grooves 15b extend so as to intersect with the plurality of second flat surface grooves 15c. As will be described for confirmation, the same applies to any of the one-side flat surface 151, the other-side flat surface 152, and the intermediate flat surface 153. The fact that the grooves included in the plurality of grooves 15b and 15c of the flat surface 15 intersect each other as described above is the same in each part of the corrugated fin 10 other than the flat surface 15.

  Further, the plurality of grooves 12b to 15c on the surface of the corrugated fin 10 are formed, for example, before the corrugated fin 10 is formed into a wave shape. Therefore, as shown in FIG. 3, the plurality of grooves 12 b to 15 c on the surface of the corrugated fin 10 continuously extend over a plurality of portions 12, 131, 132, 141, 142, and 143 constituting the corrugated fin 10. The groove is included.

  Specifically, at least one of the plurality of grooves 142b included in the louver one end 142 has one of the curved connecting portions 131 that is closer to the louver one end 142 of the pair of curved connecting portions 131. It is connected to at least one of the plurality of grooves 131b. This is the same for both surfaces of the louver one end 142. Also, the relationship between the plurality of grooves 143b of the louver other end portion 143 and the plurality of grooves 131b of the other curved connection portion 131 that is closer to the louver other end portion 143 of the pair of curved connection portions 131. It is the same.

  More specifically, any of the plurality of grooves 141b, 142b, 143b of the louver 14 reaching the louver adjacent part is connected to any groove of the louver adjacent part. The louver adjacent part is a part around the louver 14 and adjacent to the louver 14, and as shown in FIG. 3, the pair of curved connecting portions 131 and the plurality of flat surfaces 15 correspond to the louver adjacent part. .

  When attention is paid to the louver one end portion 142 of the louver 14, the one curved connecting portion 131 is adjacent to the louver one end portion 142. Of the plurality of grooves 142b that the louver one end part 142 has, the grooves that reach the one curved connecting part 131 are connected to any one of the grooves 131b that the one curved connecting part 131 has. Yes.

  Similarly, when attention is paid to the louver other end portion 143, the other curved connecting portion 131 is adjacent to the louver other end portion 143. Of the plurality of grooves 143b of the other end portion 143 of the louver, any of the grooves reaching the other curved connecting portion 131 is connected to any of the grooves 131b of the other curved connecting portion 131. ing.

  In addition, at least one of the plurality of grooves 142b included in the louver one end 142 is connected to at least one of the plurality of grooves 141b included in the louver main body 141. At the same time, in the louver other end 143, at least one of the plurality of grooves 143b included in the louver other end 143 is connected to at least one of the plurality of grooves 141b included in the louver main body 141. .

  For example, in the P1 portion of FIG. 3 and the P2 portion of FIG. 6, the groove 131b of one curved connecting portion 131 and the groove 142b of the louver one end portion 142 are connected to each other. Further, in the portion P3 in FIG. 3, the groove 141b of the louver main body 141 and the groove 142b of the louver one end 142 are connected to each other. Note that the two-dot chain line in FIG. 6 represents the schematic shape of the corrugated fin 10.

  Moreover, as shown in FIG. 5, the concave depth h included in the hydrophilic uneven shapes 12a to 15a, that is, the groove depth h of the grooves 12b to 15c is, for example, 10 μm or more. For example, with respect to the flat surface 15 of the fin main body 13, the groove depth h of the plurality of first flat surface grooves 15b is 10 μm or more, and the groove depth h of the plurality of second flat surface grooves 15c is also 10 μm or more. .

  Thereby, the hydrophilicity of the surface of the corrugated fin 10 can be sufficiently increased. When the hydrophilicity of the surface of the corrugated fin 10 is increased, the drainage of the corrugated fin 10 is improved, and the condensed water is prevented from staying on the surface of the corrugated fin 10. Therefore, since the ventilation resistance of the air passage is prevented from increasing due to the condensate water retention, the heat exchanger 1 can improve the heat exchange performance.

  Next, the flow of condensed water generated from the air cooled by the refrigerant will be described. As shown in FIG. 4, since each tube 20 is disposed along the vertical direction DRg, the condensed water flows from the upper side to the lower side as indicated by arrows F1 and F2, and the junction 12 and the tube wall surface of the corrugated fin 10. It flows along 201 and is drained out of the heat exchanger 1 from the lower part of the heat exchanger 1.

  At this time, since the fin main body portion 13 crosses the air passage between the tubes 20, the condensed water flowing as indicated by the arrow F <b> 1 passes through the surface of the louver one end portion 142 and is formed between the louvers 14. Go through the gap. Similarly, the condensed water flowing as indicated by the arrow F2 passes through the surface of the louver other end 143 and passes through the gap formed between the louvers 14. For example, in the A1 portion of FIG. 4, the condensed water flowing as indicated by the arrow F1 passes through the surface of the louver one end portion 142 and exceeds the louver one end portion 142. In the A2 portion, the condensed water flowing as indicated by the arrow F2 passes through the surface of the louver other end 143 and exceeds the louver other end 143.

  Further, since heat exchange between the refrigerant and air is promoted in the louver 14, condensed water is mainly generated in the louver 14. For example, the condensed water Wc attached to the louver main body 141 of the louver 14 spreads wet on the surface of the louver main body 141 as indicated by arrows Fa and Fb.

  The condensed water generated in the louver main body 141 in this way merges with the condensed water flowing from the upper side as indicated by the arrow Fc and the louver one end 142 and flows to the tube wall surface 201 or the joint 12. Further, the condensed water generated in the louver main body portion 141 merges with the condensed water flowing from the upper side as indicated by the arrow Fd and the louver other end portion 143 and flows to the tube wall surface 201 or the joint portion 12.

  From the flow of condensed water as described above, in the corrugated fin 10, in the flow of condensed water indicated by arrows F1 and F2, the drainage to the tube wall surface 201 and the drainage to the joint 12 need to be ensured satisfactorily. There is.

  Next, in order to explain the effect of the heat exchanger 1 of the present embodiment, a comparative example compared with the present embodiment will be described. As shown in FIG. 7, in the heat exchanger of the comparative example, the hydrophilic uneven | corrugated shape 12a-15a is not provided in the surface of the corrugated fin 90. As shown in FIG. That is, the surface of the corrugated fin 90 of the comparative example is a smooth surface without the hydrophilic irregularities 12a to 15a, and is the same as the corrugated fin 10 of the present embodiment except that. Moreover, each component (for example, tube 20 grade | etc.) Other than the corrugated fin 90 which the heat exchanger of a comparative example has is the same as that of the heat exchanger 1 of this embodiment.

  In the corrugated fin 90 of the comparative example shown in FIG. 7 and FIG. 8, each louver 14 has a high heat exchange performance between air and the refrigerant, so that the amount of condensed water generated is large. The generated condensed water is guided to the louver one end 142 or the louver other end 143 that forms a narrow gap. In addition, the condensed water flowing along the joint 12 or the tube wall surface 201 from the upper side is also guided to the louver one end 142 or the louver other end 143. For example, in FIG. 8, the flow of the condensed water guided from the upper side to the louver other end 143 is indicated by an arrow Fg.

  In the corrugated fin 90 of the comparative example, the hydrophilicity of the louver one end portion 142 and the louver other end portion 143 is lower than that of the present embodiment, so the louver one end portion 142 or the louver other end portion 143 is connected to the joint portion 12 or the tube wall surface 201. The drainage into For example, when drainage from the louver other end portion 143 to the joint portion 12 or the tube wall surface 201 as indicated by arrows Fh and Fi in FIG. 8 stagnate, the condensed water Wc stays in the gap between the louvers 14. Then, the accumulated condensed water Wc spreads over the entire gap of the louver 14 as indicated by the arrow Fj, and the entire gap of the louver 14 is clogged.

  Here, for example, if there is no condensed water Wc between the louvers 14, the air meanders along the louvers 14 as indicated by an arrow FLf in FIG. However, when the gap between the louvers 14 is clogged with the condensed water Wc as described above, the louvers 14 do not function and the air flows linearly as indicated by the arrow FLn in FIG. As described above, when the gap between the louvers 14 is clogged with the condensed water Wc, the meandering flow of air as indicated by the arrow FLf in FIG. 9 is not maintained, resulting in a decrease in cooling performance.

  Further, in the corrugated fin 90 of the comparative example, as shown in FIGS. 11 and 12, drainage from the joint portion 12 of the corrugated fin 90 to the tube wall surface 201 located on the lower side of the joint portion 12 tends to stagnate. For example, when drainage from the joint portion 12 as indicated by the arrow Fk in FIG. 12 to the tube wall surface 201 via the louver other end portion 143 stagnate, the condensed water Wc is formed between the fin main body portions 13 aligned in the tube extending direction DRt. Stay. And the condensed water Wc which flows from the upper side as shown by the arrow Fg and the condensed water Wc generated in the louver 14 are added to the accumulated condensed water Wc. Therefore, the condensed water Wc retained between the fin main body portions 13 spreads over the entire width in the tube arrangement direction DRst in the gap between the fin main body portions 13 as indicated by an arrow Fm. As a result, the gap between the fin main body portions 13 is blocked by the condensed water Wc.

  When the gap between the fin main body portions 13 is closed with the condensed water Wc as described above, the air is blocked at the location where the gap between the fin main body portions 13 is closed as shown in FIG. It can be stopped. Thus, when the clearance gap between fin main-body parts 13 is obstruct | occluded with the condensed water Wc in several places among the heat exchangers of a comparative example, the ventilation resistance which passes the heat exchanger by that much. It increases and causes a decrease in the performance of the heat exchanger.

  On the other hand, the heat exchanger 1 of the present embodiment prevents stagnation of condensed water Wc (in other words, stagnation of drainage) that can occur in the heat exchanger of the comparative example described with reference to FIGS. It is configured as follows. And in this embodiment, the ventilation resistance of the heat exchanger 1 is reduced and the performance of the heat exchanger 1 is improved by preventing the retention of the condensed water Wc, ie, improving the drainage of the condensed water Wc. be able to.

  For example, according to the present embodiment, as shown in FIG. 3, the louver one end 142 has a hydrophilic concavo-convex shape 142 a formed so as to enhance the hydrophilicity of the surface of the louver one end 142. Each has both sides in the thickness direction. And the louver other end part 143 has the hydrophilic uneven | corrugated shape 143a formed so that the hydrophilic property of the surface of the louver other end part 143 might be improved on the both sides of the plate | board thickness direction of the louver other end part 143, respectively. Yes.

  Thus, since the hydrophilicity of the surface of the louver one end part 142 and the louver other end part 143 is high, the condensed water adhering to the louver 14 becomes difficult to stay in each of the louver one end part 142 and the louver other end part 143. Then, the condensed water is quickly drained to the joint portion 12 or the tube wall surface 201 of the corrugated fin 10. That is, drainage of the louver one end 142 and the louver other end 143 that are part of the drainage path can be promoted.

  Therefore, it is possible to prevent the condensed water from staying in the louver 14 of the corrugated fin 10. As a result, for example, the function of the louver 14 guiding air as shown by the arrow FLf in FIGS. 2 and 9 can be prevented from being hindered by condensed water adhering to the louver 14.

  In addition, the groove 142b as the concave portion of the hydrophilic uneven shape 142a of the louver one end 142 generates a force that pulls the condensed water. Therefore, the condensed water that flows through the louver one end 142 using the force that the groove 142b pulls the condensed water. It is possible to promote drainage. The same applies to the louver other end portion 143.

  Further, according to the present embodiment, as shown in FIGS. 3 and 4, the fin main body portion 13 is configured such that the pair of curved connection portions 131 that are curved and connected to the joint portion 12 are connected to the fin main body portion in the tube arrangement direction DRst. 13 at both ends. And a pair of curved connection part 131 has the hydrophilic uneven | corrugated shape 131a formed so that the hydrophilic property of the surface of the curved connection part 131 might be improved on the both sides of the plate | board thickness direction of the curved connection part 131, respectively. Yes. Therefore, since the hydrophilicity of the surface of the curved connecting portion 131 is high, drainage from the curved connecting portion 131 to the joint portion 12 or the tube wall surface 201 can be promoted.

  Moreover, according to this embodiment, the hydrophilic uneven | corrugated shape 142a of the louver one end part 142 is comprised from the some groove | channel 142b. Further, the hydrophilic uneven shape 131a of one curved connecting portion 131 that is closer to the louver one end portion 142 of the pair of curved connecting portions 131 is also composed of a plurality of grooves 131b. At least one of the plurality of grooves 142b included in the louver one end 142 is connected to at least one of the plurality of grooves 131b included in the one curved connection part 131.

  Thereby, since the condensed water adhering to the louver one end part 142 becomes easy to be pulled to the one curved connecting part 131, drainage from the louver 14 can be promoted. Therefore, it is possible to promote drainage from the louver 14 to the joint portion 12 or the tube wall surface 201 via the one curved connection portion 131. For example, drainage of the condensed water Wc that flows as shown by arrows Fn and Fo in FIGS. 6 and 14 can be promoted.

  The fact that drainage from the louver 14 is promoted in this way is also the same at the louver other end 143. That is, in this embodiment, for example, as shown by arrows Fp and Fq in FIG. 14, drainage of the condensed water Wc flowing through the louver other end 143 can be promoted.

  Further, according to the present embodiment, as shown in FIGS. 3 and 4, the joining portion 12 has a hydrophilic uneven shape 12 a formed so as to increase the hydrophilicity of the surface of the joining portion 12 in the tube 20. It is on the side opposite to the joined side. Accordingly, the drainage of the condensed water is less likely to stagnate at the joint 12, so that drainage from the louver one end 142 or the louver other end 143 to the joint 12 can be promoted.

  In addition, the plurality of grooves 12 b constituting the hydrophilic uneven shape 12 a of the joint portion 12 pulls condensed water from above the curved connection portion 131 connected to the upper side of the joint portion 12. Also by this, it is possible to promote drainage of the condensed water Wc that flows as indicated by an arrow Fr in FIG.

  Moreover, in the XVI part of FIG. 15, the some groove | channel 131b of the curved connection part 131 shown in FIG. 3 pulls the condensed water Wc on the surface. At the same time, since the convex side of the curved shape of the curved connecting portion 131 faces obliquely downward, the pulling force due to the curved shape acts on the condensed water Wc on the curved connecting portion 131. Therefore, it is possible to promote drainage of the condensed water Wc flowing from the curved connecting portion 131 to the tube wall surface 201 as indicated by arrows Fs and Ft in FIGS. 15 and 16.

  Here, a diagram for explaining the pulling of the condensed water Wc due to the curved shape of the curved connecting portion 131 is shown in FIG. As shown in FIG. 17, the curvature radius R1 of the surface of the condensed water Wc attached to the concave side of the curved shape of the curved connecting portion 131 is the radius of curvature R2 of the surface of the condensed water Wc attached to the convex side of the curved shape. Bigger than. This is because the angle θ between the curved convex surface of the curved connecting portion 131 and the tube wall surface 201 is an acute angle. And when water accumulates at a corner as a physical phenomenon, the smaller the angle formed by the two sides constituting the corner, the smaller the radius of curvature of the surface of the water.

  Due to the magnitude relationship between the curvature radii R1 and R2, the force that pulls the condensed water Wc is greater on the convex side than on the concave side of the curved shape of the curved connecting portion 131, and the flow indicated by the arrows Fs and Ft in FIGS. Drainage is promoted.

  Further, according to the present embodiment, as shown in FIG. 3, the louver main body 141 has a hydrophilic concavo-convex shape 141 a formed so as to increase the hydrophilicity of the surface of the louver main body 141. 141 on both sides in the plate thickness direction. Therefore, the spread of the condensed water Wc is promoted on the surface of the louver main body 141 as indicated by arrows Fa and Fb in FIG. Therefore, the condensed water Wc easily flows from the louver main body 141 to each of the louver one end 142 and the louver other end 143, and the drainage from the louver 14 can be improved.

  Further, according to the present embodiment, as shown in FIG. 3, the flat surface 15 of the corrugated fin 10 includes a plurality of first flat surface grooves 15 b formed to enhance the hydrophilicity of the flat surface 15 and a plurality of flat surfaces 15. And a second flat surface groove 15c. The plurality of first flat surface grooves 15b extend so as to intersect with the plurality of second flat surface grooves 15c.

  Accordingly, the condensed water Wc adhering to the flat surface 15 spreads wet while being pulled by the first flat surface groove 15b and the second flat surface groove 15c, and is drained to a portion around the flat surface 15. For example, as indicated by arrows F1u, F2u, and F3u in FIG. 18, the condensed water Wc adhering to the flat surface 15 is drained downward from the flat surface 15 through a gap between the louvers 14. At this time, since the plurality of first flat surface grooves 15b and the plurality of second flat surface grooves 15c intersect with each other, the drainage paths on the flat surface 15 increase in various ways and the drainage performance from the flat surface 15 is improved. Is possible.

  For example, as shown in FIG. 19, since the plurality of first flat surface grooves 15b and the plurality of second flat surface grooves 15c intersect, the drainage path of the condensed water Wc on the flat surface 15 is the first flat surface. A large number of paths are formed by connecting a part of the groove 15b and a part of the plurality of second flat surface grooves 15c. Therefore, for example, the path along the arrow F1v and the path along the arrow F2v can be drainage paths for the condensed water Wc. Thus, the drainage path of the condensed water Wc is formed in various ways, and the drainage performance from the flat surface 15 can be improved.

  According to the present embodiment, as shown in FIGS. 1 and 4, the plurality of tubes 20 extend in the vertical direction. Therefore, it is possible to improve the drainage of the condensed water transmitted through the tube wall surface 201 as indicated by arrows F1 and F2 in FIG. 4 due to gravity.

  Moreover, according to this embodiment, the depth h of the concave shape included in the hydrophilic uneven shapes 12a to 15a shown in FIG. 5 is, for example, 10 μm or more. If it does in this way, the hydrophilicity produced by the hydrophilic uneven | corrugated shape 12a-15a is fully ensured, and the drainage effect which drains the condensed water adhering to the surface which has the hydrophilic uneven | corrugated shape 12a-15a is fully exhibited. be able to. For example, when the depth h of the concave shape is less than 10 μm, it is difficult to ensure sufficient hydrophilicity to obtain good drainage.

(Second Embodiment)
Next, a second embodiment will be described. In the present embodiment, differences from the first embodiment will be mainly described. Further, the same or equivalent parts as those of the above-described embodiment will be described by omitting or simplifying them. The same applies to the description of the embodiments described later.

  As shown in FIG. 20, in the present embodiment, the directions of the plurality of grooves 12 b to 15 c provided on the surface of the corrugated fin 10 are different from those in the first embodiment. Specifically, most of the grooves 12b to 15c of the first embodiment described above extend in a direction along the air passage direction AF or in a direction orthogonal thereto, as shown in FIG. On the other hand, most of the grooves 12b to 15c of the present embodiment extend in a direction inclined with respect to the air passage direction AF, as shown in FIG.

  Except as described above, the present embodiment is the same as the first embodiment. And in this embodiment, the effect show | played from the structure common to the above-mentioned 1st Embodiment can be acquired similarly to 1st Embodiment.

(Other embodiments)
(1) In each of the above-described embodiments, as shown in FIG. 5, the groove depth h of the plurality of grooves 12 b to 15 c formed on the surface of the corrugated fin 10 is, for example, 10 μm or more, which is preferable. However, the groove depth h is not necessarily 10 μm or more.

  (2) In each of the embodiments described above, for example, as shown in FIG. 3, the grooves 12 b to 15 c on the surface of the corrugated fin 10 all extend linearly. However, the present invention is not limited thereto, and may be curved, for example. .

  (3) In each of the above-described embodiments, as shown in FIGS. 3 and 20, the plurality of grooves 12b to 15c provided on the surface of the corrugated fin 10 respectively extend continuously from end to end of the surface. But this is an example. For example, as shown in FIG. 21, the plurality of grooves 12b to 15c may be intermittently divided.

  (4) In each of the above-described embodiments, as shown in FIGS. 1 and 4, the heat exchanger 1 is arranged so that the tube 20 extends in the vertical direction DRg, but the heat exchanger 1 is installed. There is no limit to the direction. For example, as shown in FIG. 22, the heat exchanger 1 may be arranged so that the tube 20 is oriented in the horizontal direction.

  When the heat exchanger 1 is arranged as shown in FIG. 22, in the drainage from the louver 14 to the joint 12 or the tube wall surface 201, for example, the condensed water Wc flows as indicated by the arrow Fw. Therefore, drainage from the louver 14 to the joint 12 or the tube wall surface 201 can provide the same drainage effect as in the first and second embodiments described above. That is, the heat exchanger 1 of FIG. 22 can also promote drainage from the louver 14. And if drainage from louver 14 is promoted, like the above-mentioned 1st and 2nd embodiments, the performance fall of heat exchanger 1 will be controlled, and heat exchange will be achieved by reducing the water film thickness in louver 14. It is possible to suppress an increase in ventilation resistance of the vessel 1.

  (5) In each above-mentioned embodiment, although heat exchanger 1 is explained as what is used as an evaporator, it is not restricted to this. The heat exchanger 1 of each embodiment may be a heat exchanger other than an evaporator as long as water discharge is necessary.

  (6) In each above-mentioned embodiment, although the 1st fluid which flows through the inside of tube 20 is a refrigerant, it is also assumed that the 1st fluid is fluids other than a refrigerant. Moreover, although the 2nd fluid which flows between the tubes 20 is air, it is assumed that the 2nd fluid is fluids other than air.

  (7) The present invention is not limited to the above-described embodiment, and can be implemented with various modifications. In each of the above-described embodiments, it is needless to say that elements constituting the embodiment are not necessarily essential unless explicitly stated as essential and clearly considered essential in principle. Yes.

  Further, in each of the above embodiments, when numerical values such as the number, numerical value, quantity, range, etc. of the constituent elements of the embodiment are mentioned, it is clearly limited to a specific number when clearly indicated as essential and in principle. The number is not limited to the specific number except for the case. In each of the above embodiments, when referring to the material, shape, positional relationship, etc. of the constituent elements, etc., unless otherwise specified, or in principle limited to a specific material, shape, positional relationship, etc. The material, shape, positional relationship, etc. are not limited.

(Summary)
According to the 1st viewpoint shown by one part or all part of said each embodiment, the louver of a corrugated fin has a louver main-body part which guides a 2nd fluid, and a louver one end part. One end portion of the louver has a plate shape extending from the louver body portion, and is provided at one end of the louver in one direction. Moreover, the louver one end part has an uneven shape formed so as to enhance the hydrophilicity of the surface of the louver one end part on both sides in the plate thickness direction of the louver one end part.

  According to the second aspect, the louver has a plate-like shape extending from the louver main body, and the louver is provided at the other end of the louver opposite to the one side in the one direction. Has an end. And the louver other end part has the uneven | corrugated shape formed so that the hydrophilic property of the surface of the louver other end part might be improved on the both sides of the plate | board thickness direction of the louver other end part, respectively. Therefore, since the hydrophilicity of the surface of the other end of the louver is high, the water adhering to the louver is less likely to stay at the other end of the louver. Therefore, it is easier to prevent water from staying in the louver of the corrugated fin as compared with the configuration of the first aspect.

  Moreover, according to the 3rd viewpoint, a fin main-body part has a pair of curved connection part which curves and connects with a junction part in the both ends of the fin main-body part in the said one direction, respectively. And a pair of curved connection part has the uneven | corrugated shape formed so that the hydrophilicity of the surface of the curved connection part might be improved on the both sides of the thickness direction of the curved connection part, respectively. Therefore, since the hydrophilicity of the surface of the curved connecting portion is high, drainage from the curved connecting portion to the joint portion or the tube wall surface can be promoted.

  According to the fourth aspect, the concavo-convex shape at one end of the louver is composed of a plurality of grooves, and the concavo-convex shape of one curved connecting portion on the side close to the louver end portion of the pair of curved connecting portions is also plural. Consists of grooves. Then, at least one of the plurality of grooves included in the one end portion of the louver is connected to at least one of the plurality of grooves included in the one curved connection portion. Thereby, since water adhering to one end of the louver is easily pulled to one curved connecting portion, drainage from the louver can be promoted. Therefore, it is possible to promote drainage from the louver to the joint portion or the tube wall surface via one curved connecting portion.

  Moreover, according to the 5th viewpoint, a junction part has the uneven | corrugated shape formed so that the hydrophilicity of the surface of the junction part might be improved on the opposite side to the side joined to the tube. Accordingly, since the drainage is less likely to stay at the joint, drainage from the louver to the joint can be promoted.

  Further, according to the sixth aspect, the louver main body portion has a concavo-convex shape formed so as to increase the hydrophilicity of the surface of the louver main body portion on both sides in the plate thickness direction of the louver main body portion. Accordingly, water spreads out on the surface of the louver main body and easily flows out of the louver, so that the drainage from the louver can be improved.

  According to the seventh aspect, between the tubes, the second fluid flows with one side in one crossing direction intersecting the one direction as an upstream side and the other side in the one crossing direction as a downstream side. A fin main-body part has a flat surface formed so that the said 1 crossing direction may be met. The flat surface has a plurality of first flat surface grooves and a plurality of second flat surface grooves formed so as to enhance the hydrophilicity of the flat surface. The plurality of first flat surface grooves extend so as to intersect with the plurality of second flat surface grooves.

  Therefore, the water adhering to the flat surface wets and spreads while being pulled by the first flat surface groove and the second flat surface groove, and is drained to a portion around the flat surface. At this time, since the plurality of first flat surface grooves and the plurality of second flat surface grooves intersect with each other, the drainage paths on the flat surface increase in various ways, and drainage from the flat surface can be improved. It is.

  According to the eighth aspect, the second fluid is a gas that generates condensed water by heat exchange with the first fluid.

  According to the ninth aspect, the plurality of tubes extend in the vertical direction. Therefore, it is possible to improve the drainage of the water transmitted through the tube wall surface by gravity.

  Moreover, according to the 10th viewpoint, the depth of the concave shape contained in the said uneven | corrugated shape is 10 micrometers or more. According to this, the hydrophilicity generated by the uneven shape is sufficiently secured, and the drainage effect of draining water adhering to the surface having the uneven shape can be sufficiently exhibited.

  According to the eleventh aspect, the depth of the groove included in the plurality of first flat surface grooves is 10 μm or more, and the depth of the groove included in the plurality of second flat surface grooves is also 10 μm or more. According to this, the hydrophilicity which produces a 1st flat surface groove | channel and a 2nd flat surface groove | channel is fully ensured, and the drainage effect which drains the water adhering to a flat surface can fully be exhibited.

  According to the twelfth aspect, the louver of the corrugated fin has a louver main body for guiding the second fluid and a louver one end. One end portion of the louver has a plate shape extending from the louver body portion, and is provided at one end of the louver in one direction. Moreover, the louver one end part has an uneven shape formed so as to enhance the hydrophilicity of the surface of the louver one end part on both sides in the plate thickness direction of the louver one end part.

DESCRIPTION OF SYMBOLS 1 Heat exchanger 10 Corrugated fin 12 Junction part 13 Fin main-body part 14 Louver 20 Tube 141 Louver main-body part 142 Louver one end part 142a, 143a Hydrophilic uneven | corrugated shape 143 Louver other end part

Claims (12)

A heat exchanger for exchanging heat between the first fluid and the second fluid,
A plurality of tubes (20) arranged in one direction (DRst) and through which the first fluid flows;
A corrugated fin (10) provided between the tubes and bent to form a wave shape to promote heat exchange between the first fluid and the second fluid flowing between the tubes; Prepared,
The corrugated fin includes a plurality of fin bodies connected to each of the joints so as to connect between the joints (12) joined to the tube and the joints adjacent to each other along the wave shape. Part (13),
The fin main body has a louver (14) having a shape in which a part of the fin main body is cut and raised,
The louver has a louver body (141) for guiding the second fluid, and a plate extending from the louver body. The louver is provided at one end of the louver in the one direction. One end (142),
The louver one end has a concavo-convex shape (142a) formed so as to increase the hydrophilicity of the surface of the louver one end on both sides in the plate thickness direction of the louver one end. The louver has a plate-like shape extending from the louver main body, and has a louver other end (143) provided at the other end of the louver opposite to the one side in the one direction. Have
The louver other end has an uneven shape (143a) formed so as to increase the hydrophilicity of the surface of the louver other end on both sides in the plate thickness direction of the louver other end, respectively. The described heat exchanger. Each of the fin main body portions has a pair of curved connection portions (131) that are curved and connected to the joint portion at both end portions of the fin main body portion in the one direction,
3. The pair of curved connecting portions have uneven shapes (131 a) formed so as to increase the hydrophilicity of the surface of the curved connecting portions on both sides in the plate thickness direction of the curved connecting portions, respectively. The heat exchanger as described in. The concavo-convex shape at one end of the louver is composed of a plurality of grooves (142b), and the concavo-convex shape of one of the curved connecting portions on the side close to the one end of the louver is also a plurality of grooves (131b). Consisting of
The heat exchange according to claim 3, wherein at least one of the plurality of grooves included in the one end portion of the louver is connected to at least one of the plurality of grooves included in the one curved connection portion. vessel.   The said junction part has the uneven | corrugated shape (12a) formed so that the hydrophilic property of the surface of this junction part might be improved on the opposite side to the side joined to the said tube. The heat exchanger described in 1.   6. The louver body portion according to claim 1, wherein the louver body portion has uneven shapes (141 a) formed so as to enhance the hydrophilicity of the surface of the louver body portion on both sides in the plate thickness direction of the louver body portion. The heat exchanger as described in any one. Between the tubes, the second fluid flows with one side of one crossing direction (AF) intersecting the one direction as an upstream side and the other side of the one crossing direction as a downstream side,
The fin body portion has a flat surface (15) formed so as to be along the one crossing direction,
The flat surface has a plurality of first flat surface grooves (15b) and a plurality of second flat surface grooves (15c) formed so as to increase the hydrophilicity of the flat surface,
The heat exchanger according to claim 1, wherein the plurality of first flat surface grooves extend so as to intersect the plurality of second flat surface grooves.   The heat exchanger according to any one of claims 1 to 7, wherein the second fluid is a gas that generates condensed water by heat exchange with the first fluid.   The heat exchanger according to any one of claims 1 to 8, wherein the plurality of tubes extend in a vertical direction (DRg).   The heat exchanger according to any one of claims 1 to 9, wherein a depth (h) of the concave shape included in the concave-convex shape is 10 µm or more.   The depth (h) of the groove included in the plurality of first flat surface grooves is 10 μm or more, and the depth (h) of the groove included in the plurality of second flat surface grooves is also 10 μm or more. The heat exchanger according to 7. In a heat exchanger that performs heat exchange between the first fluid and the second fluid, the heat exchanger is provided between a plurality of tubes arranged in one direction (DRst), and is bent to form a wave shape. A corrugated fin that promotes heat exchange between the flowing first fluid and the second fluid flowing between the tubes,
A plurality of joints (12) joined to the tube;
A plurality of fin main bodies (13) connected to each of the joints so as to connect between the joints adjacent to each other along the wave shape;
The fin main body has a louver (14) having a shape in which a part of the fin main body is cut and raised,
The louver has a louver body (141) for guiding the second fluid, and a plate extending from the louver body. The louver is provided at one end of the louver in the one direction. One end (142),
The louver one end is a corrugated fin having a concavo-convex shape (142a) formed so as to enhance the hydrophilicity of the surface of the louver one end on both sides in the plate thickness direction of the louver one end.

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