KR100857669B1 - Heat exchanger - Google Patents

Abstract

At the same time, a plurality of insertion tube through holes 22 for heat transfer tube insertion are formed in the fin 6, and ribs 15 are formed in the fin 6 extending substantially parallel to the outer edge 25 of the fin 6. The ribs 15 are arranged on the outer edge 25 side than all the insertion holes 22. The inner diameter of the insertion hole 22 is set to D [mm], the distance between the center of the insertion hole 22 closest to the rib 15 and the outer edge 25 is L [mm], and the rib ( The distance between the center of the center 15 and the outer edge 25 is La [mm], the width of the rib 15 is LL [mm], the plate thickness of the pin 6 is t [mm], and the rib is When the height of (15) is set to h [mm], the pin 6 has 0.4 <La <(LD / 2-0.5), 0.15 <LL <0.5, 0.05 <t <0.15, 0.5t <h <2.5 A rib 15 is formed that satisfies t.

Description

Heat exchanger {HEAT EXCHANGER}

The present invention relates to heat exchangers, and in particular to heat exchangers suitable for use in refrigeration equipment such as air conditioners.

Conventionally, as a heat exchanger, there exist some described in Unexamined-Japanese-Patent No. 2000-35296.

The heat exchanger is provided with a plurality of fins and a plurality of heat transfer tubes stacked at predetermined intervals.

The plurality of heat transfer tubes are inserted through the plurality of fins at predetermined intervals.

Grooves extending in the direction along the outer edge of the fin in the longitudinal direction are formed at both ends in the width direction of the fin. The groove is configured to guide water droplets of condensation water generated on the surface of the fin from the upper side to the lower side.

The said conventional heat exchanger guides the water droplet of the dew condensation water which generate | occur | produces on the surface of a fin from the upper direction to the downward direction by the said groove | channel, and prevents the dew condensation water which generate | occur | produces on the surface of a fin with wind.

However, in the conventional heat exchanger, when the groove formation position is too close to the outer edge of the fin, or too close to the insertion hole and the hole for the heat pipe insertion passage formed in the fin, the edge portion where the groove is formed in the fin is formed. There is a problem of deforming or deforming the groove itself. The deformation of the groove causes a condensation puddle to form in the groove, and condensation water becomes difficult to flow downward in the vertical direction. Moreover, there exists a problem that the edge part which formed the groove | channel in a fin deform | transforms and becomes wavy shape, and a person is injured by the outer edge of this wavy pin.

Therefore, the subject of this invention can guide smoothly downward so that the dew condensation water which generate | occur | produced on the surface of a pin may not be scattered to the outside, and the pin will not bend or waved, and a person will be injured. It is to provide a heat exchanger without a job.

The heat exchanger of this invention for solving the said subject,

A plurality of heat pipes,

And a plate-shaped pin having ribs substantially parallel to the outer edge and having insertion holes and holes through which the plurality of heat transfer tubes are inserted.

The ribs are arranged on the outer edge side than all the insertion holes,

The inner diameter of the insertion hole is D [mm], the center of the insertion hole is closest to the rib 15, and the distance between the outer edge is L [mm], the center of the rib, When we made distance with outer margin La [mm],

0.4 <La <(L-D / 2-0.5)

It is characterized by that.

In addition, the center of the said rib means the center in the width direction of the said rib.

According to the present invention, since the rib is formed on the pin, the rib forms a raceway by surface tension. Therefore, the dew condensation water is difficult to scatter from the pin.

According to the present invention, since 0.4 <La, the ribs do not come too close to the outer edges of the pins, and deformation does not occur at the edges or ribs of the pins. In addition, since La <(L-D / 2-0.5), the rib does not come too close to the insertion hole and the hole, and the rib does not deform.

Therefore, since the rib formed in the pin does not deform, it is possible to prevent the occurrence of a portion where condensation water is difficult to flow on the rib, so that the condensation water generated on the surface of the pin can be quickly flowed downward along the rib. can do. Therefore, the increase in the ventilation resistance accompanying the reduction of the ventilation path of heat exchange of the fin by retention of condensation water can be prevented, and the heat transfer performance can be improved. In addition, since the deformation of the pin is small, it is possible to prevent an increase in the ventilation resistance and the occurrence of joints caused by the pin falling down.

In the heat exchanger of one embodiment, when the width of the rib is LL [mm], the plate thickness of the fin is t [mm], and the height of the rib is h [mm], 0.15 <LL. <0.5, 0.05 <t <0.15, and 0.5t <h <2.5t.

According to the said embodiment, since 0.15 <LL, the deformation | transformation of a rib can be prevented more reliably, and since LL <0.5, it is possible to make the dew condensation water flow down without a problem. Moreover, since it is 0.05 <t, the strength of a fin can be made no problem, and since t <0.15, the integration of a fin can be enlarged and it can be made excellent in heat exchange efficiency. Moreover, since 0.5t <h, condensation water can flow down without a problem, and since h <2.5t, it can prevent wind from colliding with a rib and generating turbulence, etc. I can do it smoothly.

Moreover, the heat exchanger of one embodiment is in the state in which the said fin is arrange | positioned at the refrigeration apparatus of a use state, and the said outer edge inclines with respect to a perpendicular direction.

The said refrigeration apparatus means an air conditioner, a refrigerator, an ice machine, etc.

According to the said embodiment, since the said outer edge inclines with respect to a perpendicular direction in the state in which the said pin is arrange | positioned at the refrigeration apparatus of a use state, the dew condensation number which exists in the vicinity of the said outer edge which is easy to splash from a pin is reliably through the said rib. It can flow down. Therefore, it is possible to surely prevent condensation water from splashing from the pin.

Moreover, the heat exchanger of one embodiment is built in the indoor unit of the air conditioner.

According to the said embodiment, the phenomenon which a water droplet splashes in a room can be prevented.

Moreover, the heat exchanger of one embodiment is 7.5 mm or less in said inner diameter D of the said insertion hole.

When the said inner diameter D is 7.5 mm or less, since the ventilation resistance is small, it will be in the operating situation where the water splashing by a large amount of air tends to occur. However, since the ribs of the said shape and arrangement are provided in the said pin, even if it puts in the driving situation by a big air volume, the water from a fin can be prevented from splashing.

Moreover, the heat exchanger of one Embodiment is provided with the folding part in the said fin.

According to the said embodiment, since the fold part is provided in the said fin, it has the advantage that heat exchange efficiency is high, while the unevenness of a ventilation resistance arises in the place with and without a fold part, and the wind speed distribution is uneven, The phenomenon of water splashing is likely to occur at this early place, but water splashing can be prevented reliably by the ribs of the shape and arrangement.

Moreover, the heat exchanger of one embodiment of the said rib is formed in the airflow side of the direction through which a heat transfer medium flows at least than the said heat exchanger tube in the said fin.

According to the said embodiment, since the said rib is formed in the said wind fall side of the said fin, the dew condensation water which generate | occur | produced on the said fin can be reliably prevented from flying to a heat transfer medium and scattering from a fin.

Moreover, the heat exchanger of one embodiment of the said rib is formed in the wind direction side of the direction through which a heat transfer medium flows rather than the said heat exchanger tube in the said fin.

According to the said embodiment, since the said rib is formed in the said wind direction side of the said fin, the dew condensation which generate | occur | produces in the part of the wind direction side of the said fin, and becomes the particle shape by surface tension, is the edge of the wind direction side of a fin. It is possible to prevent scattering from wealth.

Moreover, the heat exchanger of one embodiment is provided with the said rib in the wind direction side of the direction in which a heat-transfer medium flows rather than the said heat exchanger tube in the said fin, and the wind down side of the direction in which the heat-transfer medium flows rather than the said heat exchanger tube in the said fin. have.

According to the said embodiment, since the said rib is formed in the wind fall side of the said pin, and the wind rise side of the said pin, it can be surely prevented that condensation water scatters from the said pin.

[Effects of the Invention]

According to the heat exchanger of the present invention, since the rib is formed in the fin, the rib forms a raceway by surface tension. Therefore, condensation water can be prevented from splashing out of the pin.

Further, according to the present invention, since 0.4 &lt; La, the center of the rib does not become too close to the insertion tube and the hole of the heat transfer tube, so that deformation does not occur at the edge of the fin or the rib. Moreover, since La <(L-D / 2-0.5), the center of the rib does not get too close to the heat transfer tube insertion position of the fin, and the rib does not deform.

Moreover, according to the heat exchanger of one embodiment, since 0.15 <LL <0.5, condensation water can flow down without a problem, and a deformation | transformation of a rib can be prevented more reliably. Moreover, since 0.05 <t <0.15, the intensity | strength of a fin can be made into no problem, the pin integration can be enlarged, and it can be made excellent in heat exchange efficiency. Moreover, since 0.5t <h <2.5t, the dew condensation water can flow down without a problem, and the wind can flow smoothly.

Moreover, according to the heat exchanger of one Embodiment, since the said heat exchanger is inclined with respect to the perpendicular direction in the state in which the said heat exchanger is arrange | positioned at the refrigeration apparatus of a use state, the dew condensation water which exists in the vicinity of the said outer edge which is easy to splash from a fin is It can be surely flowed downward through the said rib, and can surely prevent condensation water from bouncing off a pin.

The invention will be more fully understood from the following detailed description and the accompanying drawings. The accompanying drawings are for illustrative purposes only and do not limit the invention. In the drawings,

1 is a schematic cross-sectional view of an air conditioner using a heat exchanger of one embodiment of the present invention.

2A is a view showing in detail a part of the fin of the heat exchanger of the above embodiment.

2B is a view showing a part of the fin of the heat exchanger of the above embodiment in detail.

3A is a view showing an example of a rib formed in a pin.

3B is a view showing an example of a rib formed in the pin.

3C shows an example of a rib formed in a pin.

3D is a view showing an example of a rib formed in the pin.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail by the form of illustration.

1 is a schematic stage of an air conditioner using a heat exchanger according to an embodiment of the present invention. In FIG. 1, 1 is a blowing fan, 2 is a heat exchanger. In addition, in FIG. 1, arrow a shows the vertical direction upward in the state in which the heat exchanger is arrange | positioned at the air conditioner of a use state, and arrow b has shown the direction of the flow of the wind as a heat transfer medium. In FIG. 1, the case which accommodates the blower fan 1, the heat exchanger 2, etc. are abbreviate | omitted for simplicity.

This air conditioner rotates the blower fan 1, and blows the wind which sucked in through the heat exchanger 2 from a blower not shown in figure.

The heat exchanger 2 includes a fin 6 and a heat transfer tube (not shown). The pins 6 are arranged in multiple numbers at predetermined intervals in the direction perpendicular to the paper surface in FIG. The pin 6 has a flat plate shape. The pin 6 has a cross-sectional shape bent in a bracket (<) shape so that the vertical direction upwards indicated by the arrow a in FIG. 1 is a protruding portion.

The pin 6 has an outer edge that is inclined with respect to the vertical direction, and at the same time, the first portion 8 and the second portion 9 forming the bent portion, and the vertical direction of the second portion 9. It has the 3rd part 10 which continues below. As shown in FIG. 1, the first portion 8 is located downstream of the wind flow than the second portion 9. In addition, the third portion 10 extends substantially in the vertical direction. The said 1st part 8, the 2nd part 9, and the 3rd part 10 have the cross-sectional shape of substantially elongate rectangle.

The rib 15 extending in parallel with the longitudinal direction of the said 2nd part 9 is formed in the edge part of the wind fall side of the said 2nd part 9 in the longitudinal direction. In this embodiment, the pin 6 has a rectangular part in this way, and the rib 15 is extended along the outer periphery of the longitudinal direction of this rectangular part. The rib 15 guides the condensation water generated on the surface of the pin 6 to the vertical direction downward so that the condensation water does not bounce off the pin 6.

The said heat exchanger tube is arrange | positioned in multiple numbers. Each heat transfer tube extends in the arrangement direction of the fin 6, ie, the substantially normal direction (direction perpendicular to the ground in FIG. 1) of the surface of the plate-shaped fin 6. The heat transfer tube is inserted through a plurality of fins 6 arranged at predetermined intervals. As shown in FIG. 1, the insertion through holes for insertion of the heat transfer tube are alternately arranged in two rows in each of the first part 8, the second part 9, and the third part 10.

Specifically, the insertion holes are arranged in two rows in the width direction and 16 rows in the longitudinal direction in the first portion 8, and in the second portion 9, two rows and the lengths in the width direction. 12 rows are arranged in a direction. In the third portion 10, the insertion holes are arranged in two rows in the width direction and eight rows in the longitudinal direction.

Each row in the row of insertion holes and holes arranged in two rows in the width direction of the first portion 8 is substantially parallel to the outer edge of the first portion 8 in the longitudinal direction, and the second portion 9 Each row in the row of the insertion cylinder and the holes arranged in two rows in the width direction of the c) is substantially parallel to the outer edge of the second portion 9 in the longitudinal direction. Moreover, each row in the row of insertion holes and holes arranged in two rows in the width direction of the third portion 10 is substantially parallel to the outer edge of the longitudinal direction of the third portion 10.

Fluid is distributed inside the heat transfer tube. This heat exchanger performs heat exchange between the fluid which distribute | circulates in a heat exchanger tube, and the wind which distribute | circulates the outer side of a heat exchanger tube.

2 is a view showing in detail a part of the second portion 9 of the pin 6. In detail, FIG. 2A is a partial enlarged view of the second portion 9 of the pin 6. 2B is a part of sectional drawing of the (alpha) alpha line of FIG. 2A.

In FIG. 2A and FIG. 2B, 15 represents a rib, and 22 represents the insertion hole for the heat pipe insertion passage formed in the fin 6. In addition, the arrow b has shown the flow of wind in FIG. 2A. In addition, in FIG. 2A, for simplicity, only the inner diameter of the hole 22 is shown, and the detailed opening shape of a hole is abbreviate | omitted.

The rib 15 extends substantially parallel to the outer edge 25 of the plate-like pin 6. In addition, the plate-like fin 6 has an insertion tube and a hole 22 through which a plurality of heat transfer tubes are inserted. Moreover, the said rib 15 is arrange | positioned at the outer periphery 25 side rather than all the insertion through-holes 22.

In this embodiment, as shown in FIGS. 2A and 2B, the inner diameter of the insertion through hole 22 is set to D [mm], and the center of the insertion through hole 22 closest to the rib 15 and the outer edge thereof. When the distance to (25) is L [mm] and the center of the rib 15 and the distance between the outer edge 25 are La [mm], La is designed to satisfy the following formula (1). It is.

0.4 <La <(L-D / 2-0.5)... (One)

2B, the width of the rib 15 is LL [mm], the plate thickness of the pin 6 is t [mm], and the height of the rib 15 is h [mm]. In this case, the pins 6 and the ribs 15 are set to satisfy the following formulas (2), (3) and (4).

0.15 <LL <0.5... (2)

0.05 <t <0.15... (3)

0.5t <h <2.5t (4)

According to the heat exchanger of the said embodiment, the rib 15 formed in the edge of the wind of the 2nd part 9 which is a part of the said fin 6 forms the raceway by surface tension. Therefore, the dew condensation number which generate | occur | produced on the surface of the pin 6 can be guided below the perpendicular direction by the rib 15, and it can prevent that the condensation water jumps out of the pin 6.

Moreover, according to the heat exchanger of the said embodiment, since 0.4 <La, the center of the rib 15 does not become too close to the outer edge 25 of the fin 6, and the edge of the fin 6 and the rib 15 are not too close. ) Does not cause deformation. In addition, since La <(LD / 2-0.5), the center of the rib 15 does not become too close to the heat transfer tube insertion position (the heat transfer tube insertion passage insertion hole 22) of the fin 6, The rib 15 does not deform.

Therefore, the edge part of the pin 6 can be prevented from being deformed, and a person can be prevented from being wound at the outer edge of the pin 6. Moreover, since the rib 15 formed in the pin 6 does not deform | transform, it can prevent the part from which condensation water is hard to flow on the rib 15, and the dew condensation which generate | occur | produced on the surface of the pin 6 The water can flow down along the rib 15 quickly in the vertical direction. Therefore, since the ventilation resistance accompanying the reduction of the ventilation path | route of heat exchange of the fin 6 by retention of dew condensation water can be prevented, electrothermal performance can be improved.

Moreover, according to the heat exchanger of the said embodiment, since 0.15 <LL, the deformation | transformation of the rib 15 can be prevented more reliably, and since LL <0.5, condensation water can flow down without a problem. Moreover, since 0.05 <t, the strength of the fin 6 can be made into no problem, and since t <0.15, the integration of the fin 6 can be made large and the heat exchange efficiency can be made excellent. . Moreover, since 0.5t <h, condensation water can flow down without a problem, and since h <2.5t, the wind can prevent the wind from colliding with the rib 15 and generating turbulence, etc. You can smoothly flow.

Moreover, according to the heat exchanger of the said embodiment, since the outer edge 25 of the fin 6 is inclined with respect to the perpendicular direction in the state which the fin 6 is arrange | positioned at the refrigeration apparatus of a use state, it jumps from the fin 6 The dew condensation water which exists in the vicinity of the easy outer edge 25 can be surely flowed downward through the rib 15. Therefore, it is possible to surely prevent condensation water from splashing from the pin.

Moreover, according to the heat exchanger of the said embodiment, since the said rib 15 is formed in the edge part of the downwind side in the fin 6, the dew condensation which generate | occur | produced on the fin 6 blows in wind and bounces off from a fin. It can certainly be prevented.

Moreover, when the heat exchanger 2 of the said embodiment is incorporated in the indoor unit of an air conditioner, the phenomenon which a water droplet splashes in the room can be prevented reliably.

Moreover, when the inner diameter D of the said insertion hole 22 is 7.5 mm or less, since the ventilation resistance is small, it exists in the operating situation which the water flow with a large quantity of air tends to occur. However, since the ribs 15 of the said shape and arrangement are provided in the said pin 6, even if it puts in the driving situation by a large amount of air volume, it can reliably prevent the water from the fin 6 from splashing.

Moreover, in the heat exchanger of the said embodiment, as shown to FIG. 2B, one surface 27 of the plate-shaped fin 6 so that the rib 15 may satisfy | fill said Formula (1)-(4) Formula. Although it was formed so as to protrude from, in this invention, even if it is formed so that several rib which satisfy | fills said Formula (1) (preferably said (1)-(4) Formula) may protrude from one surface of a plate-shaped pin, do. In addition, a plurality of ribs satisfying the above formula (1) (preferably the above formulas (1) to (4)) are provided with both surfaces of the plate-like pin (for example, the surface 27 in FIG. 2B). And the surface 28).

Moreover, in the heat exchanger of the said embodiment, the one rib 15 substantially parallel to the outer edge 25 was formed only in the side of the wind direction of the 2nd part 9 in the width direction. However, in this invention, in order to satisfy said Formula (1) (preferably said Formula (1)-(4) Formula), the one or several rib which is substantially parallel to an outer periphery on the wind fall side of the width direction of a 2nd part is provided. In addition to the installation, one or more ribs substantially parallel to the outer edge of the first portion are provided on the wind up side in the width direction of the first portion, and the outer edge of the first portion on the wind down side in the width direction of the first portion. May be provided with one or more ribs substantially parallel, and may provide one or more ribs substantially parallel to the outer periphery of a 3rd part in the wind fall side of the width direction of a 3rd part. In this case, condensation water splashing from the pin 6 can be prevented reliably.

Moreover, in the heat exchanger of the said embodiment, although the heat exchanger tube was arrange | positioned to the 2nd part 9 by 2 rows in the width direction, one rib was formed in the airflow side of the 2nd part 9, but of this invention In the heat exchanger, the heat transfer tubes are alternately arranged in at least a portion of the fin in a plurality of rows in three rows or more in a single row arrangement or in the width direction, and the edge portion in the longitudinal direction in at least a portion of the fin is (1). You may form one or more rib which satisfy | fills Formula (preferably said (1)-(4) Formula).

For example, as shown in FIG. 3A, the heat transfer tube insertion holes are arranged in the width direction in the fin 30, and at the downstream side of the flow of wind shown by the arrow c in the fin 30. In the longitudinal edge portion, one rib 32 substantially parallel to the outer edge of the edge portion may be formed. Moreover, as shown in FIG. 3B, the heat-transfer tube insertion hole is arrange | positioned in the width direction in the fin 40, and the longitudinal direction of the upstream of the wind flow shown by the arrow d in the fin 40 is shown. In the edge portion of the edge portion, one rib 42 substantially parallel to the outer edge of the edge portion may be formed. In addition, as shown in FIG. 3C, the heat pipe insertion through-holes are arranged in the width direction in the fin 50, and the upstream and downstream sides of the wind flow indicated by the arrow e in the fin 50. Each of the ribs 52, 53 that is substantially parallel to the outer edge of the edge portion may be formed at the edge portion in the longitudinal direction of the edge portion. As shown in Fig. 3D, the heat transfer tube insertion holes are alternately arranged in the fins in two rows in the width direction, and the upstream side of the wind flow indicated by the arrow f in the fins 60 and Each of the ribs 62, 63 substantially parallel to the outer edge of these edge portions may be formed at the edge portion in the longitudinal direction on the downstream side.

Moreover, in the heat exchanger of the said embodiment, although the rib 15 was formed in the substantially whole edge part of the wind fall side of the 2nd part 9, in this invention, only in a part of the edge part of the wind fall side of a 2nd part, An approximately parallel rib may be provided only on a part of the outer edge of the pin, such as providing a rib substantially parallel to the outer edge of this part.

Moreover, in the heat exchanger of the said embodiment, although the fin 6 consists of the 1st part 8 and the 2nd part 9 which form the bending part, and the 3rd part 10, in this invention, a rib is The pin to be formed may be any shape, not limited to the shape of this embodiment, such as being composed of one plate having an equilibrium or arc-shaped cross-sectional shape.

Moreover, in the heat exchanger of the said embodiment, as shown to FIG. 2B, although the groove | channel 29 of a trapezoid of cross section is formed in the back side of the part in which the rib 15 is formed, in this invention, the rib is formed, In the back of the portion, grooves other than the grooves on the trapezoid in cross section, such as grooves having a V-shaped cross section or U-shaped cross-section, may be formed. Moreover, it is not necessary to form a groove behind the part in which the rib is formed.

Moreover, in the heat exchanger of the said embodiment, although the some insertion hole and the hole 22 were arrange | positioned alternately in the fin 6, in this invention, a some insertion into a fin is carried out, for example, lattice arrangement of the some insertion hole and the hole in a fin. You may arrange | position a through hole by arrangement methods other than staggered arrangement.

Moreover, in the heat exchanger of the said embodiment, although the fold part is not formed in the fin 6, in the heat exchanger of this invention, for example, a c-shaped incision line is put in a part of fin and a fold piece is carried out. You may install When the folds are formed on the fins, the heat exchange efficiency is high, while unevenness of the ventilation resistance occurs at and without the folds, resulting in uneven wind speed distribution, and water splashes at high wind speeds. This occurs. However, in the heat exchanger of this invention, water can be prevented from splashing reliably by the rib of the said shape and arrangement. Therefore, the heat exchange efficiency can be improved and water can also be prevented from splashing out of the fins.

In the heat exchanger of the present invention, ribs may be formed on all of the plurality of fins. In addition, a rib may be formed only in a part of the plurality of fins, or a fin without ribs may be present.

As mentioned above, although embodiment of this invention was described, it is clear that this may be changed in various ways. Such changes should not be seen as departures from the spirit and scope of the invention, and all obvious changes to those skilled in the art are intended to be included within the scope of the following claims.

Although the heat exchanger of this invention was applied to the air conditioner in the said embodiment, of course, you may apply the heat exchanger of this invention to refrigeration apparatuses other than an air conditioner, such as a refrigerator.

Claims (6)

A plurality of heat pipes, And having a rib 15 parallel to the outer edge 25, and having a plate-like pin 6 having an insertion hole and a hole 22 through which the plurality of heat transfer tubes are inserted. The ribs 15 are arranged on the outer edge 25 side than all the insertion holes 22, The inner diameter of the insertion hole 22 is D [mm], and the distance between the center of the insertion hole 22 closest to the rib 15 and the outer edge 25 is L [mm]. When the distance between the center of the rib 15 and the outer edge 25 is La [mm], 0.4 <La <(L-D / 2-0.5) Heat exchanger characterized in that the. The method according to claim 1, When the width of the rib 15 is LL [mm], the plate thickness of the pin 6 is t [mm], and the height of the rib 15 is h [mm], 0.15 <LL <0.5, 0.05 <t <0.15, And 0.5t <h <2.5t. The method according to claim 1, The heat exchanger, characterized in that the outer edge (25) is inclined with respect to the vertical direction, with the fins (6) arranged in the refrigeration apparatus in use. The method according to claim 3, And the heat exchanger is built in an indoor unit of the air conditioner. The method according to claim 3, And the inner diameter (D) of the insertion hole (22) is 7.5 mm or less. The method according to claim 3, The fin is provided with a fold up portion.

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