JP6189263B2 - Fin for heat exchanger and heat exchanger provided with the same - Google Patents

Description

  The present invention relates to a heat exchanger fin and a heat exchanger provided with the same.

  In general, a heat exchanger includes heat exchanger fins arranged in parallel with each other at a predetermined interval, heat transfer tubes arranged in a plurality of rows through the heat exchanger fins in the normal direction, and the like. And heat exchange is performed by the heat transfer effect between the air which flows between the fins for adjacent heat exchangers, and the liquid medium which flows through the inside of the heat transfer tube.

  As described in Patent Document 1, a conventional heat exchanger fin is provided with a plurality of slit groups that are cut and raised on the front and back surfaces so as to have an opening of a predetermined height toward the air flow. It has been. In order to reduce ventilation resistance, each slit group has slits adjacent to each other in the air flow direction cut in the reverse direction with respect to the heat exchanger fins, and is formed in a staircase shape.

JP 2003-161588 A

  However, the slit group of the fins for heat exchangers of Patent Document 1 is formed in a staircase shape in which slits adjacent to each other in the air flow direction are cut and raised in opposite directions with reference to the fins for heat exchangers. Therefore, when the air flow hits the first slit on the upstream side, the subsequent air flow hardly hits the slit located on the downstream side, and becomes layered (rectified).

  Here, heat transfer is performed in a temperature boundary layer (boundary layer) formed around the slit. Therefore, the heat transfer effect on the air flow side by the slit is significantly reduced if the number of times the air flow hits the slit is small. As a result, the fin for the heat exchanger of Patent Document 1 has a problem that the heat transfer effect is low.

  Therefore, a main object of the present invention is to provide a heat exchanger fin having a high heat transfer effect and a heat exchanger including the same.

The heat exchanger fin according to the present invention is:
A heat sink,
A plurality of heat transfer tube opening holes for heat transfer tubes penetrating the heat sink;
A plurality of slits opened toward the air flow and cut and raised only on one main surface of the heat sink;
The multiple rows of slits are uneven in the height of the multiple rows of slits, because the height of the slits adjacent to the traveling direction of the air flow is different in three or more stages .
The adjacent slits are arranged outside the range of the temperature boundary layer of each slit,
The plurality of rows of slits are arranged between the front edge and the rear edge of the heat sink in the air flow direction, and are axisymmetric with respect to the vertical center line of the opening hole for the heat transfer tube,
The plurality of rows of slits are gradually shorter from the front edge of the heat radiating plate toward the vertical center line of the opening hole for the heat transfer tube, and are arranged without any interval in front view, and the opening hole for the heat transfer tube Gradually longer from the vertical center line toward the rear edge of the heat sink, and in front view, without any spacing,
Vertical center line of the aperture holes for heat transfer tubes is parallel to a direction perpendicular to a flow direction of air, and, parallel der Rukoto to the extending direction of the slit,
It is the fin for heat exchangers characterized by these.
The height of the slits in the plurality of rows is uneven. I mean.

Moreover, the fin for the heat exchanger according to the present invention is
The opening hole for the heat transfer tube has an annular heat transfer tube support frame portion standing up from the hole edge and inscribed in the heat transfer tube, and a stepped annular portion disposed around the annular heat transfer tube support frame portion. And
The annular heat transfer tube support frame has a large-diameter circumferential surface portion in the lower half, a small-diameter circumferential surface portion in the upper half, and a step portion connecting the large-diameter circumferential surface portion and the small-diameter circumferential surface portion. The inner diameter of the peripheral surface is set to be substantially smaller than the outer diameter of the heat transfer tube,
At least one end of the plurality of rows of slits reaches the stepped annular portion of the opening hole for the heat transfer tube, and the shape of the end surface matches the arc shape of the stepped annular portion,
The annular heat transfer tube support frame portion and the stepped annular portion are provided on the other main surface of the heat radiating plate opposite to the one main surface of the heat radiating plate provided with a plurality of rows of slits. It is a fin for heat exchangers.

Moreover, the heat exchanger according to the present invention is
The aforementioned heat exchanger fins arranged at predetermined intervals;
Heat transfer tubes arranged in multiple rows through the heat exchanger fins;
The heat exchanger is characterized by comprising:

  According to the present invention, since the heights of the slits adjacent to each other in the traveling direction of the air flow are uneven, the heights of the slits in the plurality of rows are uneven, so that the number of times the air flow hits the slit increases. A heat exchanger fin having a high thermal effect can be obtained.

  Further, according to the present invention, the plurality of rows of slits are axisymmetric with respect to the vertical center line of the heat transfer tube opening hole in the air flow direction, so that the heat transfer effect is substantially equal to the entire heat exchanger fin. To be demonstrated. Further, since the plurality of rows of slits are line symmetric with respect to the vertical center line of the heat transfer tube opening hole, when the heat exchanger fin is inserted into the heat transfer tube, the heat exchange fin is inserted in the direction of heat exchange. Even if the leading edge and the trailing edge of the fin for the equipment are inserted reversely, the arrangement of the slits in the plurality of rows with respect to the air flow does not change at all, so the manufacture of the heat exchanger can be performed with respect to the heat exchanger tube of the fin for the heat exchanger. This can be done without worrying about the direction of insertion.

  Moreover, according to this invention, since it has an annular heat exchanger tube support frame part, the fins for heat exchangers can be reliably arranged at a predetermined interval. Further, since the stepped annular portion is provided, the stress applied to the heat exchanger fins can be dispersed throughout the heat exchanger fins, and the mechanical stress applied to the heat exchanger fins can be alleviated.

  Moreover, according to this invention, it becomes a heat exchanger with a high heat-transfer effect.

  The above-described object, other objects, features, and advantages of the present invention will become more apparent from the following description of embodiments for carrying out the invention with reference to the drawings.

It is a front view which shows 1st Embodiment of the fin for heat exchangers which concerns on this invention. It is a top view of the fin for heat exchangers shown in FIG. It is a right view of the fin for heat exchangers shown in FIG. It is AA sectional drawing of FIG. It is BB sectional drawing of FIG. It is a top view for demonstrating the assembly | attachment of the fin for heat exchangers. It is a right view which shows the state after the assembly | attachment of the fin for heat exchangers. It is a schematic diagram for demonstrating the heat-transfer effect of the fin for heat exchangers. It is a front view which shows 2nd Embodiment of the fin for heat exchangers which concerns on this invention. It is a top view of the fin for heat exchangers shown in FIG. It is a right view of the fin for heat exchangers shown in FIG.

1. First Embodiment FIG. 1 is a front view showing a first embodiment of a heat exchanger fin according to the present invention. FIG. 2 is a top view of the heat exchanger fin shown in FIG. 1. FIG. 3 is a right side view of the fin for the heat exchanger shown in FIG. 4 is a cross-sectional view taken along line AA in FIG. 5 is a cross-sectional view taken along the line BB in FIG.

(1) Heat exchanger The heat exchanger includes the heat exchanger fins 10 shown in FIG. 1 arranged at predetermined intervals, the heat transfer tubes 12 arranged in a plurality of rows through the heat exchanger fins 10, and It has. The liquid medium flows inside the heat transfer tube 12, and the air flow 14 flows in the direction of the arrow between adjacent heat exchanger fins 10. The axial direction of the heat transfer tube 12 is parallel to the normal direction of the heat exchanger fins 10 and is orthogonal to the flow direction of the air flow 14. In the heat exchanger, heat is exchanged by the heat transfer effect between the air flow 14 flowing between the adjacent heat exchanger fins 10 and the liquid medium flowing in the heat transfer tube 12. The liquid medium is, for example, heat transfer oil, warm water, cooling water, refrigerant liquid, or the like.

  The heat transfer tube 12 is formed by molding a metal material such as stainless steel, aluminum, or copper. The heat exchanger fin 10 is obtained by pressing a metal material such as stainless steel, aluminum, or copper.

(2) Heat Exchanger Fin The heat exchanger fin 10 includes a long heat sink 20, a first heat transfer tube opening 22 a for the heat transfer tube 12 that penetrates the heat sink 20, and a second heat transfer tube opening. The holes 22b and a plurality of rows of first slit group 3a to third slit group 3c that open toward the flow of the air flow 14 and are cut and raised only on one main surface 20a of the heat radiating plate 20 are provided. .

  The first slit group 3a includes a first slit 31a to an eighth slit 38a. The first slit group 3 a is disposed between the first heat transfer tube opening hole 22 a and the short side of the heat sink 20. The first slit 31a to the eighth slit 38a are formed between the front edge (upstream edge of the airflow 14) and the rear edge (downstream edge of the airflow 14) of the heat exchanger fin 10 in the flow direction of the airflow 14. Each of the first slit 31 a to the eighth slit 38 a extends in the longitudinal direction of the heat sink 20.

  The lengths of the first slit 31a to the fourth slit 34a are gradually shortened from the front edge of the heat exchanger fin 10 toward the vertical center line L1 (described later) of the heat transfer tube opening holes 22a and 22b. On the other hand, the lengths of the fifth slit 35a to the eighth slit 38a are gradually increased from the vertical center line L1 of the heat transfer tube opening holes 22a and 22b toward the rear edge of the heat exchanger fin 10. The length of the first slit 31a to the eighth slit 38a makes it easy to generate turbulence of the air flow 14.

  The 1st slit 31a-the 4th slit 34a are arrange | positioned at the front edge side of the fin 10 for heat exchangers. The fifth slit 35a to the eighth slit 38a are disposed on the rear edge side of the heat exchanger fin 10. The first slit 31a to the fourth slit 34a and the fifth slit 35a to the eighth slit 38a are spaced apart from each other with the plane portion 39a therebetween.

  One end of each of the first slit 31 a to the eighth slit 38 a reaches the short side of the heat sink 20. The other end of each of the first slit 31a to the eighth slit 38a reaches the stepped annular portion 50 of the first heat transfer tube opening hole 22a, and the shape of the end surface thereof is the stepped annular portion 50 ( It matches the arc shape (described later).

  The first slit 31a to the fourth slit 34a and the fifth slit 35a to the eighth slit 38a are axisymmetric with respect to the vertical center line L1 of the heat transfer tube opening holes 22a and 22b. Here, the vertical center line L1 of the opening holes 22a and 22b for the heat transfer tubes is parallel to the direction orthogonal to the flow direction of the air flow 14, and in the extending direction of the first slit 31a to the eighth slit 38a. Parallel to it.

  The second slit group 3b includes a first slit 31b to an eighth slit 38b. The second slit group 3b is disposed between the first heat transfer tube opening hole 22a and the second heat transfer tube opening hole 22b. The first slit 31b to the eighth slit 38b are sequentially arranged between the front edge and the rear edge of the heat exchanger fin 10 in the flow direction of the air flow 14, and each of the first slit 31b to the eighth slit 38b is The heat radiating plate 20 extends in the longitudinal direction.

  The lengths of the first slit 31b to the fourth slit 34b are gradually shortened from the front edge of the heat exchanger fin 10 toward the vertical center line L1. On the other hand, the lengths of the fifth slit 35b to the eighth slit 38b are gradually increased from the vertical center line L1 toward the rear edge of the heat exchanger fin 10. The length of the first slit 31b to the eighth slit 38b makes it easy to generate turbulent air flow 14.

  The 1st slit 31b-the 4th slit 34b are arrange | positioned at the front edge side of the fin 10 for heat exchangers. The fifth slit 35b to the eighth slit 38b are arranged on the rear edge side of the heat exchanger fin 10. The first slit 31b to the fourth slit 34b and the fifth slit 35b to the eighth slit 38b are spaced apart from each other with the plane portion 39b therebetween.

  One end of each of the first slit 31b to the eighth slit 38b reaches the stepped annular portion 50 of the first heat transfer tube opening hole 22a, and the shape of the end surface thereof is that of the stepped annular portion 50. It matches the arc shape. The other end of each of the first slit 31b to the eighth slit 38b reaches the stepped annular portion 50 of the second heat transfer tube opening hole 22b, and the shape of the end surface thereof is the same as that of the stepped annular portion 50. It matches the arc shape.

  The first slit 31b to the fourth slit 34b and the fifth slit 35b to the eighth slit 38b are line symmetric with respect to the vertical center line L1 of the heat transfer tube opening holes 22a and 22b.

  The third slit group 3c includes a first slit 31c to an eighth slit 38c. The third slit group 3c is disposed between the second heat transfer tube opening hole 22b and the third heat transfer tube opening hole (not shown). The first slit 31c to the eighth slit 38c are sequentially arranged between the front edge and the rear edge of the heat exchanger fin 10 in the flow direction of the air flow 14, and each of the first slit 31c to the eighth slit 38c is The heat radiating plate 20 extends in the longitudinal direction.

  The lengths of the first slit 31c to the fourth slit 34c are gradually shortened from the front edge of the heat exchanger fin 10 toward the vertical center line L1. On the other hand, the lengths of the fifth slit 35c to the eighth slit 38c are gradually increased from the vertical center line L1 toward the rear edge of the heat exchanger fin 10. The length of the first slit 31c to the eighth slit 38c makes it easy to generate turbulent air flow 14.

  The 1st slit 31c-the 4th slit 34c are arrange | positioned at the front edge side of the fin 10 for heat exchangers. The fifth slit 35 c to the eighth slit 38 c are disposed on the rear edge side of the heat exchanger fin 10. The first slit 31c to the fourth slit 34c and the fifth slit 35c to the eighth slit 38c are separated from each other with the plane portion 39c therebetween.

  One end of each of the first slit 31 c to the eighth slit 38 c reaches the stepped annular portion 50 of the second heat transfer tube opening hole 22 b, and the shape of the end surface thereof is that of the stepped annular portion 50. It matches the arc shape. The other end of each of the first slit 31 c to the eighth slit 38 c reaches the stepped annular portion 50 of the third heat transfer tube opening hole, and the shape of the end surface is the arc of the stepped annular portion 50. Matches the shape.

  The first slit 31c to the fourth slit 34c and the fifth slit 35c to the eighth slit 38c are line symmetric with respect to the vertical center line L1 of the heat transfer tube opening holes 22a and 22b.

  As shown in FIG. 4, in the first slit group 3 a to the third slit group 3 c, the slit adjacent in the traveling direction of the air flow 14 is cut and raised only on one main surface 20 a of the heat radiating plate 20. And the cut-and-raised height of each slit of the 1st slit group 3a-the 3rd slit group 3c is uneven because the cut-and-raised height of an adjacent slit differs. That is, it means that the slits of the first slit group 3a to the third slit group 3c do not change gradually lower or change gradually higher.

  The cut and raised heights of the first slits 31a to 31c and the eighth slits 38a to 38c are set to h1. The cut and raised heights of the second slits 32a to 32c and the seventh slits 37a to 37c are set to h2. The cut and raised heights of the third slits 33a to 33c and the sixth slits 36a to 36c are set to h3. The cut and raised heights of the fourth slits 34a to 34c and the fifth slits 35a to 35c are set to h4. In the first embodiment, h3> h1> h4> h2. As described above, the heights of h1, h2, h3, and h4 are all different.

  In the first embodiment, the height h1 of the first slits 31a to 31c and the eighth slits 38a to 38c, the height h2 of the second slits 32a to 32c and the seventh slits 37a to 37c, the third slit The height h3 of 33a to 33c and the sixth slits 36a to 36c and the height h4 of the fourth slits 34a to 34c and the fifth slits 35a to 35c are set to four heights, but are not limited thereto. Instead, the first slits 31a to 31c to the eighth slits 38a to 38c may be set to have different heights in eight stages. In the first embodiment, as described above, the plurality of slits formed in each slit group is not limited to four steps or eight steps, and the height of the cuts of at least three or more slits is raised. Is preferably formed.

  In addition, the widths W of the first slit group 3a to the third slit group 3c in the direction in which the air flow 14 flows are all equal.

  As shown in FIG. 5, the shapes of the slits of the first slit group 3 a to the third slit group 3 c viewed from the upstream side of the air flow 14 are substantially trapezoidal.

  As shown in FIG. 4, each of the first heat transfer tube opening hole 22 a and the second heat transfer tube opening hole 22 b rises from the hole edge and is inscribed in the heat transfer tube 12. And a stepped annular part 50 disposed around the annular heat transfer tube support frame part 40. The annular heat transfer tube support frame portion 40 and the stepped annular portion 50 are provided on the other main surface 20b opposite to the one main surface 20a of the heat radiating plate 20 provided with the plurality of rows of slit groups 3a to 3c. It has been.

  The annular heat transfer tube support frame portion 40 includes a lower half large-diameter circumferential surface portion 42, an upper half small-diameter circumferential surface portion 46, and a stepped portion 44 connecting the large-diameter circumferential surface portion 42 and the small-diameter circumferential surface portion 46. ,have. The inner diameter of the small-diameter circumferential surface portion 46 is set to be substantially smaller than the outer diameter of the heat transfer tube 12. Then, by inserting the heat transfer tube 12 into the small diameter circumferential surface portion 46, the outer peripheral surface of the heat transfer tube 12 and the inner peripheral surface of the small diameter circumferential surface portion 46 are joined, and the heat transfer tube 12 and the heat exchanger fins 10 Is fixed.

  On the other hand, the inner diameter of the large-diameter circumferential surface portion 42 is set slightly larger than the outer diameter of the small-diameter circumferential surface portion 46. As shown in FIG. 6, the large-diameter circumferential surface portion 42 has a small-diameter circumferential surface portion 46 of the annular heat transfer tube support frame portion 40 of the adjacent heat exchanger fin 10, and the step-diameter portion 44 has a small-diameter circumferential surface portion 46. It can be inserted until the tip of the abuts. Therefore, the adjacent heat exchanger fins 10 can be reliably arranged at predetermined intervals.

  Further, since the stepped annular portion 50 is provided, the stress applied to the heat exchanger fins 10 can be dispersed throughout the heat exchanger fins 10 to reduce the mechanical stress applied to the heat exchanger fins 10. it can.

  Angle-shaped ribs 80 and 81 are provided on the front and rear edges of the long heat sink 20, respectively. The ribs 80 and 81 extend in the length direction of the heat radiating plate 20 (the direction parallel to the vertical center line L1 of the heat transfer tube opening holes 22a and 22b) to improve the bending rigidity of the long heat radiating plate 20. I am letting.

  Furthermore, the guide pin hole 84 formed in the extending direction of the ribs 80 and 81 at the position of the ribs 80 and 81 is a guide pin for feeding the heat exchanger fins 10 in the manufacturing process of the heat exchanger. It is a hole for insertion.

  The heat exchanger fin 10 having the above configuration is different in the cut-and-raised height of the adjacent slits of the first slit group 3a to the third slit group 3c with respect to the traveling direction of the air flow 14, Since the cut and raised heights of the respective slits of the first slit group 3a to the third slit group 3c are uneven, the number of times the air flow 14 hits the slit increases, and the heat exchanger fin 10 having a high heat transfer effect is provided. Can be obtained.

The heat transfer effect of the heat exchanger fin 10 will be described in more detail with reference to FIG.
For example, the second slit 32b adjacent to the downstream side of the first slit 31b with respect to the flow direction of the air flow 14 is set to be disposed outside the temperature boundary layer of the first slit 31b. The third slit 33b adjacent to the downstream side of the second slit 32b is set to be disposed outside the temperature boundary layer of the second slit 32b. The fourth slit 34b adjacent to the downstream side of the third slit 33b is set to be disposed outside the temperature boundary layer of the third slit 33b.

  Similarly, the sixth slit 36b adjacent to the downstream side of the fifth slit 35b with respect to the flow direction of the air flow 14 is set to be disposed outside the temperature boundary layer of the fifth slit 35b. . The seventh slit 37b adjacent to the downstream side of the sixth slit 36b is set to be disposed outside the temperature boundary layer of the sixth slit 36b. The eighth slit 38b adjacent to the downstream side of the seventh slit 37b is set to be disposed outside the temperature boundary layer of the seventh slit 37b.

  When the air flow 14 hits the first slit 31b or the second slit 32b of the second slit group 3b, the air flow 14 is divided into the divided flow 14a and the divided flow 14b by the first slit 31b and the second slit 32b, respectively.

  The divided flow 14a divided by the first slit 31b and the divided flow 14b divided by the second slit 32b merge and further hit a fourth slit 34b disposed downstream with respect to the flow direction of the air flow 14. The fourth slit 34b divides the merge of the divided flow 14a divided by the first slit 31b and the divided flow 14b divided by the second slit 32b into the divided flow 14a and the divided flow 14b.

  The divided flow 14b divided by the first slit 31b further hits a third slit 33b disposed downstream with respect to the flow direction of the air flow 14. The third slit 33b divides the divided flow 14b divided by the first slit 31b into a divided flow 14a and a divided flow 14b. Thus, the air flow 14 is divided every time it hits the first slit 31b to the eighth slit 38b as it flows downstream.

  Here, since the first slit 31b to the eighth slit 38b are different in the cut and raised heights of the adjacent slits, the number of times the air flow 14 hits the first slit 31b to the eighth slit 38b increases. . As a result, the air flow 14 around the slit is disturbed, and the heat exchanger fin 10 having a high heat transfer effect can be obtained.

  Further, since each of the first slit group 3a to the third slit group 3c is axisymmetric with respect to the vertical center line L1 of the heat transfer tube opening holes 22a and 22b in the flow direction of the air flow 14, the heat transfer effect. Is exerted substantially evenly on the entire heat exchanger fin 10. Further, each of the first slit group 3a to the third slit group 3c is axisymmetric with respect to the vertical center line L1 of the heat transfer tube opening holes 22a and 22b. When the heat exchanger fins 10 are inserted, the first slit group 3a to the third slit with respect to the flow of the air flow 14 even if the front and rear edges of the heat exchanger fins 10 are inserted in reverse. Since the arrangement of the groups 3c does not change at all, the heat exchanger can be manufactured without worrying about the direction in which the heat exchanger fins 10 are inserted into the heat transfer tubes 12.

  As a result, the heat exchanger using the heat exchanger fins 10 becomes a heat exchanger having a high heat transfer effect.

2. Second Embodiment FIG. 9 is a front view showing a second embodiment of the fin for a heat exchanger according to the present invention. FIG. 10 is a top view of the heat exchanger fin shown in FIG. FIG. 11 is a right side view of the heat exchanger fin shown in FIG. 9.

  The heat exchanger fin 110 according to the second embodiment includes a first heat transfer tube opening hole 122a and a second heat transfer tube opening hole 122b, a third heat transfer tube opening hole 122c, and a fourth heat transfer tube opening hole 122d. Are formed in a two-row alignment in the longitudinal direction of the long heat sink 120 with the central plane portion 160 therebetween. The heat exchanger fin 110 is formed by pressing a metal material such as aluminum, stainless steel, or copper.

  The heat exchanger fin 110 includes a long heat sink 120, first heat transfer pipe opening holes 122 a to 122 d for heat transfer pipes 112 penetrating the heat sink 120, and an air flow 114. And a plurality of rows of first slit groups 103a to 103f cut and raised only on one main surface 120a of the heat sink 120.

  The first slit group 103a includes a first slit 131a to an eighth slit 138a. The first slit group 103 a is disposed between the first heat transfer tube opening hole 122 a and the short side of the heat sink 120. The first slit 131a to the eighth slit 138a are sequentially arranged between the front edge of the heat exchanger fin 110 (upstream edge of the air flow 114) and the flat portion 160 in the flow direction of the air flow 114, Each of the slit 131 a to the eighth slit 138 a extends in the longitudinal direction of the heat sink 120.

  The lengths of the first slit 131a to the fourth slit 134a are gradually shortened from the front edge of the heat exchanger fin 110 toward the vertical center line L11 (described later) of the heat transfer tube opening holes 122a and 122b. On the other hand, the lengths of the fifth slit 135a to the eighth slit 138a are gradually increased from the vertical center line L11 toward the flat portion 160 of the heat exchanger fin 110. The length of the first slit 131a to the eighth slit 138a makes it easy to generate turbulent air flow 114.

  The first slit 131a to the fourth slit 134a are arranged on the front edge side of the heat exchanger fin 110. The 5th slit 135a-the 8th slit 138a are arrange | positioned at the plane part 160 side of the fin 110 for heat exchangers. The first slit 131a to the fourth slit 134a and the fifth slit 135a to the eighth slit 138a are separated from each other with the plane portion 139a interposed therebetween.

  One end of each of the first slit 131 a to the eighth slit 138 a reaches the short side of the heat sink 120. The other end of each of the first slit 131a to the eighth slit 138a reaches the stepped annular portion 150 of the first heat transfer tube opening hole 122a, and the shape of the end surface thereof is the stepped annular portion 150 ( It matches the arc shape (described later).

  The first slit 131a to the fourth slit 134a and the fifth slit 135a to the eighth slit 138a are line symmetric with respect to the vertical center line L11 of the heat transfer tube opening holes 122a and 122b. Here, the vertical center line L11 of the heat transfer tube opening holes 122a and 122b is parallel to a direction orthogonal to the flow direction of the air flow 114 and extends in the extending direction of the first slit 131a to the eighth slit 138a. Parallel to it.

  The second slit group 103b includes a first slit 131b to an eighth slit 138b. The second slit group 103b is disposed between the first heat transfer tube opening hole 122a and the second heat transfer tube opening hole 122b. The first slit 131b to the eighth slit 138b are sequentially arranged between the front edge of the heat exchanger fin 110 and the flat portion 160 in the flow direction of the air flow 114, and each of the first slit 131b to the eighth slit 138b. Extends in the longitudinal direction of the heat sink 120.

  The lengths of the first slit 131b to the fourth slit 134b are gradually shortened from the front edge of the heat exchanger fin 110 toward the vertical center line L11. On the other hand, the lengths of the fifth slit 135b to the eighth slit 138b are gradually increased from the vertical center line L11 toward the plane portion 160 of the heat exchanger fin 110. The length of the first slit 131b to the eighth slit 138b makes it easy to generate turbulent air flow 114.

  The first slit 131b to the fourth slit 134b are arranged on the front edge side of the heat exchanger fin 110. The 5th slit 135b-the 8th slit 138b are arrange | positioned at the plane part 160 side of the fin 110 for heat exchangers. The first slit 131b to the fourth slit 134b and the fifth slit 135b to the eighth slit 138b are separated from each other with the plane portion 139b interposed therebetween.

  One end of each of the first slit 131b to the eighth slit 138b reaches the stepped annular portion 150 of the first heat transfer tube opening hole 122a, and the shape of the end surface of the first slit 131b to the eighth slit 138b is that of the stepped annular portion 150. It matches the arc shape. The other end of each of the first slit 131b to the eighth slit 138b reaches the stepped annular portion 150 of the second heat transfer tube opening 122b, and the shape of the end surface of the first slit 131b to the eighth slit 138b is that of the stepped annular portion 150. It matches the arc shape.

  The first slit 131b to the fourth slit 134b and the fifth slit 135b to the eighth slit 138b are line symmetric with respect to the vertical center line L11 of the heat transfer tube opening holes 122a and 122b.

  The third slit group 103c includes a first slit 131c to an eighth slit 138c. The third slit group 103c is disposed between the second heat transfer tube opening hole 122b and the fifth heat transfer tube opening hole (not shown). The first slit 131c to the eighth slit 138c are sequentially arranged between the front edge of the heat exchanger fin 110 and the flat portion 160 in the flow direction of the air flow 114, and each of the first slit 131c to the eighth slit 138c. Extends in the longitudinal direction of the heat sink 120.

  The lengths of the first slit 131c to the fourth slit 134c are gradually shortened from the front edge of the heat exchanger fin 110 toward the vertical center line L11. On the other hand, the lengths of the fifth slit 135c to the eighth slit 138c are gradually increased from the vertical center line L11 toward the flat portion 160 of the heat exchanger fin 110. The length of the first slit 131c to the eighth slit 138c makes it easy to generate turbulent air flow 114.

  The 1st slit 131c-the 4th slit 134c are arrange | positioned at the front edge side of the fin 110 for heat exchangers. The 5th slit 135c-the 8th slit 138c are arrange | positioned at the plane part 160 side of the fin 110 for heat exchangers. The first slit 131c to the fourth slit 134c and the fifth slit 135c to the eighth slit 138c are separated from each other with the plane portion 139c therebetween.

  One end of each of the first slit 131 c to the eighth slit 138 c reaches the stepped annular portion 150 of the second heat transfer tube opening hole 122 b, and the shape of the end surface thereof is the stepped annular portion 150. It matches the arc shape. The other end of each of the first slit 131c to the eighth slit 138c reaches the stepped annular portion 150 of the fifth heat transfer tube opening hole, and the shape of the end surface is the arc of the stepped annular portion 150. Matches the shape.

  The first slit 131c to the fourth slit 134c and the fifth slit 135c to the eighth slit 138c are line symmetric with respect to the vertical center line L11 of the heat transfer tube opening holes 122a and 122b.

  The fourth slit group 103d includes a first slit 131d to an eighth slit 138d. The fourth slit group 103 d is disposed between the third heat transfer tube opening hole 122 c and the short side of the heat sink 120. The first slit 131d to the eighth slit 138d are sequentially arranged between the flat portion 160 of the heat exchanger fin 110 and the rear edge (the downstream edge of the air flow 114) in the flow direction of the air flow 114. Each of the slits 131d to 138d extends in the longitudinal direction of the heat sink 120.

  The lengths of the first slit 131d to the fourth slit 134d are gradually shortened from the flat portion 160 of the heat exchanger fin 110 toward the vertical center line L12 (described later) of the heat transfer tube opening holes 122c and 122d. . On the other hand, the lengths of the fifth slit 135d to the eighth slit 138d are gradually increased from the vertical center line L12 toward the rear edge of the heat exchanger fin 110. The length of the first slit 131d to the eighth slit 138d makes it easy to generate a turbulent flow of the air flow 114.

  The 1st slit 131d-the 4th slit 134d are arrange | positioned at the plane part 160 side of the fin 110 for heat exchangers. The fifth slit 135d to the eighth slit 138d are arranged on the rear edge side of the heat exchanger fin 110. The first slit 131d to the fourth slit 134d and the fifth slit 135d to the eighth slit 138d are separated from each other with the plane portion 139d interposed therebetween.

  One end of each of the first slit 131d to the eighth slit 138d reaches the short side of the heat sink 120. The other end of each of the first slit 131d to the eighth slit 138d reaches the stepped annular portion 150 of the third heat transfer tube opening hole 122c, and the shape of the end surface of the first slit 131d to the eighth slit 138d is that of the stepped annular portion 150. It matches the arc shape.

  The first slit 131d to the fourth slit 134d and the fifth slit 135d to the eighth slit 138d are line symmetric with respect to the vertical center line L12 of the heat transfer tube opening holes 122c and 122d. Here, the vertical center line L12 of the heat transfer tube opening holes 122c and 122d is parallel to the direction orthogonal to the flow direction of the air flow 114 and extends in the extending direction of the first slit 131d to the eighth slit 138d. Parallel to it.

  The fifth slit group 103e includes a first slit 131e to an eighth slit 138e. The fifth slit group 103e is disposed between the third heat transfer tube opening hole 122c and the fourth heat transfer tube opening hole 122d. The 1st slit 131e-the 8th slit 138e are arrange | positioned in order between the plane part 160 and the rear edge of the fin 110 for heat exchangers in the flow direction of the air flow 114, and each of the 1st slit 131e-the 8th slit 138e. Extends in the longitudinal direction of the heat sink 120.

  The lengths of the first slit 131e to the fourth slit 134e are gradually shortened from the flat portion 160 of the heat exchanger fin 110 toward the vertical center line L12. On the other hand, the lengths of the fifth slit 135e to the eighth slit 138e are gradually increased from the vertical center line L12 toward the rear edge of the heat exchanger fin 110. The length of the first slit 131e to the eighth slit 138e makes it easy to generate a turbulent flow of the air flow 114.

  The 1st slit 131e-the 4th slit 134e are arrange | positioned at the plane part 160 side of the fin 110 for heat exchangers. The fifth slit 135e to the eighth slit 138e are arranged on the rear edge side of the heat exchanger fin 110. The first slit 131e to the fourth slit 134e and the fifth slit 135e to the eighth slit 138e are separated from each other with the plane portion 139e therebetween.

  One end of each of the first slit 131e to the eighth slit 138e reaches the stepped annular portion 150 of the third heat transfer tube opening hole 122c, and the shape of the end surface of the first slit 131e to the eighth slit 138e is that of the stepped annular portion 150. It matches the arc shape. The other end of each of the first slit 131e to the eighth slit 138e reaches the stepped annular portion 150 of the fourth heat transfer tube opening hole 122d, and the shape of the end surface thereof is the stepped annular portion 150. It matches the arc shape.

  The first slit 131e to the fourth slit 134e and the fifth slit 135e to the eighth slit 138e are axisymmetric with respect to the vertical center line L12 of the heat transfer tube opening holes 122c and 122d.

  The sixth slit group 103f includes a first slit 131f to an eighth slit 138f. The third slit group 103f is disposed between the fourth heat transfer tube opening hole 122d and the sixth heat transfer tube opening hole (not shown). The first slit 131f to the eighth slit 138f are sequentially arranged between the flat portion 160 of the heat exchanger fin 110 and the rear edge in the flow direction of the air flow 114, and each of the first slit 131f to the eighth slit 138f. Extends in the longitudinal direction of the heat sink 120.

  The lengths of the first slit 131f to the fourth slit 134f are gradually shortened from the flat portion 160 of the heat exchanger fin 110 toward the vertical center line L12. On the other hand, the lengths of the fifth slit 135f to the eighth slit 138f are gradually increased from the vertical center line L12 toward the rear edge of the heat exchanger fin 10. The length of the first slit 131f to the eighth slit 138f makes it easy to generate a turbulent flow of the air flow 114.

  The 1st slit 131f-the 4th slit 134f are arrange | positioned at the plane part 160 side of the fin 10 for heat exchangers. The fifth slit 135f to the eighth slit 138f are arranged on the rear edge side of the heat exchanger fin 110. The first slit 131f to the fourth slit 134f and the fifth slit 135f to the eighth slit 138f are separated from each other with the plane portion 139f interposed therebetween.

  One end of each of the first slit 131 f to the eighth slit 138 f reaches the stepped annular portion 150 of the fourth heat transfer tube opening hole 122 d, and the shape of the end surface thereof is the stepped annular portion 150. It matches the arc shape. The other end of each of the first slit 131f to the eighth slit 138f reaches the stepped annular portion 150 of the opening hole for the sixth heat transfer tube, and the shape of the end surface is the arc of the stepped annular portion 150. Matches the shape.

  The first slit 131f to the fourth slit 134f and the fifth slit 135f to the eighth slit 138f are line symmetric with respect to the vertical center line L12 of the heat transfer tube opening holes 122c and 122d.

  In the first slit group 103 a to the sixth slit group 103 f, the slit adjacent in the traveling direction of the air flow 114 is cut and raised only on one main surface 120 a of the heat sink 120. And the cutting height of each slit of the 1st slit group 103a-the 6th slit group 103f is uneven because the cutting height of the adjacent slit differs. That is, it means that the slits of the first slit group 103a to the sixth slit group 103f do not change gradually lower or change gradually higher.

  The cut and raised heights of the first slits 131a to 131f and the eighth slits 138a to 138f are set to h1. The cut and raised heights of the second slits 132a to 132f and the seventh slits 137a to 137f are set to h2. The cut and raised heights of the third slits 133a to 133f and the sixth slits 136a to 136f are set to h3. The cut and raised heights of the fourth slits 134a to 134f and the fifth slits 135a to 135f are set to h4. In the second embodiment, h3> h1> h4> h2. As described above, the heights of h1, h2, h3, and h4 are all different.

  In addition, the widths W of the first slit group 103a to the sixth slit group 103f in the direction in which the air flow 114 flows are all equal.

  The shapes of the slits of the first slit group 103a to the sixth slit group 103f viewed from the upstream side of the air flow 114 are substantially trapezoidal.

  As shown in FIG. 10 and FIG. 11, the first heat transfer tube opening hole 122 a to the fourth heat transfer tube opening hole 122 d each stand up from the hole edge and are inscribed in the heat transfer tube 112. 140 and a stepped annular portion 150 disposed around the annular heat transfer tube support frame portion 140. The annular heat transfer tube support frame portion 140 and the stepped annular portion 150 are provided on the other main surface 120b opposite to the one main surface 120a of the heat sink 120 provided with a plurality of rows of slit groups 103a to 103f. It has been.

  The annular heat transfer tube support frame portion 140 includes a lower half large-diameter circumferential surface portion 142, an upper half small-diameter circumferential surface portion 146, and a stepped portion 144 that connects the large-diameter circumferential surface portion 142 and the small-diameter circumferential surface portion 146. ,have. The inner diameter of the small diameter circumferential surface portion 146 is set to be substantially smaller than the outer diameter of the heat transfer tube 112. The heat transfer tube 112 is fitted into the small-diameter circumferential surface portion 146, whereby the outer peripheral surface of the heat transfer tube 112 and the inner peripheral surface of the small-diameter circumferential surface portion 146 are joined, and the heat transfer tube 112, the heat exchanger fin 110, Is fixed.

  On the other hand, the inner diameter of the large-diameter circumferential surface portion 142 is set slightly larger than the outer diameter of the small-diameter circumferential surface portion 146. Then, the small-diameter circumferential surface portion 146 of the annular heat transfer tube support frame portion 140 of the adjacent heat exchanger fin 110 is inserted into the large-diameter circumferential surface portion 142 until the tip portion of the small-diameter circumferential surface portion 146 contacts the stepped portion 144. It can be done. Therefore, the adjacent heat exchanger fins 110 can be reliably arranged at predetermined intervals.

  Further, since the stepped annular portion 150 is provided, the stress applied to the heat exchanger fins 110 can be dispersed throughout the heat exchanger fins 110 to reduce the mechanical stress applied to the heat exchanger fins 110. it can.

  Angle-shaped ribs 180 and 181 are provided on the front and rear edges of the long heat sink 120, respectively. The ribs 180 and 181 extend in the length direction of the heat radiating plate 120 (for example, the direction parallel to the vertical center line L11 of the opening holes 122a and 122b for the heat transfer tubes), and the bending rigidity of the long heat radiating plate 120. Has improved.

  Further, the guide pin hole 184 formed in the extending direction of the ribs 180 and 181 at the position of the ribs 180 and 181 is a guide pin for sending the heat exchanger fins 110 in the manufacturing process of the heat exchanger. It is a hole for insertion.

  The heat exchanger fin 110 having the above configuration is different in the cut-and-raised height of the adjacent slits of the first slit group 103a to the sixth slit group 103f with respect to the traveling direction of the air flow 114. Since the cut-and-raised height of each slit of the first slit group 103a to the sixth slit group 103f is uneven, the number of times the air flow 114 hits the slit increases, and the heat exchanger fin 110 having a high heat transfer effect is provided. Can be obtained.

  Further, each of the first slit group 103a to the sixth slit group 103f is axisymmetric with respect to the vertical center line L11 or the vertical center line L12 in the flow direction of the air flow 114, and the first slit group 103a to the first slit group 103f. Since the third slit group 103c and the fourth slit group 103d to the sixth slit group 103f are axisymmetric with respect to the plane portion 160, the heat transfer effect is exerted substantially uniformly on the entire heat exchanger fin 110. In addition, since each of the first slit group 103a to the sixth slit group 103f is symmetrical with respect to the vertical center line L11 or the vertical center line L12, when inserting the heat exchanger fin 110 into the heat transfer tube 112, Each of the first slit group 3a to the sixth slit group 3f with respect to the flow of the air flow 114, even if the front edge and the rear edge of the heat exchanger fin 110 are inserted in reverse as the heat exchanger fin 110 insertion direction. Therefore, the heat exchanger can be manufactured without worrying about the direction in which the heat exchanger fins 110 are inserted into the heat transfer tubes 112.

  As a result, the heat exchanger using the heat exchanger fins 110 becomes a heat exchanger having a high heat transfer effect.

  In addition, this invention is not limited to the said embodiment, A various deformation | transformation is carried out within the range of the summary. The heat exchanger fins may have a plurality of heat transfer tube opening holes arranged in three or more rows or two or more rows in a staggered manner with respect to the air flow direction. In addition, the slit group is formed between the plurality of heat transfer tube opening holes, but is not limited thereto, and these heat transfer pipe opening holes are arranged in two or more rows in the heat exchanger fins. If present, it may be provided in the central plane portion.

3a, 103a 1st slit group 3b, 103b 2nd slit group 3c, 103c 3rd slit group 103d 4th slit group 103e 5th slit group 103f 6th slit group 10,110 Fin 10 for heat exchangers
12, 112 Heat transfer tube 14, 114 Air flow 14a, 14b Split flow 20, 120 Heat sink 20a, 120a One main surface 20b, 120b The other main surface 22a, 122a First heat transfer tube opening hole 22b, 122b Second transfer Opening hole for heat tube 122c Opening hole for third heat transfer tube 122d Opening hole for fourth heat transfer tube 31a to 31c, 131a to 131f First slit 32a to 32c, 132a to 132f Second slit 33a to 33c, 133a to 133f Third slit 34a-34c, 134a-134f 4th slit 35a-35c, 135a-135f 5th slit 36a-36c, 136a-136f 6th slit 37a-37c, 137a-137f 7th slit 38a-38c, 138a-138f 8th slit 39a-39c, 139a-1 9f Plane portion 40, 140 Annular heat transfer tube support frame portion 42, 142 Large diameter circumferential surface portion 44, 144 Step portion 46, 146 Small diameter circumferential surface portion 50, 150 Stepped annular portion 80, 81, 180, 181 Rib 84, 184 Guide pin hole 160 Central plane h1 Cut and raised height of first and eighth slits h2 Cut and raised height of second and seventh slits h3 Cut and raised height of third and sixth slits h4 Cut height of 4 slits and 5th slit W Width of air flow direction of each slit L1, L11, L12 Vertical center line of heat transfer tube opening hole

Claims (3)

A heat sink,
A plurality of heat transfer tube opening holes for heat transfer tubes penetrating the heat sink;
A plurality of slits opened toward the air flow and cut and raised only on one main surface of the heat sink; and
The plurality of rows of slits are uneven in the height of the plurality of rows of slits, because the height of the slits adjacent to each other in the air flow direction is different in three or more stages .
The adjacent slits are arranged outside the range of the temperature boundary layer of each slit,
The plurality of rows of slits are arranged between the front edge and the rear edge of the heat radiating plate in the air flow direction, and are line symmetric with respect to the vertical center line of the heat transfer tube opening hole,
The plurality of rows of slits are gradually shorter from the front edge of the heat radiating plate toward the vertical center line of the opening hole for the heat transfer tube, and are arranged without being spaced apart in front view, and Gradually longer from the vertical center line of the heat transfer tube opening hole toward the rear edge of the heat radiating plate, and arranged in front view without any interval,
Vertical center line of the opening hole heat transfer pipe is parallel to the direction perpendicular to a flow direction of air, and, parallel der Rukoto to the extending direction of the slit,
A heat exchanger fin characterized by the following. The heat transfer tube opening hole includes an annular heat transfer tube support frame portion that stands up from a hole edge and inscribes the heat transfer tube, and a stepped annular portion disposed around the annular heat transfer tube support frame portion. Have
The annular heat transfer tube support frame has a lower half large-diameter circumferential surface, an upper half small-diameter circumferential surface, and a stepped portion connecting the large-diameter circumferential surface and the small-diameter circumferential surface. The inner diameter of the small diameter circumferential surface portion is set to be substantially smaller than the outer diameter of the heat transfer tube,
At least one end portion of the plurality of rows of slits reaches the stepped annular portion of the opening hole for the heat transfer tube, and the shape of the end surface matches the arc shape of the stepped annular portion. And
The annular heat transfer tube support frame portion and the stepped annular portion are provided on the other main surface of the heat radiating plate opposite to one main surface of the heat radiating plate provided with the plurality of rows of slits. The heat exchanger fin according to claim 1, wherein the fin is for heat exchanger. The heat exchanger fins according to claim 1 or 2, which are arranged at predetermined intervals,
Heat transfer tubes arranged in a plurality of rows through the heat exchanger fins;
A heat exchanger characterized by comprising.