JP6336364B2 - heatsink - Google Patents

Description

  The present invention relates to a heat sink that has an inner fin in a flat flow path, a cooled body such as a semiconductor attached to the outer surface thereof, and cools it.

  Patent Document 1 below proposes a heat sink. This is one in which inner fins are arranged in a rectangular frame body, plates are provided at both upper and lower ends thereof, and the whole is integrally brazed and fixed. Then, the refrigerant is circulated from one end side to the other end side, a semiconductor integrated circuit or the like is attached to the surface of the plate, and it is cooled by the refrigerant.

JP 2003-60145 A

Usually, many integrated circuits such as semiconductors attached to the outer surface of such a heat sink are arranged in parallel along the flow of the refrigerant. However, as the refrigerant flows from the upstream side to the downstream side, the temperature gradually increases, and there is a drawback that the cooling capacity of the semiconductor located further downstream is lowered.
Accordingly, an object of the present invention is to provide a heat sink that can maintain a relatively high cooling capacity on both the upstream side and the downstream side of the refrigerant.

The present invention according to claim 1 is a flat rectangular dish (3) having a side wall (2) formed on the outer periphery of the bottom (1), and a lid for closing the opening of the dish (3). The body (4) constitutes a main body (5) having a flat flow path formed therein, and an inner fin is interposed inside the main body (5), and one end and the other end of the main body (5) In the heat sink in which the refrigerant inlet / outlet (7) is formed, and the object to be cooled (6) is attached to the bottom (1) and / or the lid (4),
A pair of first inner fins (8) are juxtaposed in the width direction via the first bypass passage (10) on the one inlet / outlet (7) side of the refrigerant,
A second inner fin (9) is disposed on the other inlet / outlet (7) side with a space (11) from the end of the pair of first inner fins (8), and the second inner fin (9). A pair of second bypass passages (13) are formed between both sides in the width direction and the side wall portion (2), and a planar funnel-shaped partition (12) is disposed in the space (11). The expansion side is located on both sides of the second inner fin (9), the funnel-shaped throttle side communicates with the first bypass passage (10),
The heat sink is a heat sink in which the object to be cooled (6) is disposed at the position of the pair of first inner fins (8) and the position of the second inner fin (9).

The present invention according to claim 2 is flattened internally by a flat rectangular dish-like body 3 having a side wall 2 formed on the outer periphery of the bottom part 1 and a lid 4 that closes the opening of the dish-like body 3. The main body 5 is formed with a simple flow path, an inner fin is interposed inside the main body 5, and first and second refrigerant inlets 7 are formed at one end and the other end of the main body 5. In the heat sink in which the cooled object 6 is attached to the bottom 1 and / or the lid 4,
The first inner fin 8 is disposed close to one side in the width direction of the main body 5 on the first inlet / outlet side of the refrigerant, and a first bypass passage 10 is formed between the other side and the side wall portion 2,
A space 11 is provided from the end of the first inner fin 8, and the second inner fin 9 is disposed near the side wall 2 on the other side in the width direction of the main body 5 on the second doorway 7 side. 2 A second bypass path 13 is formed between one side in the width direction of the inner fin 9 and the side wall 2.
A relatively low temperature refrigerant flows through the space 11 to the other side portion of the inner fin located downstream of the refrigerant 15, and a relatively high temperature refrigerant flows through the one side portion.
This is a heat sink in which the object to be cooled 6 is disposed at the position of the first inner fin 8 and the position of the second inner fin 9.

According to the third aspect of the present invention, a flat rectangular dish 3 having a side wall 2 formed on the outer periphery of the bottom 1 and a lid 4 that closes the opening of the dish 3 are flattened inside. The main body 5 is formed with a simple flow path, an inner fin is interposed in the main body 5, a refrigerant inlet / outlet 7 is formed at one end and the other end of the main body 5, and the bottom 1 and / or the lid In the heat sink in which the body to be cooled 6 is attached to the body 4,
A pair of first inner fins 8 are juxtaposed in the width direction via the first bypass path 10 on the side of the one inlet / outlet 7 of the refrigerant,
A space 11 is formed from the end portions of the pair of first inner fins 8, and second inner fins 9 are disposed on the other entrance / exit 7 side, and both sides in the width direction of the second inner fins 9 are the side wall portions 2. Placed in contact with
Refrigerant is supplied to the pair of first inner fins 8 and the first bypass passage 10 located on the upstream side, and a relatively low temperature refrigerant flows through the center portion in the width direction of the second inner fin 9 located on the downstream side. , Configured to circulate in a relatively high temperature refrigerant on both sides in the width direction,
This is a heat sink in which the object to be cooled 6 is disposed at the position of the pair of first inner fins 8 and the position of the second inner fins 9.

  In the first aspect of the present invention, since the planar funnel-shaped partition 12 is formed in the space 11 between the pair of first inner fins 8 and second inner fins 9, the comparison is made by passing through the inner fins on the upstream side. The refrigerant having reached a high temperature is bypassed by the second bypass passage 13 on the downstream side, and only the relatively low-temperature refrigerant is supplied from the first bypass passage 10 to the second inner fin 9. Therefore, the refrigerant | coolant capability of each part can be improved and the to-be-cooled body 6 arrange | positioned in the position of each inner fin can be cooled effectively.

According to the second aspect of the present invention, a first bypass passage 10 and a second bypass passage 13 are formed on the other side of the first inner fin 8 and one side of the second inner fin 9, and a space 11 is formed between the fins. Is arranged, a relatively low temperature refrigerant flows through the space 11 to the other side portion of the second inner fin 9 located on the downstream side of the refrigerant 15, and a relatively high temperature refrigerant flows through the one side portion. It is comprised as follows. Therefore, a large-capacity cooled object 6 is disposed at the position of the low-temperature refrigerant circulation portion of the inner fin located downstream of the refrigerant, and the low-capacity cooled object is disposed at the position of the high-temperature refrigerant circulation portion of the inner fin. By arranging the body 6a, each part can be used effectively.

In the invention according to claim 3 , a pair of first inner fins 8 are juxtaposed in the width direction via the first bypass passage 10 on the one inlet / outlet port 7 side of the refrigerant,
A space 11 is formed from the ends of the pair of first inner fins 8, and the second inner fins 9 are disposed on the other entrance / exit 7 side, and both sides in the width direction of the second inner fins 9 are formed on the side wall portions 2. Placed in contact,
Refrigerant is supplied to the pair of first inner fins 8 and the first bypass passage 10 located on the upstream side, and a relatively low temperature refrigerant flows through the center portion in the width direction of the second inner fin 9 located on the downstream side. The refrigerant having a relatively high temperature circulates on both sides in the width direction.
Therefore, the large-capacity cooled object 6 is disposed at the position of the low temperature refrigerant circulation portion in the central portion of the inner fin located on the downstream side of the refrigerant, and the high temperature refrigerant circulation portions on both sides of the inner fin are positioned. Can arrange the to-be-cooled body 6a with a small capacity, and can use each part effectively.

The top view which shows the internal structure of the heat sink of 1st Example of this invention. The top view which shows the internal structure of the heat sink of the 2nd Example. FIG. 3 is an exploded perspective view of each of the first and second embodiments. The top view which shows the internal structure of the heat sink of 3rd Example of this invention. The top view which shows the internal structure of the heat sink of 4th Example of this invention. Explanatory drawing which shows the attachment state of the to-be-cooled bodies 6 and 6a on the surface of the cover body 4 of the Example. The top view which shows the internal structure of the heat sink of 5th Example of this invention. Explanatory drawing which shows the attachment state of the to-be-cooled bodies 6 and 6a on the surface of the cover body 4 of the Example.

  Next, embodiments of the present invention will be described with reference to the drawings.

1 and 3 are an internal structure and an exploded perspective view of a first embodiment of the present invention.
As shown in FIG. 3, the heat sink includes a bottom 1 having a same outer periphery, a frame-shaped side wall 2, and a lid 4. And the side wall part 2 is mounted on the bottom part 1, a pair of 1st inner fin 8 and the 2nd inner fin 9 and the partition 12 are arrange | positioned in the side wall part 2, and the cover body 4 is attached to those upper surfaces.
An entrance / exit 7 is formed at the other end of the bottom 1, and an entrance / exit 7 is also formed at one end of the lid 4. And they are brazed together.

As shown in FIG. 1, a pair of first inner fins 8 are disposed on the upstream side of the entrance / exit 7 via a first bypass passage 10 and a second inner fin is disposed on the downstream side thereof via a space 11 as shown in FIG. 9 is arranged, and a partition 12 is interposed in the space 11.
The partition 12 is formed in a planar funnel shape, the expansion side of the partition 12 holds the upstream end edge of the second inner fin 9, and the throttle side is connected to the downstream end of the first bypass path 10.

[Operation of Example 1]
In FIG. 1, the refrigerant 15 flows in from the inlet / outlet 7 opened at the left end, and flows through the pair of first inner fins 8, and a part thereof is guided to the first bypass passage 10. The low-temperature refrigerant 15 a supplied to the first inner fin 8 gradually becomes high temperature as it flows through the first inner fin 8, becomes a high-temperature refrigerant 15 b, is guided to the outer periphery of the partition 12, and passes through the second bypass passage 13. And flows out from the rightmost entrance 7.
On the other hand, the low-temperature refrigerant 15a supplied from the inlet / outlet 7 to the first bypass passage 10 is directly led to the inside of the partition 12 and supplied to the second inner fin 9, and gradually becomes high temperature and flows out from the right-end inlet / outlet 7 to the outside. .

  A plurality of bodies to be cooled 6 are arranged on the upper surface of the lid body 4 and / or the lower surface of the bottom portion 1, and the refrigerant 15 circulates therein to cool them. In this example, a pair of objects to be cooled 6 are arranged in parallel at the position of the pair of first inner fins 8, and one object to be cooled 6 is disposed at the position of the second inner fin 9. Is cooled. The flow resistance of the refrigerant in the pair of first inner fins 8 is substantially the same as the flow resistance of the first bypass passage 10. Therefore, the flow rate of the refrigerant flowing through the first bypass passage 10 and the flow rate of the refrigerant flowing through the pair of first inner fins 8 are substantially the same.

Next, FIG. 2 shows a second embodiment of the present invention, and this example is different from that of FIG. 1 only in that the flow direction of the refrigerant 15 is opposite to that of FIG.
In FIG. 2, a part of the low-temperature refrigerant 15 a flowing in from the right inlet / outlet 7 circulates in the second inner fin 9, and the other low-temperature refrigerants 15 a circulate in the pair of second bypass passages 13. Then, the low-temperature refrigerant 15 a guided into the second inner fin 9 cools the body 6 to be cooled to become a high-temperature refrigerant 15 b, and is guided directly from the first bypass passage 10 to the left inlet / outlet 7 via the partition 12. In addition, the low-temperature refrigerant 15 a guided to the pair of second bypass passages 13 is guided by the slope of the partition 12 and supplied to the pair of first inner fins 8, and the respective cooled objects disposed on the first inner fins 8. The body 6 is cooled to become a high-temperature refrigerant 15b and flows out from the left entrance / exit 7. In this example, the flow resistance of the refrigerant in the second inner fin 9 is adjusted to be substantially the same as the flow resistance of the pair of second bypass passages 13. The flow rate of the refrigerant flowing through the pair of second bypass passages 13 and the flow rate of the refrigerant flowing through the second inner fin 9 are substantially the same.

  Next, FIG. 4 shows a third embodiment of the present invention. In this example, the first inner fin 8 and the second inner fin 9 are arranged apart from each other in the refrigerant flow direction through the space 11. The inner fin 8 is disposed on one side in the width direction of the main body 5, and the second inner fin 9 is disposed on the other side. And the 1st bypass path 10 and the 2nd bypass path 13 are formed between each inner fin 8 and 9 and the side wall part 2 which consists of a frame. Further, an oblique partition 12 is disposed in the space 11, one end of which contacts the downstream end of the end edge of the first inner fin 8, and the other end contacts the upstream end of the end edge of the second inner fin 9. In this example, the flow resistance of the refrigerant in the first bypass passage 10 and the flow resistance of the refrigerant in the first inner fin 8 are adjusted to be approximately equal.

[Operation of Example 3]
In FIG. 4, the refrigerant 15 that has flowed in from the left inlet / outlet 7 is divided into the inside of the first inner fin 8 and the first bypass passage 10. The low-temperature refrigerant 15a that has flowed into the first inner fin 8 cools an object to be cooled (not shown) disposed at the position of the first inner fin 8, and becomes a high-temperature refrigerant 15b that is led to the space 11 and disposed there. The partition 12 is led to the second bypass 13.
On the other hand, the low-temperature refrigerant 15 a that circulates in the first bypass passage 10 is guided to the downstream side of the partition 12, circulates in the second inner fin 9, and is to be cooled (not shown) disposed at the position of the second inner fin 9. Is cooled to become a high-temperature refrigerant 15 b and is led to the right entrance 7.
In this example, the refrigerant 15 is guided from the left inlet / outlet 7 to the right inlet / outlet 7, but conversely, the refrigerant 15 may be guided from the right inlet / outlet 7 to the left inlet / outlet 7. In that case, the arrow direction of each refrigerant is reversed.

  Next, FIG. 5 shows a fourth embodiment of the present invention, and this example is different from that of FIG. 4 in that no partition 12 exists in the space 11.

[Operation of Example 4]
The refrigerant 15 that has flowed in from the left inlet / outlet 7 flows into the first inner fin 8 and the first bypass passage 10. Since the first bypass channel 10 has a small flow resistance, the flow rate per flow channel cross section is large, and the flow rate is small in the first inner fin 8. The low-temperature refrigerant 15a circulated in the first bypass passage 10 circulates more on the side of the second inner fin 9 brought closer to the other side closer to the first bypass passage 10, passes through the first inner fin 8, and is relatively The high-temperature refrigerant 15b that has reached a high temperature flows through the second inner fin 9 at a position close to the second bypass passage 13 side, mixes with the low-temperature refrigerant 15a, and the intermediate-temperature refrigerant 15 passes through the second bypass passage 13 side. Distribute more.

Therefore, in the second inner fin 9, the mixed refrigerant having a relatively high temperature flows in the second inner fin 9 close to the second bypass passage 13 side, and the refrigerant having a relatively low temperature is opposite to the second bypass passage 13. Circulate.
Therefore, in this example, as shown in FIG. 6, a cooling body 6a having a relatively small capacity is disposed on the second bypass fin 13 side of the second inner fin 9, and a covering having a relatively large capacity is disposed on the opposite side. The cooling body 6 is disposed. And they are each cooled by the refrigerant | coolant of each temperature.
In the example of FIG. 5, the refrigerant is circulated from the left inlet / outlet 7 to the right inlet / outlet 7, but it may be reversed. In that case, the bodies 6 and 6a to be cooled are arranged on the first inner fin 8 on the downstream side.

Next, FIG. 7 shows a fifth embodiment of the present invention. In this example, a pair of first inner fins 8 are arranged on the upstream side of the refrigerant via the first bypass passage 10, and a space 11 is arranged on the downstream side thereof. The 2nd inner fin 9 is arrange | positioned through.
As for this 2nd inner fin 9, the width direction both ends are in contact with the side wall part 2 which consists of a frame.

[Operation of Example 5]
The refrigerant 15 guided from the left entrance 7 is supplied to the pair of first inner fins 8 and to the first bypass passage 10. The low-temperature refrigerant 15 a that has circulated through the first bypass passage 10 having a relatively low flow resistance is guided to the center portion in the width direction of the second inner fin 9.
In addition, the refrigerant that has circulated through the first inner fins 8 cools the body 6 to be cooled at those positions to become a high-temperature refrigerant 15b, which circulates in the vicinity of both sides of the second inner fins 9, The refrigerant is mixed with the refrigerant that has passed through the bypass 10, and the temperature is intermediate between the refrigerant and the refrigerant is guided to the right entrance 7.

  Therefore, the low-temperature refrigerant 15a easily flows through the intermediate portion in the width direction of the second inner fin 9, and the mixture of the low-temperature refrigerant 15a and the high-temperature refrigerant 15b flows through both ends in the width direction. Therefore, as shown in FIG. 8, the cooled object 6 having a relatively large capacity is arranged at the middle position of the second inner fin 9, and the cooled object 6 a having a relatively small capacity is arranged on both sides thereof. They can be cooled by a refrigerant at each temperature.

[Modification]
In these embodiments, as shown in FIG. 3, the bottom portion 1 and the side wall portion 2 are formed separately and are integrally fixed by brazing. 2 may be formed in a dish shape, and the lid 4 may be fixed to the opening end.
Further, in these examples, the first inner fin 8 is bent in a waveform and the ridgeline direction is arranged in the refrigerant flow direction, but an offset type inner fin can be arranged instead.
Moreover, although the flat flow path was made into one step in this example, it can also be laminated | stacked in multiple steps.
In FIG. 3, the body 6 to be cooled can also be disposed on the lower surface side of the bottom 1.

DESCRIPTION OF SYMBOLS 1 Bottom part 2 Side wall part 3 Dish-like body 4 Lid body 5 Main body 6 Cooled body 6a Cooled body 7 Entrance / exit 8 First inner fin 9 Second inner fin

DESCRIPTION OF SYMBOLS 10 1st bypass path 11 Space 12 Partition 13 2nd bypass path 14 Heat sink 15 Refrigerant 15a Low temperature refrigerant 15b High temperature refrigerant

Claims (3)

A flat rectangular dish (3) having a side wall (2) formed on the outer periphery of the bottom (1) and a lid (4) that closes the opening of the dish (3) are flattened inside. A main body (5) having a simple flow path is formed, an inner fin is interposed inside the main body (5), and a refrigerant inlet / outlet (7) is formed at one end and the other end of the main body (5). In the heat sink in which the object to be cooled (6) is attached to the bottom (1) and / or the lid (4),
A pair of first inner fins (8) are juxtaposed in the width direction via the first bypass passage (10) on the one inlet / outlet (7) side of the refrigerant,
A second inner fin (9) is disposed on the other inlet / outlet (7) side with a space (11) from the end of the pair of first inner fins (8), and the second inner fin (9). A pair of second bypass passages (13) are formed between both sides in the width direction and the side wall portion (2) ,
A planar funnel-shaped partition (12) is disposed in the space (11), the funnel-shaped expansion side is located on both sides of the second inner fin (9), and the funnel-shaped throttle side is the first bypass channel (10 )
A heat sink in which the object to be cooled (6) is disposed at the position of the pair of first inner fins (8) and the position of the second inner fin (9). A flat rectangular dish (3) having a side wall (2) formed on the outer periphery of the bottom (1) and a lid (4) that closes the opening of the dish (3) are flattened inside. The main body (5) in which a simple flow path is formed, inner fins are interposed in the main body (5), and first and second refrigerant inlets and outlets are provided at one end and the other end of the main body (5). In the heat sink in which (7) is formed and the object to be cooled (6) is attached to the bottom (1) and / or the lid (4),
A first inner fin (8) is disposed close to one side in the width direction of the main body (5) on the first inlet / outlet (7) side of the refrigerant, and the first inner fin (8) is disposed between the other side and the side wall (2). 1 bypass (10) is formed,
A space (11) is formed from the end of the first inner fin (8), and the second inner fin (9) is disposed on the second entrance / exit (7) side, and the side wall on the other side in the width direction of the main body (5). A second bypass path (13) is formed between one side in the width direction of the second inner fin (9) and the side wall (2).
A relatively low temperature refrigerant flows through the space (11) to the other side portion of the inner fin located on the downstream side of the refrigerant (15), and a relatively high temperature refrigerant flows through the one side portion. And
A heat sink in which the object to be cooled (6) is arranged at the position of the first inner fin (8) and the position of the second inner fin (9). A flat rectangular dish (3) having a side wall (2) formed on the outer periphery of the bottom (1) and a lid (4) that closes the opening of the dish (3) are flattened inside. A main body (5) having a simple flow path is formed, an inner fin is interposed inside the main body (5), and a refrigerant inlet / outlet (7) is formed at one end and the other end of the main body (5). In the heat sink in which the object to be cooled (6) is attached to the bottom (1) and / or the lid (4),
A pair of first inner fins (8) are juxtaposed in the width direction via the first bypass passage (10) on the one inlet / outlet (7) side of the refrigerant,
A second inner fin (9) is disposed on the other inlet / outlet (7) side with a space (11) from the end of the pair of first inner fins (8), and the second inner fin (9). Are arranged in contact with the side wall (2),
Refrigerant is supplied to the pair of first inner fins (8) and the first bypass passage (10) located on the upstream side, and is relatively heated at the center in the width direction of the second inner fin (9) located on the downstream side. Is configured so that a low-temperature refrigerant flows and a relatively high-temperature refrigerant flows on both sides in the width direction.
A heat sink in which the object to be cooled (6) is disposed at the position of the pair of first inner fins (8) and the position of the second inner fin (9).

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