JPWO2013088582A1 - Cooling device and electronic device - Google Patents

Abstract

  The cooling device divides a plurality of fans including a first fan and a second fan, and a gas blown from the first fan into a plurality of directions including a direction toward the first region, A dividing mechanism that divides the gas blown from the second fan into gases in a plurality of directions including a direction toward the first region.

Description

  The embodiments discussed herein relate to a cooling device and an electronic device that includes the cooling device and a heat generating component.

  2. Description of the Related Art Conventionally, in a cooling device arranged in an electronic device or the like, there is a mechanism that ensures cooling performance by the other fan even if one fan fails by combining the cooling air of two fans.

  There is also a backflow prevention mechanism that prevents the cooling performance from stopping due to the backflow of cooling air from the failed fan when the fan fails.

JP 2005-11304 A JP 02-128499 A Japanese Utility Model Publication No. 57-044597 JP 2002-176281 A

  22A to 22C are explanatory diagrams for explaining the cooling device 50 according to the first reference technique.

  FIG. 22D is a chart showing the relationship between the fan state and the air volume in the cooling device 50.

  As shown in FIG. 22A, the cooling device 50 includes a first fan 51 and a second fan 52 that are arranged in parallel in the left and right directions, and a space 53. The first fan 51 and the second fan 52 are provided with a restriction plate (not shown) that prevents backflow.

  The first region 53 a faces the first fan 51 with the space 53 interposed therebetween. The second region 53 b faces the second fan 52 with the space 53 interposed therebetween. It is assumed that the object to be cooled is located on the leeward side of each of the areas 53a and 53b shown in plan in the drawing.

  In the space 53, the gas G51 sucked from the first fan 51 mainly flows to the opposing first region 53a. As a result, wind is blown to the object to be cooled behind the first region 53a.

  In the space 53, the gas G52 sucked from the second fan 52 mainly flows to the second region 53b facing each other. As a result, wind is blown to the object to be cooled behind the second region 53b.

  Assuming that the amount of gas blown by each of the first fan 51 and the second fan 52 is Q (per unit time), as shown in FIG. 22D, in normal times, that is, the first fan 51 and the second fan 52 During the operation of the second fan 52, the gas having the air volume Q flows through the first region 53a and the second region 53b.

  When the first fan 51 fails as shown in FIG. 22B, backflow from the first fan 51 is prevented by a restriction plate (not shown), but as shown in FIG. 22D, the air volume in the first region 53a is The air volume in the second region 53b remains Q. Further, when the second fan 52 fails as shown in FIG. 22C, backflow from the second fan 52 is prevented by a restriction plate (not shown), but the air volume in the second region 53b as shown in FIG. 22D. Becomes almost 0, and the air volume in the first region 53a remains Q.

  Thus, when one of the fans fails, the gas is not blown to the object to be cooled behind the area facing the fan, so that the cooling performance is significantly reduced.

  23A to 23C are explanatory diagrams for explaining a cooling device 60 according to the second reference technique.

  FIG. 23D is a chart showing a relationship between the fan state and the air volume in the cooling device 60.

  As shown in FIG. 23A, the cooling device 60 includes a first fan 61 and a second fan 62, and a duct 63, which are arranged in parallel on the left and right. The sixth fan 61 and the second fan 62 are provided with a restriction plate (not shown) that prevents backflow.

  A single exhaust port 63 a is formed in the duct 63.

  In the duct 63, the gas G <b> 61 sucked from the first fan 61 and the gas G <b> 62 sucked from the second fan 62 are exhaust ports 63 a that are opposed to intermediate positions between the first fan 61 and the second fan 62. Exhausted from. Thereby, the gas exhausted from the exhaust port 63a is blown to the area behind the exhaust port 63a.

  Assuming that the air volume of the gas blown by each of the first fan 61 and the second fan 62 is Q, as shown in FIG. 23D, in normal times, that is, the first fan 61 and the second fan 62. During operation, a gas having an air volume of 2Q flows through the exhaust port 63a.

  When the first fan 61 fails as shown in FIG. 23B, backflow from the first fan 61 is prevented by a restriction plate (not shown). However, as shown in FIG. 23D, the air volume at the exhaust port 63a is 2Q. Half Q. Further, when the second fan 62 fails as shown in FIG. 23C, backflow from the second fan 62 is prevented by a restriction plate (not shown), but the air volume at the exhaust port 63a is 2Q as shown in FIG. 23D. Q of half of this.

  Further, in the cooling device 60, the flow path is narrowed in order to join the gas blown from the two fans 61 and 62, so that the width L <b> 12 of the exhaust port 63 a is blown from the two fans 61 and 62. It becomes smaller than the width L11 of the part. Therefore, the cooling performance when the two fans 61 and 62 are normally operated is inferior to the case where the duct 63 is not provided.

  By the way, electronic devices are often required to operate stably for a long time, for example, as electronic components are used as components of a system that supports social infrastructure. For this reason, it is required that the cooling performance is prevented from being lowered and the system can continue to operate even when a failure of the cooling fan that efficiently discharges heat generated in the electronic device occurs.

  In one aspect, a cooling device and an electronic device disclosed in this specification are intended to suppress uneven cooling when a fan fails.

  The cooling device disclosed in the present specification includes a plurality of fans and a dividing mechanism. The plurality of fans includes a first fan and a second fan. The dividing mechanism divides the gas blown from the first fan into a plurality of directions including a direction toward the first region, and the gas blown from the second fan is changed to the first fan. The gas is divided into a plurality of directions including a direction toward the region.

  An electronic device disclosed in the present specification includes a heat generating component, a plurality of fans, and a dividing mechanism. The heat generating component is disposed at least in the first region. The plurality of fans includes a first fan and a second fan. The dividing mechanism divides a gas blown from the first fan into a plurality of directions including a direction toward the first region, and a gas blown from the second fan is changed to the first fan. The gas is divided into a plurality of directions including a direction toward one region.

  According to the cooling device and the electronic apparatus according to the embodiment, it is possible to suppress uneven cooling when a fan fails.

It is explanatory drawing (the 1) for demonstrating the division mechanism of a cooling device. It is explanatory drawing (the 2) for demonstrating the division mechanism of a cooling device. It is explanatory drawing (the 3) for demonstrating the division mechanism of a cooling device. It is explanatory drawing (the 4) for demonstrating the division mechanism of a cooling device. It is explanatory drawing (the 5) for demonstrating the division mechanism of a cooling device. It is explanatory drawing (the 6) for demonstrating the division mechanism of a cooling device. It is a perspective view which shows the electronic device which concerns on 1st Embodiment. It is a perspective view which shows the cooling device which concerns on 1st Embodiment. It is a perspective view which shows the cooling device which concerns on 1st Embodiment which represented the fan with the broken line. It is a perspective view which shows the duct in 1st Embodiment. It is a perspective view which shows the internal structure of the A cross-section part of FIG. It is a perspective view which shows the internal structure of the B cross-section part of FIG. It is a top view which shows the internal structure of the A cross-section part of FIG. It is a top view which shows the internal structure of the B cross-section part of FIG. It is explanatory drawing which shows the flow of the gas of the A cross-section part of FIG. It is explanatory drawing which shows the flow of the gas of the B cross-section part of FIG. FIG. 7B is a composite diagram of FIGS. 7A and 7B. It is explanatory drawing which shows the flow of gas when the 1st fan of the A cross-section part of FIG. 4 fails. It is explanatory drawing which shows the flow of gas when the 1st fan of the B cross section part of FIG. 4 fails. FIG. 9 is a composite diagram of FIGS. 8A and 8B. It is explanatory drawing which shows the flow of gas when the 2nd fan of the A cross-section part of FIG. 4 fails. It is explanatory drawing which shows the flow of gas when the 2nd fan of the B cross section part of FIG. 4 fails. FIG. 9B is a composite diagram of FIGS. 9A and 9B. It is a perspective view which shows arrangement | positioning of the cooling device which concerns on 1st Embodiment in fluid simulation. It is a perspective view which shows arrangement | positioning of the cooling fan which concerns on the comparative example in fluid simulation. It is a side view which shows the 2nd heat-emitting component for demonstrating a temperature measurement point. It is a graph which shows a fluid simulation result. It is a perspective view which shows the duct and regulation board in 2nd Embodiment. It is a perspective view which shows the internal structure of the upper stage part of the duct in 2nd Embodiment. It is a perspective view which shows the internal structure of the lower stage part of the duct in 2nd Embodiment. It is a top view which shows the internal structure of the upper stage part of the duct in 2nd Embodiment. It is a top view which shows the internal structure of the lower stage part of the duct in 2nd Embodiment. It is explanatory drawing which shows the flow of the gas of the duct in 2nd Embodiment. It is a perspective view which shows the duct and regulation board in 2nd Embodiment. It is a perspective view which shows the internal structure of the upper stage part of the duct in 3rd Embodiment. It is a perspective view which shows the internal structure of the middle step part of the duct in 3rd Embodiment. It is a perspective view which shows the internal structure of the lower stage part of the duct in 3rd Embodiment. It is a top view which shows the internal structure of the upper stage part of the duct in 3rd Embodiment. It is a top view which shows the internal structure of the middle step part of the duct in 3rd Embodiment. It is a top view which shows the internal structure of the lower stage part of the duct in 3rd Embodiment. It is explanatory drawing which shows the flow of the gas of the duct in 3rd Embodiment. It is explanatory drawing (the 1) for demonstrating the cooling device which concerns on a 1st reference technique. It is explanatory drawing (the 2) for demonstrating the cooling device which concerns on a 1st reference technique. It is explanatory drawing (the 3) for demonstrating the cooling device which concerns on a 1st reference technique. It is a graph which shows the relationship between the state of the fan and air volume in the cooling device which concerns on 1st reference technology. It is explanatory drawing (the 1) for demonstrating the cooling device which concerns on a 2nd reference technique. It is explanatory drawing (the 2) for demonstrating the cooling device which concerns on a 2nd reference technique. It is explanatory drawing (the 3) for demonstrating the cooling device which concerns on a 2nd reference technique. It is a graph which shows the relationship between the state of the fan and air volume in the cooling device which concerns on 2nd reference technique.

  1A to 1F are explanatory views for explaining an outline of a dividing mechanism (duct 13) of the cooling device 10. FIG.

  As illustrated in FIG. 1A, the cooling device 10 includes a first fan 11 and a second fan 12 that are arranged in parallel in the left-right direction as an example of a plurality of fans, and a duct 13 that is an example of a dividing mechanism.

  As shown in FIG. 1B, the duct 13 is supplied with gas from the first air inlet 13 a-1 and the second air inlet 13 a-2 through which gas is blown from the first fan 11, and from the second fan 12. A third air inlet 13b-1 and a fourth air inlet 13b-2 to be blown are formed.

  The gas blown from the first fan 11 is divided into upper and lower gases by the first intake port 13a-1 on the upper stage side and the second intake port 13a-2 on the lower stage side. Further, the gas blown from the second fan 12 is divided into upper and lower gases by the third intake port 13b-1 on the upper stage side and the fourth intake port 13b-2 on the lower stage side. Note that the gas blown from one fan may be divided into three gases as in a third embodiment described later, or more gases. Further, the gas blown from one fan may be divided into, for example, left and right gases instead of the upper and lower gases when the fans are arranged in parallel in the vertical direction. It may be divided into two gases.

  The duct 13 includes a first exhaust port 13c on the side facing the first intake port 13a-1 and the second intake port 13a-2, a third intake port 13b-1 and a fourth intake port 13b. -2 on the side facing -2. As shown in FIG. 1A, the width L2 of the portion where the first exhaust port 13c and the second exhaust port 13d are formed is a portion where air is blown from the two fans 11 and 12 (intake port) 13a-1, 13a-2, 13b-1, 13b-2) is the same as the width L1.

  The duct 13 exhausts the gas G11-1 sucked from the first air inlet 13a-1 and the gas G12-1 sucked from the third air inlet 13b-1 from the first air outlet 13c. To guide. Thereby, the gas exhausted from the first exhaust port 13c is blown to a region behind the first exhaust port 13c.

  Further, the duct 13 exhausts the gas G11-2 sucked from the second air inlet 13b-1 and the gas G12-2 sucked from the fourth air inlet 13b-2 from the second exhaust port 13d. To guide. Thereby, the gas exhausted from the second exhaust port 13d is blown to a region behind the second exhaust port 13d.

  As shown in FIG. 1C, Q / 2, which is half the air volume Q (per unit time) of the gas blown by the first fan 11, flows from the first intake port 13a-1 to the first exhaust port 13c ( Gas G11-1). Further, the remaining half Q / 2 flows from the second intake port 13a-2 to the second exhaust port 13d (gas G11-2).

  Further, Q / 2, which is half of the air volume Q of the gas blown by the second fan 12, flows from the third intake port 13b-1 to the first exhaust port 13c (gas G11-2). The remaining half of Q / 2 flows from the fourth intake port 13b-2 to the second exhaust port 13d (gas G12-2).

  Therefore, as shown in FIG. 1F, in the normal time when both the first fan 11 and the second fan 12 are operating, the air volume Q (2 × 2) is supplied to the first exhaust port 13c and the second exhaust port 13d, respectively. Q / 2) gas is supplied.

  As shown in FIG. 1D and FIG. 1F, when the first fan 11 fails, the gas blown by the second fan 12 flows from the third intake port 13b-1 to the first exhaust port 13c (gas G12-1) flows from the fourth intake port 13b-2 to the second exhaust port 13d (gas G12-2) by half (Q / 2).

  As shown in FIG. 1E and FIG. 1F, when the second fan 12 fails, the gas blown by the first fan 11 is transferred from the first intake port 13a-1 to the first exhaust port 13c (gas G11-1) and half (Q / 2) are supplied from the second intake port 13a-2 to the second exhaust port 13d (gas G11-2).

  In this way, even if the first fan 11 or the second fan 12 fails, the gas is supplied to the first exhaust port 13c and the second exhaust port 13d, and eventually to the region behind the first exhaust port 13c and the second exhaust port 13d. Furthermore, as described above, the width L2 of the portion where the first exhaust port 13c and the second exhaust port 13d are formed is the same as the width L1 of the portion where gas is blown from the two fans 11 and 12 Thus, it is possible to prevent the cooling performance from being reduced by narrowing the flow path.

  Furthermore, if one of the fans fails and the rotational speed of the other fan is doubled, for example, it is possible to prevent loss of cooling performance when the fans 11 and 12 fail.

<First Embodiment>
FIG. 2 is a perspective view showing the electronic apparatus 1 according to the first embodiment.

  FIG. 3A is a perspective view showing the cooling device 20 according to the first embodiment, and FIG. 3B is a perspective view showing the cooling device 20 in which the fans 21 and 22 are represented by broken lines.

  FIG. 4 is a perspective view showing the duct 23.

  5A is a perspective view showing the internal structure of the A cross section of FIG. 4, and FIG. 5B is a perspective view showing the internal structure of the B cross section of FIG.

  6A is a plan view showing the internal structure of the A cross section of FIG. 4, and FIG. 6B is a plan view showing the internal structure of the B cross section of FIG.

  As shown in FIG. 2, the electronic device 1 includes four cooling devices 20, a housing 2, an exhaust unit 3, a substrate 4, and a plurality of heat generating components 5 and 6. The heat generating components 5 and 6 are arranged in the first region S1, the second region S2, and the like (at least one example of the first region) in which gas is blown by the cooling device 20. One heat generating component 5 includes, for example, a memory, and the other heat generating component 6 includes, for example, a CPU. Note that the number of the cooling devices 20 may be one, and may be appropriately determined according to the electronic device 1.

  The cooling device 20 cools the first region S1, the second region S2 (only the regions S1 and S2 corresponding to the cooling device 20 at the left end in FIG. 2 are indicated by a two-dot chain line), and the like.

  As illustrated in FIG. 3A, the cooling device 20 includes a first fan 21 and a second fan 22 that are arranged in parallel in the left-right direction as an example of a plurality of fans, and a duct 23 that is an example of a dividing mechanism. The cooling device 20 further includes two regulating plates 24-1 and 24-2 shown in FIGS. 5A to 6B.

  As shown in FIGS. 3B and 4, the duct 23 includes a first air inlet 23 a-1 and a second air inlet 23 a-2 through which gas is blown from the first fan 21, and a second fan 22. A third intake port 23b-1 and a fourth intake port 23b-2 through which gas is blown from are formed.

  The gas blown from the first fan 21 is divided into upper and lower gases by the first intake port 23a-1 on the upper stage side and the second intake port 23a-2 on the lower stage side. Further, the gas blown from the second fan 22 is divided into upper and lower gases by the third intake port 23b-1 on the upper stage side and the fourth intake port 23b-2 on the lower stage side. Between the first intake port 23a-1 and the second lower intake port 23a-2, and between the third intake port 23b-1 and the lower fourth intake port 23b-2. For example, a flat plate having a thickness of 1 mm is provided.

  The first intake port 23a-1 and the third intake port 23b-1 are formed in the upper part of the duct 23 shown in FIGS. 5A and 6A (cross section A in FIG. 4). Further, the upper portion of the duct 23 guides the gas sucked from the first air inlet 23a-1 to the right side, and merges it with the gas sucked from the third air inlet 23b-1. The air is exhausted from the exhaust port 23c. As will be described in detail later, the gas exhausted from the first exhaust port 23c is blown to the first region S1 shown in FIG. 2, which is a region behind the first exhaust port 23c.

  As shown in FIG. 5A and FIG. 6A, the first regulating plate 24-1 disposed in the upper stage portion of the duct 23 is blown from two adjacent fans 21 and 22 and is divided into two pieces of gas divided by the duct 23. It rotates about the rotation axis between two flow paths. The two flow paths are a flow path that continues from the first intake port 23a-1 to the first exhaust port 23c, and a flow path that continues from the third intake port 23b-1 to the first exhaust port 23c. is there. The first restricting plate 24-1 is rotatable to a position for restricting the backflow of gas to one of the two fans 21 and 22, and a position for restricting the backflow of gas to the other.

  The second intake port 23a-2 and the fourth intake port 23b-2 are formed in the lower part of the duct 23 shown in FIGS. 5B and 6B (cross section B in FIG. 4). The lower part of the duct 23 guides the gas sucked from the fourth air inlet 23b-2 to the left side and joins the gas sucked from the second air inlet 23a-2, so that the second The air is exhausted from the exhaust port 23d. As will be described in detail later, the gas exhausted from the second exhaust port 23d is blown to the second region S2 shown in FIG. 2, which is a region behind the first exhaust port 23d.

  As shown in FIG. 5B and FIG. 6B, the second regulating plate 24-2 disposed in the lower part of the duct 23 is supplied with two gases 2 blown from two adjacent fans 21 and 22 and divided by the duct 23. It rotates about the rotation axis between two flow paths. The two flow paths are a flow path that continues from the second intake port 23a-2 to the second exhaust port 23d, and a flow path that continues from the fourth intake port 23b-2 to the second exhaust port 23d. is there. Moreover, the 2nd control board 24-2 can be rotated to the position which controls the backflow of the gas to one of the two fans 21 and 22, and the position which controls the backflow of the gas to the other.

  FIG. 7A is an explanatory diagram showing a gas flow in a section A of FIG. FIG. 7B is an explanatory diagram illustrating a gas flow in a B cross-section portion of FIG. 4. FIG. 7C is a composite diagram of FIGS. 7A and 7B.

  As shown in FIG. 7A, the upper portion of the duct 23 is configured to receive the gas G21-1 sucked from the first air inlet 23a-1 and the gas G22-1 sucked from the third air inlet 23b-1. It guides so that it may exhaust from 1 exhaust port 23c. As a result, the gas exhausted from the first exhaust port 23c is blown to the first region S1 indicated by a two-dot chain line, which is a region behind the first exhaust port 23c. At this time, the 1st control board 24-1 exists in the position between these with the flow of gas G21-1, G22-1.

  As shown in FIG. 7B, the lower portion of the duct 23 is configured to receive the gas G22-1 sucked from the second air inlet 23a-2 and the gas G22-2 sucked from the fourth air inlet 23b-2. The second exhaust port 23d is guided to be exhausted. Thereby, the gas exhausted from the second exhaust port 23d is blown to the second region S2 indicated by a two-dot chain line, which is a region behind the second exhaust port 23d. At this time, the 2nd control board 24-2 exists in the position between these with the flow of gas G21-2, 22-2.

  As shown in FIG. 7C, the duct 23 includes the gas G21-1 and the second region in the direction toward the first region S1 of the gas blown from the first fan 21 by the above-described upper and lower portions. It divides | segments into gas G21-2 of the direction which goes to S2. Further, the duct 23 divides the gas blown from the second fan 22 into a gas G22-1 in the direction toward the first region S1 and a gas G22-2 in the direction toward the second region S2. The gas blown from the first fan 21 is blown from the first region S1 when the gas is divided into a plurality of directions including the direction toward the first region S1 and from the second fan 22. The first region S1 in the case where the gas is divided into a plurality of directions of gas including the direction toward the first region S1 does not need to be a region that exactly matches. The same applies to the second region S2.

  Even when the first fan 21 fails as shown in FIGS. 8A to 8C, the duct 23 causes the gas blown from the second fan 22 to the first region in the upper portion shown in FIGS. 8A and 8C. The gas that is guided in the direction toward S1 (gas G22-1) and blown from the second fan 22 in the lower portion shown in FIGS. 8B and 8C is directed in the direction toward the second region S2 (gas G22-2). To guide.

  Since the pressure on the intake side of the first fan 21 in operation is in a low pressure state, a backflow of gas may occur when the first fan 21 fails. However, as shown in FIG. 8A and FIG. 8B, the upper first restriction plate 24-1 and the lower second restriction plate 24-2 have a gas reverse flow from the first fan 21 due to the gas reverse flow. Rotate to a position to regulate.

  When the second fan 22 fails as shown in FIGS. 9A to 9C, the duct 23 causes the gas blown from the first fan 22 to the first region S1 in the upper portion shown in FIGS. 9A and 9C. Guide to the direction (gas G21-1) toward In addition, the duct 23 guides the gas blown from the second fan 22 in the direction toward the second region S2 (gas G21-2) in the lower portion shown in FIGS. 9B and 9C.

  In addition, since the pressure on the intake side of the second fan 22 in operation is in a low pressure state, in the same way as when the first fan 21 described above fails, the gas also occurs when the second fan 22 fails. Regurgitation may occur. However, as shown in FIGS. 9A and 9B, the upper first restriction plate 24-1 and the lower second restriction plate 24-2 are configured to cause the gas reverse flow from the second fan 22 by the gas reverse flow. Rotate to a position to regulate.

  Hereinafter, a fluid simulation for verifying the cooling performance of the fans 21 and 22 in the normal time and the failure time will be described.

  FIG. 10 is a perspective view showing the arrangement of the cooling device 20 according to the present embodiment in the fluid simulation.

  In cooling device 20, as shown in Drawing 7C, Drawing 8C, and Drawing 9C, each of the 1st fan 21 and the 2nd fan 22 blows gas to both the 1st field S1 and the 2nd field S2. To do.

  FIG. 11 is a perspective view showing the arrangement of the cooling fans 21 and 22 according to the comparative example in the fluid simulation. In addition, the cooling fans 21 and 22 which concern on a comparative example remove | exclude the duct 23 and the control plates 24-1 and 24-2 from the cooling device 20 which concerns on this embodiment.

  The first cooling fan 21 according to the comparative example blows gas mainly to the second region S2. The second cooling fan 22 according to the comparative example blows gas mainly to the first region S1.

  FIG. 12 is a side view showing the second heat generating component 6 for explaining the temperature measurement point P. FIG.

  FIG. 13 is a chart showing fluid simulation results.

  As shown in FIG. 12, the second heat generating component 6 includes a heat generator 6a that is, for example, a CPU, and a heat sink 6b. The temperature measurement point P is the central part of the heating element 6a. The heating element 6a has a planar shape of 45 mm × 45 mm and a height of 2.6 mm as an example, and the heat sink 6b has a planar shape of 95 mm × 100 mm and a height of 32 mm as an example.

  As shown in FIG. 13, during normal operation, that is, when the first fan 21 and the second fan 22 are in operation, the temperature of the heating element 6a is 63.6 ° C. in the present embodiment, and 64 in the comparative example. .3 ° C.

  When the first fan 21 fails, the temperature of the heating element 6a is 73.2 ° C. in the present embodiment and 79.7 ° C. in the comparative example. The temperature rise from the normal time is 9.6 ° C. in this embodiment and 15.4 ° C. in the comparative example, and it can be understood that this embodiment can suppress the temperature rise by 5.8 ° C. than the comparative example. .

  In this embodiment, as shown in FIG. 8C, the second fan 22 blows gas to both the first region S1 and the second region S2, whereas in the comparative example, the second fan 22 This is because the gas 22 is blown only to the first region S1.

  Similarly, when the second fan 22 fails, the temperature of the heating element 6a is 73.6 ° C. in the present embodiment and 79.9 ° C. in the comparative example. The temperature rise from the normal time is 10.0 ° C. in the present embodiment and 15.6 ° C. in the comparative example, and it can be understood that this embodiment can suppress the temperature rise by 5.6 ° C. than the comparative example. .

  In the present embodiment, the first fan 21 blows gas to both the first region S1 and the second region S2 as shown in FIG. 9C, whereas in the comparative example, the first fan 21 This is because the gas 21 is blown only to the second region S2.

  As described above, in the comparative example, when the fans 21 and 22 fail, an average temperature increase of 15.6 ° C. is observed compared to the normal time, and the cooling performance is reduced. However, in the case of this embodiment, the average temperature rise is 9.8 ° C., and the temperature rise at the time of failure of the fans 21 and 22 is reduced by 5.7 ° C. compared with the comparative example to prevent the cooling performance from being lowered I understand that.

  Furthermore, as shown in FIGS. 7C, 8C, and 9C, the cooling device 20 according to the present embodiment includes the first fan 21 and the second fan 22 in the first region S1 and the second region S2, respectively. Since the gas is blown to both of the areas S2, even if one of the fans 21 and 22 breaks down, it is possible to suppress uneven cooling in the first area S1 and the second area S2.

  Furthermore, in this embodiment, when one fan fails, when the rotation speed of the other fan is increased by, for example, twice, the amount of gas blown to the first region S1 and the second region S2 is reduced. Therefore, it is possible to prevent a temperature rise when a fan fails.

  In the present embodiment described above, the duct (an example of a dividing mechanism) 23 causes the gas blown from the first fan 21 to flow toward the first region S1 and toward the second region S2 (first). Is divided into gas in one direction including a direction toward the first area), and the gas blown from the second fan 22 is directed toward the first area S1 and the second area S2 (first direction). The gas is divided into gas in one example of a plurality of directions including a direction toward one region.

  For this reason, even if the first fan 21 or the second fan 22 fails, at least the cooling of the first region S1 can be continued. Therefore, according to the present embodiment, it is possible to suppress uneven cooling when a fan fails.

  Moreover, in this embodiment, the 1st control board 24-1 and the 2nd control board 24-2 control the backflow of the gas to the failed fan among the some fans 21 and 22. Therefore, even if the fans 21 and 22 fail, the duct 23 can reliably divide the gas by preventing the reverse flow of the gas from the failed fan. Therefore, the cooling unevenness at the time of fan failure can be suppressed more reliably.

  Further, in the present embodiment, the duct 23 is configured so that the gas blown from each of the plurality of fans 21 and 22 is in the same number of regions as the number of fans of the plurality of fans (two in the present embodiment) and the plurality of fans 21. , 22 is divided into gas in the direction toward the common areas S1, S2. Therefore, even if a part of the fans breaks down, the other fans can send the gas evenly to the same number of areas. Therefore, the cooling unevenness at the time of fan failure can be suppressed more reliably.

  In the present embodiment, an example of the plurality of fans is the first fan 21 and the second fan 22, and the duct 23 uses gas blown from each of the first fan 21 and the second fan 22. The gas G21-1 and G22-1 in the direction toward the first region S1 and the gas G21-2 and G22-2 in the direction toward the second region S2 are divided. Therefore, even if one fan fails, the other fan can send gas evenly to the two areas. Further, the gas can be divided into two gases by a simple configuration in which the duct 23 divides the gas blown from the two fans 21 and 22 into two gases. Therefore, the cooling unevenness at the time of fan failure can be more reliably suppressed, and the structure of the cooling device 20 can be prevented from becoming complicated.

  Moreover, in this embodiment, the duct 23 merges the gas divided by being blown from the first fan 21 and the second fan 22 (an example of at least two fans). Therefore, the gas blown from a plurality of fans can be reliably sent to each region by the duct 23. Therefore, the cooling unevenness at the time of fan failure can be suppressed more reliably.

  In the present embodiment, the first restricting plate 24-1 and the second restricting plate 24-2 are two flow paths of gas blown from the two adjacent fans 21 and 22 and divided by the duct 23. Between the two fans 21 and 22, the position where the backflow of gas to one of the two fans 21 and 22 is restricted, and the position where the backflow of gas to the other is restricted. Therefore, it is possible to prevent the backflow of gas from the failed fan with a simple configuration. Therefore, the cooling unevenness at the time of fan failure can be more reliably suppressed with a simple configuration.

  In the present embodiment, as an example of the dividing mechanism, a duct 23 that forms not only a gas but also a gas flow path is used. Therefore, the divided gas can be sent in each direction with a simple configuration. Therefore, the cooling unevenness at the time of fan failure can be more reliably suppressed with a simple configuration.

Second Embodiment
In the present embodiment, the gas blown from the three fans 31, 32, and 33 is divided into two gases, respectively, and gas is blown from the two fans to each of the three regions. In the present embodiment, a plurality of regulating plates 35 are provided at each intake port of the duct 34. Since points other than these are the same as in the first embodiment described above, detailed description thereof is omitted.

  FIG. 14 is a perspective view showing the duct 34 and the restriction plate 35 in the second embodiment.

  FIG. 15A is a perspective view showing the internal structure of the upper part of the duct 34, and FIG. 15B is a perspective view showing the internal structure of the lower part of the duct 34.

  FIG. 16A is a plan view showing the internal structure of the upper part of the duct 34, and FIG. 15B is a plan view showing the internal structure of the lower part of the duct 34.

  FIG. 17 is an explanatory diagram showing the gas flow in the duct 34.

  The duct 34 is formed with first to sixth intake ports 34a-1, 34a-2, 34b-1, 34b-2, 34c-1, and 34c-2.

  As shown in FIGS. 16A and 16B, the first air inlet 34 a-1 and the second air inlet 34 a-2 are blown with gas from the first fan 31. The third air inlet 34 b-1 and the fourth air inlet 34 b-2 are blown with gas from the second fan 32. The fifth air inlet 34 c-1 and the sixth air inlet 34 c-2 are blown with gas from the third fan 33.

  The gas blown from the first fan 31 is divided into two upper and lower gases by the first intake port 34a-1 on the upper stage side and the second intake port 34a-2 on the lower stage side. The gas blown from the second fan 32 is divided into two upper and lower gases by the third intake port 34b-1 on the upper stage side and the fourth intake port 34b-2 on the lower stage side. The gas blown from the third fan 33 is divided into two upper and lower gases by the upper fifth intake port 34c-1 and the lower sixth intake port 34c-2.

  For example, four restriction plates 35 shown in FIG. 14 are provided in each of the first to sixth intake ports 34a-1, 34a-2, 34b-1, 34b-2, 34c-1, and 34c-2 of the duct 34. (In FIG. 14, the restriction plate 35 is shown only in the first intake port 34a-1 and the second intake port 34a-2). The restriction plate 35 includes a rotation shaft 35a and a plate material 35b.

  The four rotation shafts 35a of each intake port are provided in parallel to each other so as to be bridged over two opposite sides of the intake port. The four plate members 35b are centered on the rotation shaft 35a and are located at a position where the intake port of the duct 34 is closed, and an open position parallel to the gas flow direction by the gas blown from the fans 31, 32, 33. It can be rotated.

  Since the pressure on the intake side of the operating fans 31, 32, and 33 is in a low pressure state, a gas backflow may occur if the fan breaks down. However, the plate member 35 b of the regulation plate 35 is not supported by the gas backflow. It rotates to the position which controls the backflow of the gas from.

  Further, the plate member 35b of the regulating plate 35 is opened by the gas flow during operation of the fan, and rotates to a position parallel to the gas flow direction.

  As shown in FIG. 14, FIG. 15A, and FIG. 16A, the upper part of the duct 34 is on the right side so that the gas sucked from the first air inlet 34a-1 is exhausted from the second air outlet 34e. To guide. Further, the duct 34 guides the gas sucked from the third air inlet 34b-1 to the right side, and merges it with the gas sucked from the fifth air inlet 34c-1, so that the fourth air outlet Exhaust from 34g.

  As shown in FIGS. 14, 15B, and 16B, the lower part of the duct 34 is on the left side so that the gas sucked from the fourth air inlet 34b-2 is exhausted from the first air outlet 34d. The air is exhausted from the first exhaust port 34d by guiding and joining the gas sucked from the second intake port 34a-2. The duct 34 guides the gas sucked from the sixth air inlet 34c-2 to the left side so as to be exhausted from the third air outlet 34f. Note that the third exhaust port 34f is located below the second exhaust port 34e, and exhausts the gas toward the second region S12 together with the second exhaust port 34e.

  As shown in FIG. 17, the duct 34 is configured so that the gas blown from the first fan 31 shown in FIGS. 16A and 16B by the above-described upper stage portion and lower stage portion is in the direction toward the second region S12. It divides | segments into G31-1 and gas G31-2 of the direction which goes to 1st area | region S11.

  Further, the duct 34 divides the gas blown from the second fan 32 into a gas G32-1 in the direction toward the third region S13 and a gas G31-2 in the direction toward the first region S11.

  Further, the duct 34 divides the gas blown from the third fan 33 into a gas G33-1 in the direction toward the third region S13 and a gas G33-2 in the direction toward the second region S12.

  As described above, since gas is sent from the two fans to each of the regions S11, S12, and S13, even when one fan fails, the duct 34 guides the gas to each region.

  In the present embodiment described above, the duct (an example of a dividing mechanism) 34 causes the gas blown from the first fan 31 to move toward the second region S12 and toward the first region S11 (first). The gas is divided into gas in one direction including the direction toward the first region), and the gas blown from the second fan 32 is directed to the third region S13 and the first region S11 (first direction). The gas is divided into gas in one example of a plurality of directions including a direction toward one region.

  Therefore, the cooling of the first region S11 can be continued even if the first fan 31 or the second fan 32 fails. Therefore, according to the present embodiment, it is possible to suppress uneven cooling when a fan fails.

  In the present embodiment, the duct 34 divides the gas blown from the first fan 31 into a gas in the direction toward the first region S11 and a gas in the direction toward the second region S12, and the second The gas blown from the fan 32 is divided into a gas in the direction toward the first region S11 and a gas in the direction toward the third region S13, and the gas blown from the third fan 33 is divided into the second region. It divides | segments into the gas of the direction which goes to S12, and the gas of the direction which goes to 3rd area | region S13. Therefore, even if any fan breaks down, gas can be blown from other fans to each of the regions S11 to S13. Therefore, the cooling unevenness at the time of fan failure can be suppressed more reliably.

<Third Embodiment>
In this embodiment, each of the gas blown from the three fans 31, 32, 33 is divided into three gases, and the gas is blown from the three fans to each of the three regions S21 to S23. In the present embodiment, the restriction plate 45 is the same as the restriction plate 35 in the second embodiment. Since points other than these are the same as in the first embodiment described above, detailed description thereof is omitted.

  FIG. 18 is a perspective view showing the duct 44 and the restriction plate 45 in the third embodiment.

  19A is a perspective view showing the internal structure of the upper part of the duct 44, FIG. 19B is a perspective view showing the internal structure of the middle part of the duct 44, and FIG. 19C shows the internal structure of the lower part of the duct 44. FIG.

  20A is a perspective view showing the internal structure of the upper part of the duct 44, FIG. 20B is a perspective view showing the internal structure of the middle part of the duct 44, and FIG. 20C shows the internal structure of the lower part of the duct 44. FIG.

FIG. 21 is an explanatory diagram showing the gas flow in the duct 44.
The duct 44 is formed with first to ninth intake ports 44a-1, 44a-2, 44a-3, 44b-1, 44b-2, 44b-3, 44c-1, 44c-2, 44c-3. Has been.

  As shown in FIGS. 20A to 20C, the first air inlet 44 a-1, the second air inlet 44 a-2, and the third air inlet 44 a-3 are blown with gas from the first fan 41. . The fourth intake port 44 b-1, the fifth intake port 44 b-2, and the sixth intake port 44 b-3 are blown with gas from the second fan 42. The seventh air inlet 44 c-1, the eighth air inlet 44 c-2, and the ninth air inlet 44 c-3 are blown with gas from the third fan 43.

  The gas blown from the first fan 41 is raised by the first intake port 44a-1 on the upper stage side, the second intake port 44a-2 on the middle stage side, and the third intake port 44a-3 on the lower stage side. Divided into middle and lower gas. The gas blown from the second fan 42 is raised by the fourth intake port 44b-1 on the upper stage side, the fifth intake port 44b-2 on the middle stage side, and the sixth intake port 44b-3 on the lower stage side. Divided into middle and lower gas. The gas blown from the third fan 43 is raised by the upper seventh intake port 44c-1, the middle eighth intake port 44c-2, and the lower ninth intake port 44c-3. Divided into middle and lower gas.

  For example, four restriction plates 45 shown in FIG. 18 are provided in each of the first to ninth intake ports of the duct 44 (in FIG. 18, the restriction plates 45 are illustrated only in the first to third intake ports. ). The restriction plate 45 includes a rotation shaft 45a and a plate material 45b.

  The four rotation shafts 45a of each intake port are provided in parallel to each other so as to be bridged over two opposite sides of the intake port. The four plate members 45b are centered on the rotation shaft 45a and are located at a position where the intake port of the duct 44 is blocked, and at an open position parallel to the gas flow direction by the gas blown from the fans 41, 42, 43. It can be rotated.

  Since the pressure on the intake side of the operating fans 41, 42, and 43 is in a low pressure state, a back flow of gas may occur if the fan breaks down. However, the plate material 45b of the regulating plate 45 is It rotates to the position which controls the backflow of the gas from.

  Further, the plate member 45b of the regulating plate 45 is opened by the gas flow during operation of the fan, and rotates to a position parallel to the gas flow direction.

  As shown in FIGS. 18, 19A, and 20A, the upper stage portion of the duct 44 allows the gas sucked from the first intake port 44a-1 and the fourth intake port 44b-1 to flow into the third exhaust port. The gas is exhausted from the third exhaust port 44f by being guided to the right side so as to be exhausted from the 44f and joining the gas sucked from the seventh intake port 44c-1.

  As shown in FIG. 18, FIG. 19B, and FIG. 20B, the middle portion of the duct 44 supplies the gas sucked from the second intake port 44a-2 and the eighth intake port 44c-2 to the second exhaust port. The air is exhausted from the second exhaust port 44e by being guided to the center side so as to be exhausted from 44e, and joining the gas sucked from the fifth intake port 44b-2.

  As shown in FIGS. 18, 19C, and 20C, the lower portion of the duct 44 allows the gas sucked from the sixth intake port 44b-3 and the ninth intake port 44c-3 to flow into the first exhaust port. The gas is exhausted from the first exhaust port 44d by being guided to the left side so as to be exhausted from 44d, and joining the gas sucked from the third intake port 44a-3.

  As shown in FIG. 21, the duct 44 causes the gas blown from the first fan 41 shown in FIGS. 20A and 20B toward the third region S23 by the above-described upper stage portion, middle stage portion, and lower stage portion. The gas G41-1 in the direction, the gas G41-2 in the direction toward the second region S22, and the gas G41-3 in the direction toward the first region S21 are divided.

  Similarly, in the duct 44, the gas blown from the second fan 42 and the third fan is also directed to the gases G42-1 and G43-1 in the direction toward the third region S23 and the second region S22. The gas G42-2 and G43-2 in the direction and the gas G42-3 and G43-3 in the direction toward the first region S21 are divided.

  Thus, since gas is sent from each of the three fans to each of the regions S11, S12, and S13, even if any of the fans fails, the duct 34 guides the gas from the two fans to each region.

  In the present embodiment described above, the duct (an example of a dividing mechanism) 44 divides the gas blown from the first fan 41 into a gas in a direction toward the first region S11 and the like, and the second fan 32. The gas blown from is divided into gases in the direction toward the first region S11.

  Therefore, the cooling of the first region S21 can be continued even if the first fan 31 or the second fan 32 fails. Therefore, according to the present embodiment, it is possible to suppress uneven cooling when a fan fails.

  Moreover, in this embodiment, the duct 44 is the area | region of the same number as the number of fans (this embodiment three) of the some fan, and the several fan 41 sends the gas ventilated from each of the several fans 41-43. The gas is divided into gases in the direction toward the regions S21, S22, and S23 common to .about.43. Therefore, even if a part of the fans breaks down, the other fans can send the gas evenly to the same number of areas. Therefore, the cooling unevenness at the time of fan failure can be suppressed more reliably.

  Moreover, in this embodiment, an example of a some fan is the 1st-3rd fans 41-43, and the duct 44 makes the 1st the gas ventilated from each of the 1st-3rd fans 41-43 1st. It divides | segments into the gas of the direction which goes to the area | region S21, the direction which goes to the 2nd area | region S22, and the gas which goes to the 3rd area | region S23. Therefore, even if a part of the fans breaks down, the gas can be evenly sent to the three areas by the other fans. Therefore, it is possible to more reliably suppress the cooling unevenness when the fan fails, and to prevent the structure of the cooling device from becoming complicated.

DESCRIPTION OF SYMBOLS 1 Electronic device 2 Housing | casing 3 Exhaust part 4 Board | substrate 5,6 Heat generating component 6a Heat generating body 6b Heat sink 10 Cooling device 11 1st fan 12 2nd fan 13 Duct 13a-1 1st inlet 13a-2 2nd Inlet 13b-1 Third Inlet 13b-2 Fourth Inlet 13c First Exhaust 13d Second Exhaust 20 Cooling Device 21 First Fan 22 Second Fan 23 Duct 23a-1 First Inlet 23a-2 Second Inlet 23b-1 Third Inlet 23b-2 Fourth Inlet 23c First Exhaust Port 23d Second Exhaust Port 24-1 First Regulating Plate 24-2 Second restriction plate 31 First fan 32 Second fan 33 Third fan 34 Duct 34a-1 First air inlet 34a-2 Second air inlet 34b-1 Third air inlet 34b-2 4 inlet 34 -1 5th intake port 34c-2 6th intake port 34d 1st exhaust port 34e 2nd exhaust port 34f 3rd exhaust port 34g 4th exhaust port 35 1st regulating plate 35a Rotating shaft 35b Plate material 41 1st fan 42 2nd fan 43 3rd fan 44 Duct 44a-1 1st inlet 44a-2 2nd inlet 44a-3 3rd inlet 44b-1 4th inlet 44b-2 5th intake port 44b-3 6th intake port 44c-1 7th intake port 44c-2 8th intake port 44c-3 9th intake port 44d 1st exhaust port 44e 2nd Exhaust port 44f Third exhaust port 45 First restriction plate 45a Rotating shaft 45b Plate material

Claims (10)

A plurality of fans including a first fan and a second fan;
The gas blown from the first fan is divided into a plurality of directions of gas including a direction toward the first region, and the gas blown from the second fan is directed toward the first region. A dividing mechanism that divides the gas into a plurality of directions including:
A cooling device comprising:   The cooling device according to claim 1, further comprising a regulating plate that regulates the backflow of gas to the failed fan among the plurality of fans.   The dividing mechanism divides the gas blown from each of the plurality of fans into a gas in a direction toward the area common to the plurality of fans in the same number of fans as the number of fans of the plurality of fans. The cooling device according to claim 1.   The dividing mechanism divides the gas blown from each of the first fan and the second fan into a gas in a direction toward the first region and a gas in a direction toward the second region. The cooling device according to claim 3. The plurality of fans further includes a third fan,
The dividing mechanism is configured to move the gas blown from each of the first fan, the second fan, and the third fan to a gas in a direction toward the first region and a direction toward the second region. The cooling device according to claim 3, wherein the cooling device is divided into a gas in a direction toward the third region. The plurality of fans further includes a third fan,
The dividing mechanism divides the gas blown from the first fan into a gas in a direction toward the first region and a gas in a direction toward the second region, and is blown from the second fan. Gas is divided into a gas in a direction toward the first region and a gas in a direction toward the third region, and the gas blown from the third fan is divided in a direction toward the second region. Dividing into a gas and a gas in a direction toward the third region,
The cooling device according to claim 1.   The cooling device according to claim 1, wherein the division mechanism joins the divided gases blown from at least two of the plurality of fans.   The restricting plate is configured such that the gas flows backward to one of the two fans with a rotation axis between the two flow paths of the gas blown from the two adjacent fans and divided by the dividing mechanism. The cooling device according to claim 2, wherein the cooling device is rotatable to a position for regulating the backflow and a position for regulating the backflow of the gas to the other.   The cooling device according to claim 1, wherein the dividing mechanism is a duct in which a plurality of flow paths are formed. A heat generating component disposed at least in the first region;
A plurality of fans including a first fan and a second fan;
The gas blown from the first fan is divided into gas in a plurality of directions including a direction toward the first region, and the gas blown from the second fan is directed to the first region. A dividing mechanism that divides the gas into a plurality of directions including directions;
An electronic device comprising:

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