JP4742016B2 - Electronic equipment - Google Patents

Description

  The present invention relates to an electronic device.

  As an electronic device that cools a heat-generating component in an apparatus housing by a cooling fan disposed in the apparatus housing, an electronic device described in Patent Document 1 is known. In this conventional example, a plurality of printed circuit boards as devices to be cooled are arranged over almost the entire area of the apparatus casing in the apparatus casing. In addition, a duct provided with a cooling fan is arranged in the device casing, and heat generated from the printed circuit boards is guided to the duct through the ventilation path between the printed circuit boards and then released to the outside of the apparatus casing. The

  However, in the above-described conventional example, since the cooling fan is provided corresponding to the entire apparatus to be cooled in the apparatus housing, there is a problem that the apparatus cannot be reduced in size. That is, when each cooling target device is uniformly cooled using a common fan in the device casing, it is desirable that the cooling air passage for each cooling target device has a small pressure loss and is homogenized. The condition makes it difficult to reduce the size of the device by arranging the objects to be cooled at high density, or causes the size of the device to be increased by installing an excessive common fan assuming a cooling air passage with a large pressure loss.

  As shown in FIG. 4, the problem is that the cooling target device 1, the heat generation amount, and the cooling fan 2 corresponding to the pressure loss of the cooling air passage are accommodated in the divided wind tunnel 4, so that the cooling target device 1 can be mounted at high density. By making it possible, it is possible to eliminate the problem by cooling the common cooling target device 5 arranged in the common region 3 by using the cooling air flowing into the divided wind tunnel 4 to effectively use the space. it can.

  However, the electronic device configured as described above can achieve downsizing of the device by increasing the mounting efficiency, but has a drawback that the cooling reliability is lowered. That is, as shown in FIG. 4, the fan-mounted unit stored in the divided wind tunnel 4 is of a type in which the unit internal ventilation portion 7 is provided alongside the cooling air suction port of the unit-mounted fan 2, When the cooling fan 2 is disposed, if the downstream cooling fan 2 breaks down, the pressure loss increases and the exhaust from the unit mounting fan 2 circulates into the unit ventilation section 7.

When the sneak occurs in the fan-mounted unit, the intake air amount by the divided wind tunnel 4 in which the fan-mounted unit is accommodated decreases, and as a result, the cooling air amount in the common area 3 decreases, and the cooling target device in the common area 3 Insufficient cooling occurs.
JP 2000-124646 A

  The present invention has been made to solve the above-described drawbacks, and an object of the present invention is to provide an electronic apparatus that can downsize the apparatus and can stably cool the apparatus to be cooled.

  The apparatus housing has an appropriate number of divided wind tunnels 4 branched from the common region 3, and the cooling target apparatus 1 and a cooling fan 2 for cooling the apparatus are accommodated in each divided wind tunnel 4. Since the cooling target device 1 and the cooling fan 2 for cooling the cooling target device 1 are accommodated in the split wind tunnel 4 in a pair, the cooling of each cooling target device 1 can be ensured. 1 high density arrangement is possible. Further, since the cooling air is supplied to the common region 3 by the cooling fans 2 arranged in the respective divided wind tunnels 4, the special cooling fan 2 for the common cooling target device 5 is not necessary, and coupled with the high-density arrangement described above. The device can be miniaturized.

  Furthermore, a unit of a type provided with a fan ventilation portion 6 through which cooling air from the unit-mounted fan 2 and an in-unit ventilation portion 7 are provided (this type of unit is referred to as “fan side-by-side unit 1A” in this specification). A divided wind tunnel 4 in which another cooling fan 2 is disposed downstream of the fan juxtaposed unit 1A (this divided wind tunnel 4 is referred to as a “parallel unit storing wind tunnel 8” in this specification) is closed with a boundary wall 9. A wall 10 is provided to isolate the in-unit ventilation portion 7 from the fan ventilation portion 6. When the downstream side cooling fan 2 is operating normally, cooling air is introduced into the unit ventilation section 7 from the outside air introduction opening 11 provided in the wall surface of the apparatus casing, and the fan juxtaposed unit 1A is cooled. Furthermore, the cooling fan 2 mounted on the fan juxtaposed unit 1A contributes to securing the cooling air volume in the common area 3.

  On the other hand, when the downstream cooling fan 2 fails and stops, the pressure loss on the downstream side of the fan ventilation portion 6 increases, but the circulatory flow path to the in-unit ventilation portion 7 is blocked. In addition, the amount of cooling air passing through the fan ventilation portion 6 is not greatly reduced, and it can still contribute to securing the amount of cooling air in the common region 3 and stable cooling can be obtained.

  ADVANTAGE OF THE INVENTION According to this invention, an apparatus can be reduced in size and the stable cooling with respect to a cooling object apparatus is attained.

  An embodiment of the present invention applied as a RAID (Redundant Arrays Inexpensive Disks) type disk array device is shown in FIGS. The disk array device is formed by storing a plurality of hard disk devices 5, a control unit 1 </ b> B for controlling access to these hard disk devices 5, a battery unit, and a power supply unit 18 in a device housing 15.

  The device housing 15 that accommodates the hard disk device 5 and the like has a common region 3 and a divided wind tunnel 4 that branches from the common region 3, and a common cooling target in the common region 3 that opens to the front wall side. A hard disk device 5 as the device 5 is stored. Each hard disk device 5 is connected to a back panel 16 disposed in the common area 3 to perform power supply from the power supply unit 18 and communication with the control unit 1B. The hard disk devices 5 are arranged at equal intervals so that the flow of the cooling air in the common area 3 is made smooth and the hard disk devices 5 are evenly cooled.

  On the other hand, the split wind tunnel 4 has a hollow rectangular cross section that is opened outward from the rear surface of the apparatus housing 15 and is partitioned from another adjacent split wind tunnel 4 by a partition wall 17. The power supply unit 18, the control unit 1B, and the battery unit 1C are housed in separate divided wind tunnels 4, and the control unit 1B and the battery unit 1C each have a fan mounted with a cooling fan 2 capable of cooling its own unit. Configured as a unit. Each unit-mounted fan 2 is driven such that cooling air flows from the front side of the apparatus housing 15 toward the back side.

  The power supply unit 18 converts an ACDC power supply unit 1D that converts a commercial power supply into a DC power supply having a predetermined voltage (12V in this embodiment), and transforms an output from the ACDC power supply unit 1D to a predetermined AC voltage to control a device or the like. It is formed by connecting to a DCDC power supply unit 1A that feeds power. In this embodiment in which the mounted fan on the DCDC power supply unit 1A is also used as a cooling air intake fan from the common area 3, the ACDC power supply unit 1D is disposed on the downstream side of the DCDC power supply unit 1A.

  The units constituting the power supply unit 18 are configured as fan-mounted units each equipped with a cooling fan 2 capable of cooling the own unit, and fan ventilation in the DCDC power supply unit 1A described later is provided on the ACDC power supply unit 1D. Two cooling fans 2 arranged on the extended regions of the part 6 and the unit internal ventilation part 7 are mounted.

  In order to obtain the operation reliability of the apparatus, the control unit 1B and the power supply unit 18 have a redundant structure, and two sets are arranged at symmetrical positions of the apparatus casing 15, respectively. Further, the ACDC power supply unit 1D and the DCDC power supply unit 1A provided in two sets operate as a pair in each set. For example, when one of the ACDC power supply units 1D breaks down, the DCDC power supply unit 1A belonging to this set Operation stops.

  Further, as will be described later, since the cooling fan 2 mounted with the DCDC power supply unit 1A also serves as a cooling air supply to the common region 3, the ACDC power supply unit 1D belonging to one of the groups, and a pair thereof Even when the DCDC power supply unit 1A to be operated is stopped, it is configured so that it can be operated by receiving power from another set of DCDC power supply units 1A.

  The DCDC power supply unit 1 </ b> A constituting the power supply unit 18 is formed by arranging a mounting area for a DCDC converter component that is a cooling target component on the side of the unit mounting fan 2. As a result, the DCDC power supply unit 1A includes a fan juxtaposed unit in which the in-unit ventilation portion 7 for supplying cooling air to the components to be cooled is arranged in parallel to the fan ventilation portion 6 through which the cooling air from the unit mounting fan 2 passes. Configured as 1A. As described above, the side-by-side unit storage wind tunnel 8 in which the fan side-by-side unit 1A is stored has another cooling fan 2 (unit-mounted fan 2 on the ACDC power supply unit 1D in this embodiment) located on the downstream side. There is a risk of cooling air sneaking occurring when it stops, and in order to avoid this, the in-unit ventilation portion 7 and the fan ventilation portion 6 are partitioned by the boundary wall 9 and the blocking wall 10.

  The boundary wall 9 is extended to the vicinity of the unit mounting fan 2 on the ACDC power supply unit 1D, and the blocking wall 10 completely closes the upstream opening of the unit internal ventilation unit 2 and leads to the isolated unit internal ventilation unit 2 In order to supply cooling air, an outside air introduction opening 11 is opened in the ceiling wall of the device casing 15, the ACDC power supply unit 1D, and the DCDC power supply unit 1A.

  The cooling operation of the disk array apparatus configured as described above will be described with reference to FIGS. In the figure, the flow of cooling air is indicated by a chain line.

  As described above, in a state where the units in each divided wind tunnel 4 are operating normally, each unit is cooled by the unit mounting fan 2, and further, by the cooling air guided to the common area 3 by these unit mounting fans 2. The hard disk device 5 is cooled.

  At this time, in the fan ventilation section 6 basin of the power supply section 18, as shown in FIG. 3A, the DCDC power supply unit 1A is cooled by the unit mounting fan 2 on the DCDC power supply unit 1A, and the ACDC power supply unit 1D is Cooling of the ACDC power supply unit 1D by the unit mounting fan 2 is performed, and cooling air intake from the common area 3 is performed by the unit mounting fan 2 on the DCDC power supply unit 1A. As shown in FIG. 3 (b), in the in-unit ventilation section 7 basin of the power supply section 18, the cooling air from the outside air introduction opening 11 by the unit mounting fan 2 on the ACDC power supply unit 1D to the in-unit ventilation section 7 Inhalation is performed, whereby the ACDC power supply unit 1D is cooled.

  From this state, when the ACDC power supply unit 1D in the divided wind tunnel 4 located at the left end in FIG. 2A fails and the unit-mounted fan 2 on the ACDC power supply unit 1D stops, power is supplied from the DCDC power supply unit 1A. However, since the power supply unit 18 has a redundant configuration as described above, the unit mounted fan on the DCDC power supply unit 1A from the DCDC power supply unit 1A in the divided wind tunnel 4 located at the right end in FIG. 2 is fed, and the unit-mounted fan 2 on the DCDC power supply unit 1A can be operated.

  Therefore, in the fan ventilation section 6 basin of the power supply section 18, the unit-mounted fan 2 on the stopped ACDC power supply unit 1D is located on the ventilation path of the cooling air from the mounted fan on the DCDC power supply unit 1A. For this reason, although the cooling air pressure resistance increases and the cooling air pressure loss increases, the circulatory flow path to the internal ventilation portion 7 is blocked by the boundary wall 9 and the blocking wall 10, so that the cooling air wraps around. Therefore, the cooling air can be blown in the back direction of the device casing 15, and as a result, the supply amount of the cooling air in the common region 3 is prevented from being lowered, and the cooling air can be stably supplied. .

  Further, in the in-unit ventilation section 7 basin of the power supply section 18, since the unit mounting fan 2 on the ACDC power supply unit 1D is stopped, the outside air introduction opening 11 by the unit mounting fan 2 on the ACDC power supply unit 1D is opened inside the unit. Although cooling air is not drawn into the ventilation section 7, the ACDC power supply unit 1D and the DCDC power supply unit 1A do not need to be operating when the fan mounted on the ACDC power supply unit 1D is stopped. Even if wind suction is not performed, there is no problem in the operation of the entire apparatus.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure which shows this invention, (a) is a disassembled perspective view of a disk array apparatus, (b) is a perspective view which fractures | ruptures and shows a part. 2A and 2B are diagrams showing details inside the disk array device, in which FIG. 1A is a plan view, FIG. 1B is a front view, and FIG. It is a figure which shows a ventilation state, (a) is the 3A-3A sectional view taken on the line of Fig.2 (a), (b) is the expanded sectional view of the 3B-3B line of Fig.2 (a). It is a figure which shows a prior art example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Cooling target apparatus 1A Fan juxtaposed unit 1B Control unit 2 Cooling fan 3 Common area 4 Divided wind tunnel 5 Common cooling target apparatus 6 Fan ventilation part 7 Unit internal ventilation part 8 Parallel unit storage wind tunnel 9 Boundary wall 10 Blocking wall 11 Outside air introduction Opening

Claims (3)

A common area in which the common cooling target devices are arranged;
A plurality of divided wind tunnels located downstream of the common region and provided with cooling fans,
At least one of the plurality of divided wind tunnels is
A fan ventilation section having a first fan that is a unit-mounted fan mounted on a cooling target device in the divided wind tunnel, and a second cooling fan disposed downstream of the unit-mounted fan;
The fan ventilation section and the boundary wall extending from the upstream side to the downstream side of the divided wind tunnel are isolated, the blocking wall closing the upstream end, the outside air introduction opening capable of taking in outside air, and the first arranged downstream of the outside air introduction opening. A ventilation unit in the unit having three cooling fans;
An electronic device comprising: The electronic device according to claim 1, wherein the second and third cooling fans are other unit-mounted fans. The electronic device according to claim 1, wherein the common cooling target device is a hard disk device, and the cooling target device in the divided wind tunnel is a power supply component unit.

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