JP2014216512A - Storage apparatus cooling device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve cooling effects of storage equipment.SOLUTION: In a storage device, a plurality of storage apparatuses 6 of a flat and rectangular parallelepiped storage housing 6a are mounted in an apparatus mount housing 3 side by side in a direction of cooling air circulation while keeping a longitudinal attitude and along the plurality of mounted storage apparatuses, cooling air 5 is circulated by a cooling air blowing fan 4. A heat exchanger plate 7 with high heat conductivity is disposed from a side face region 6aof the storage housing that is a portion close to a heat source of each storage apparatus, to an upper end face region 6aof the storage housing that becomes a top face of the storage apparatus in the style of mounting to the apparatus mount housing. A radiator plate 9 is installed via a Peltier element 8 in the upper end face region of the storage housing in each heat exchanger plate, and currents to flow to the Peltier elements are controlled in accordance with temperatures of the storage apparatuses.

Description

  The present invention relates to a storage device cooling apparatus.

  The storage device has a heating element built in the housing and needs to be cooled. In a storage device using an HDD as a storage medium, it is desirable to forcibly cool the vicinity of the drive motor because the amount of heat generated by the drive motor of the HDD is large and the temperature rise in the vicinity of the drive motor is large.

  A large-scale storage device having a configuration in which a plurality of storage canisters containing storage devices are mounted side by side on a device mounting housing and the device mounting housings are mounted in multiple stages on a rack is provided by a cooling blower fan. Each storage device is configured to be air-cooled by allowing cooling air to flow along the body.

JP 2011-119302 A

  In a large-scale storage device in which a plurality of storage devices are arranged side by side in the flow direction of the cooling air generated by the cooling fan, the temperature of the cooling air is lower than the upstream area of the flow. The cooling effect on the storage device located in the area is reduced. In order to sufficiently cool the storage device located in the downstream area, it is necessary to increase the flow rate of the cooling air. However, if the air blowing capacity of the cooling air blowing fan is increased to increase the air flow rate, the power consumption is increased. This will increase the noise generated.

  Accordingly, one object of the present invention is to efficiently realize air cooling of storage devices. In particular, a plurality of storage devices arranged side by side in the flow direction of the cooling air generated by the cooling air fan can be efficiently air-cooled to reduce power consumption and generated noise of the cooling air fan.

  Another object of the present invention is to reduce the power consumption and generated noise of the cooling fan in a large storage device in which a plurality of storage devices are arranged side by side in the cooling air flow direction so that each storage device can be efficiently air-cooled. There is to do.

  Still another object of the present invention is to enable each storage device to be efficiently air-cooled in a large-scale storage device in which a plurality of storage devices are arranged side by side in a cooling air flow direction and a direction crossing the cooling air flow direction. It is to reduce the power consumption and generated noise of the cooling fan.

The storage device cooling device according to the present invention has a plurality of storage devices mounted in a vertical orientation in which a plurality of storage devices in a flat, rectangular parallelepiped storage case are placed side by side in a cooling air flow direction in the device mounting case. In the storage device cooling device of the storage device in which the cooling air is caused to flow along the storage housing of the device by the cooling air fan,
High thermal conductivity from the side area of the storage enclosure, which is a part close to the heat source of each storage apparatus, to the upper end area of the storage enclosure, which is the upper surface of the storage apparatus in the mounting form on the apparatus mounting enclosure Place the heat transfer plate in the storage enclosure of each storage device,
Install a heat sink via a Peltier element in the upper end surface area of the storage housing of each heat transfer plate,
The current flowing through the Peltier element installed in each storage device is controlled according to the temperature of each storage device.

  The storage devices are placed side by side in a cooling air flow direction in the device mounting housing and a direction crossing the cooling air flow direction, and the cooling blower fan is arranged in a row of storage devices placed side by side ( Each cooling fan is installed in the device mounting housing every front and rear direction) and controls the operation according to the temperature of the storage device in each row.

  In addition, the cooling air blowing fans in a row in which storage devices exceeding the set temperature exist are also accelerated by the current control of the Peltier element.

Further, the storage device cooling device of the present invention is a storage device cooling device in which cooling air is allowed to flow by a cooling blower fan along the storage case of a flat and rectangular parallelepiped storage case.
A heat transfer plate with high thermal conductivity is arranged from the side surface region to the end surface region of the storage housing, which is a part close to the heat source of the storage device,
Installing a heat sink via a Peltier element in the housing end face region of the heat transfer plate,
The current flowing through the Peltier element is controlled according to the temperature of the storage device.

  The present invention has a high thermal conductivity from the side region of the storage casing close to the heat source of the storage device to the upper end surface region of the storage casing which is the upper surface of the storage device in the mounting form on the device mounting casing. A heat transfer plate is placed in the storage case of each storage device, a heat sink is installed through the Peltier element in the upper end surface area of the storage case of each heat transfer plate, and the heat flow plate flows through the Peltier element installed in each storage device By configuring the current to be controlled according to the temperature of each storage device, the air cooling efficiency can be improved. In particular, a plurality of storage devices arranged side by side in the flow direction of the cooling air generated by the cooling air fan can be efficiently air-cooled, and the power consumption and generated noise of the cooling air fan can be reduced.

  In a large storage device in which a plurality of storage devices are arranged side by side in the cooling air flow direction and the direction crossing the cooling air flow direction, a Peltier element in each storage device and a cooling fan provided for each column are provided. Since each storage device can be efficiently air-cooled by being configured to be controlled individually, the power consumption and generated noise of the cooling fan can be reduced.

It is a perspective view of a large-sized storage device showing a state in which a side plate is removed and a device mounting housing is pulled out rearward. It is a perspective view which shows the mounting state of the storage apparatus and the cooling ventilation fan to an apparatus mounting housing | casing. It is a perspective view of the storage apparatus accommodated in the storage canister. It is a side view of the storage apparatus accommodated in the storage canister. It is the end view (a) and partial enlarged view (b) which show the attachment state of the heat exchanger plate with respect to a storage apparatus, a Peltier device, and a heat sink. It is a control circuit diagram which controls the Peltier device of a storage apparatus, and a cooling ventilation fan. It is a flowchart of the cooling control which the control apparatus in a control circuit performs. It is a side view which shows the Example which mounted a part of control apparatus in the storage canister. It is a perspective view which shows the expansion state of the storage apparatus to an apparatus mounting housing | casing.

The storage device cooling device according to the present invention has a plurality of storage devices mounted in a vertical orientation in which a plurality of storage devices in a flat, rectangular parallelepiped storage case are placed side by side in a cooling air flow direction in the device mounting case. In the storage device cooling device of the storage device in which the cooling air is caused to flow along the storage housing of the device by the cooling air fan,
High thermal conductivity from the side area of the storage enclosure, which is a part close to the heat source of each storage apparatus, to the upper end area of the storage enclosure, which is the upper surface of the storage apparatus in the mounting form on the apparatus mounting enclosure Place the heat transfer plate in the storage enclosure of each storage device,
Install a heat sink via a Peltier element in the upper end surface area of the storage housing of each heat transfer plate,
It is configured to control the current flowing through the Peltier element installed in each storage device according to the temperature of each storage device,
The storage devices are placed side by side in a cooling air flow direction in the device mounting housing and a direction crossing the cooling air flow direction, and the cooling blower fan is arranged in a row of storage devices placed side by side (front-rear direction). ) Is installed in the equipment mounting case every time, and each cooling blower fan controls the operation according to the temperature of the storage equipment in each row,
The cooling blower fans in the row where the storage devices exceeding the set temperature exist also by the current control of the Peltier element are configured to increase the speed.

  FIG. 1 is a perspective view showing a state in which a side plate of a large storage apparatus in which a large number of storage devices are mounted in a plurality of stages in a rack is removed and a device mounting housing is pulled out rearward.

  The rack 1 has a configuration in which a side plate (not shown) is attached to a skeleton in which a column 1c is interposed between a bottom plate 1a and a top plate 1b. The rack 1 includes a housing mounting guide (not shown) for mounting the device mounting housing 2 from the rear side so that the device mounting housing 2 can be inserted and removed in multiple stages in the vertical direction.

  As shown in FIG. 2, a large number of storage canisters 3 containing storage devices (for example, HDDs) are placed side by side in the front-rear direction and the lateral direction in the device mounting housings 2 at the respective stages. The cooling fan 4 is placed side by side at the foremost position. Although illustration explanation is omitted, when the cooling fan 4 is placed on the device mounting housing 2, the fan control terminal is fitted to a control terminal (not shown) provided on the device mounting housing 2. It is electrically connected to a control device (described later).

  When the cooling blower fan 4 is operated in such a state that the storage canister 3 and the cooling blower fan 4 are placed side by side on the equipment mounting housing 2, the storage canisters 3 arranged in the horizontal direction and each storage canister are placed. As the cooling air 5 flows from the rear to the front along the upper surface of the storage 3, the storage devices accommodated in the storage canisters 3 are air-cooled.

  In order to efficiently cool the storage device accommodated in each storage canister 3, the configuration of the storage device accommodated in each storage canister 3 in this embodiment will be described with reference to FIGS.

  In this embodiment, an HDD is used as the storage device 6. The storage device 6 is a rectangular parallelepiped with a flat storage casing 6a. The storage apparatus 6 has a built-in HDD, and includes a storage control terminal 6b at the lower end of the storage casing 6a. The storage device 6 is housed in the storage canister 3 and placed side by side in a vertical posture on the device mounting housing 2 in the front-rear direction (cooling air flow direction) and the horizontal direction (direction crossing the cooling air flow direction). . 3a is a storage canister handle. When the storage device 6 is accommodated in the storage canister 3 and placed on the device mounting housing 2, the storage control terminal 6 b is fitted into a control terminal (not shown) provided on the device mounting housing 2. Electrically connected to a control device (described later).

Each storage device 6, storage housing comprising a top surface of the storage device 6 in the mounted configuration of the storage housing 6a side region 6a ₁ of a portion close to the HDD drive motor (heat source) to置筐body 2 mounting device 6a over the upper end face region 6a ₂ of disposing the high heat transfer plate 7 having thermal conductivity along a storage housing 6a of the storage device 6. Heat transfer plate 7, the storage side portion 7a along the side regions 6a ₁ of the housing 6a is a heat receiving region of the storage device 6, the upper end face portion 7b along the upper surface region 6a ₂ of the storage housing 6a heat dissipation Act as a region.
A heat radiating plate 9 is installed on the upper end surface portion 7 b which is a heat radiating region of the heat transfer plate 7 via a Peltier element 8. The heat dissipating plate 9 has a structure in which heat dissipating fins 9a extending in the front-rear direction are provided on the surface of the heat dissipating plate 9 in order to increase heat dissipating efficiency.

  A temperature sensor 10 is attached to the side surface portion 7a which is a heat receiving area in the heat transfer plate 7, and the temperature of the side surface portion 7a is detected and a temperature detection signal is output.

Power supply to the Peltier element 8 is connected to the Peltier power supply terminal 12 provided with the Peltier power supply line 11 disposed along the lateral end face 6a ₃ of the storage housing 6a to the lower end of the storage housing 6a, the storage of the storage device 6 canister 3, the Peltier power supply terminal 6 c is fitted into a control terminal (not shown) provided in the device mounting housing 2 and is electrically connected to a control device (described later). Connected.

The temperature sensor 10 is connected to the temperature signal terminal 14 provided on the lower end of the storage housing 6a by the temperature detection signal line 13 arranged along the other lateral end face 6a ₄ of the storage housing 6a, the storage device 6 When housed in the storage canister 3 and placed on the device placement housing 2, the temperature signal terminal 6d is fitted into a control terminal (not shown) provided on the device placement housing 2 to control the device (described later). And electrically connected.

  As shown in FIG. 6, the control device 15 is mounted together with a power supply device, a computer device (not shown) and the like on each device mounting case 2 on which the storage canister 3 is mounted or on the canister mounted on the lowermost stage of the rack 1. Placed.

  The control device 15 is constituted by a microcomputer or a peripheral device, inputs data read / write control processing of the storage device 6 and a temperature detection signal from the temperature sensor 10, and refers to the temperature detection signal to refer to the cooling fan 4 and Peltier. The driving current of the element 8 is controlled.

  The storage device configured as described above is configured by mounting the storage canister 3 in which the storage device 6 is accommodated in the device mounting housing 2 and the cooling blower fan 4 and mounting them in the rack 1 in multiple stages.

  The controller 15 controls the data reading / writing of the storage device 6, and refers to the temperature detection signal input from the temperature sensor 10 to control the driving current of the cooling fan 4 and the Peltier element 8.

  By operating the cooling fan 4, the cooling air 5 flows from the rear side to the front side through the storage device, so that the storage case 6 a, the heat transfer plate 7, and the heat dissipation plate 9 of each storage device 6 The storage device 6 is air-cooled by taking heat away. At this time, since the upstream region of the cooling air 5 flowing through the storage device is a relatively low temperature air flowing from the room, the storage device 6 located in this upstream region has a relatively low temperature cooling air 5. Acts and cools well. However, since the storage device 6 located in the downstream region is cooled by the cooling air 5 that has been cooled to a relatively high temperature by cooling the storage device 6 located in the upstream region, the storage device 6 located in the downstream region. The cooling effect on the temperature tends to decrease and the temperature of these storage devices 6 tends to increase.

  Therefore, the control device 15 in the storage device in this embodiment inputs and refers to the temperature detection signal output from each temperature sensor 10, and this storage device is used for the storage device 6 whose temperature is higher than the set value. The drive current control is performed on the Peltier element 8 installed on the heat transfer plate 7 of the storage housing 6 a 6 so as to absorb the heat of the heat transfer plate 7 and release it to the heat dissipation plate 9. When the drive control for the Peltier element 8 is performed in this way, the temperature of the heat radiating plate 9 rises, so that the heat dissipating action is enhanced even for the cooling air 5 having a relatively high temperature. The temperature increase of the storage device 6 that is located in the downstream region in the flow direction and increases in temperature can be suppressed.

  If the temperature rise of the storage device 6 cannot be suppressed below the set value even by such driving current control of the Peltier element 8, the control device 15 cannot store the temperature rise below the set value. Control is performed to increase the blowing capacity (increase the rotational speed) of the cooling blower fan 4 placed at the forefront position of the row where the device 6 is placed. When the temperature increase of the storage device 6 cannot be suppressed below the set value even by this air flow capacity increase control, the cooling air fan 4 located in the row adjacent to the row where the storage device 6 is placed is also used. The same ventilation capacity increase control is performed.

An embodiment of control processing executed by the control device 15 for such cooling control will be described with reference to FIG.

Step S701
When the storage apparatus is operated, the cooling blower fans 4 in each row of the device mounting housings 2 in each stage are started to operate at a predetermined rotation speed.

Step S702
A temperature detection signal from the temperature sensor 10 of each storage device 6 is acquired.

Step S703
Each acquired temperature detection signal is compared with a set value, and the presence or absence of the storage device 6 having a temperature exceeding the set value is monitored.

Step S704
By supplying a drive current to the Peltier element 8 of the storage device 6 whose temperature exceeds the set value and causing the Peltier element 8 to function, heat is taken from the heat transfer plate 7 and released to the heat radiating plate 9. Thereby, since the heat sink 9 becomes higher temperature, it becomes possible to efficiently radiate heat to the relatively high temperature cooling air 5.

Step S705
The control processing is branched by monitoring the temperature of the storage device 6 including the Peltier element 8 to which the drive current is supplied.

Step S706
When the temperature of the storage device 6 including the Peltier element 8 to which the drive current is supplied becomes equal to or lower than a set value, a control process for reducing the Peltier drive current is performed.

Step S707
If the temperature of the storage device 6 does not drop below the set value even when a drive current is supplied to the Peltier element 8, a cooling fan for the placement row (including the adjacent row if necessary) of this storage device 6 4 is increased to increase the air blowing capacity of the cooling fan 4 and the air cooling capacity for the storage device 6 is increased.

Step S708
The control processing is branched by monitoring the temperature of the storage device 6 exceeding the set temperature in a row in which the cooling fan 4 is accelerated.

Step S709
When the temperature of the storage device 6 including the accelerated cooling fan 4 becomes equal to or lower than a set value, a control process for decelerating the cooling fan 4 is performed.

Step S710
The temperature of the storage device 6 exceeding the set temperature is monitored in a row in which the cooling blower fan 4 is accelerated. If the temperature of the storage device 6 is equal to or lower than the upper limit value, the cooling control is continued.

Step S711
When the temperature of the storage device 6 exceeds the upper limit value, abnormal processing such as alarm processing is performed.

  According to such a storage device, in the plurality of storage devices 6 arranged side by side in the flow direction of the cooling air 5 generated by the cooling blower fan 4, it is located in the downstream region where the temperature of the flowing cooling air 5 rises. Also in the storage device 6, the heat transfer plate 7 is cooled by the Peltier element 8 and the temperature of the heat radiating plate 9 is increased, so that the storage device 6 can be efficiently air-cooled without increasing the blowing capacity of the cooling blower fan 4. The increase in generated noise can be suppressed.

  However, when there is a storage device 6 in which the temperature rise cannot be suppressed to a set value or less even if the Peltier element 8 functions in this way, the cooling fan 4 in the row in which the storage device 6 is placed is accelerated. Since the cooling capacity of the storage device 6 is increased by increasing the blowing capacity, the increase in power consumption and generated noise of the cooling fan 4 can be reduced.

  A part of the control device 15 that performs such control processing can be configured to be installed in each storage canister 3.

  FIG. 8 is a side view of the storage canister 3 housing the storage device 6 in this embodiment.

  The auxiliary control device 15a is a functional means for executing a part of the cooling control function of the control device 15 in the above-described embodiment on the side of each storage device 6, and is configured mainly by a microcomputer and installed in each storage canister 3. To do. In addition, the overlapping description is abbreviate | omitted about the structural means which is common in Example 1. FIG.

  The auxiliary control device 15a receives a detected temperature signal from the temperature sensor 10 via the temperature detection signal line 13, compares it with the set temperature set in the storage device 6, and when the detected temperature exceeds the set temperature. Transmits a Peltier drive request signal to the control device 15 via the control request signal line 16 and the control request signal terminal 17 in order for the control device 15 to function the Peltier element 8.

  The control device 15 that has received this Peltier drive request signal passes through the Peltier feed line 11 and the Peltier feed terminal 12 to the Peltier element 8 of the storage device 6 accommodated in the storage canister 3 that has transmitted this Peltier drive request signal. Supply Peltier drive current. The auxiliary control device 15a transmits a Peltier drive current reduction request signal for reducing the Peltier drive current to the control device 15 when the detected temperature falls below the set value due to the supply of the Peltier drive current.

  The control device 15 that has received the Peltier drive current reduction request signal executes Peltier drive current reduction control.

  If the temperature of the storage device 6 does not drop below the set value even when a drive current is supplied to the Peltier element 8, a cooling fan for the placement row (including the adjacent row if necessary) of this storage device 6 4 is increased through the control request signal line 16 and the control request signal terminal 17 to increase the air blowing capacity of the cooling fan 4 and to increase the air cooling capacity for the storage device 6 via the control request signal line 16 and the control request signal terminal 17. Transmit to device 15.

  The auxiliary control device 15a monitors the temperature detection signal, and transmits a deceleration control request signal for decelerating the cooling air fan 4 to the control device 15 when the temperature of the storage device 6 becomes equal to or lower than the set value. Slow 4

  Thereafter, if the temperature of the storage device 6 is equal to or lower than the upper limit value, the cooling control is continued. However, when the temperature of the storage device 6 exceeds the upper limit value, the auxiliary control device 15a makes an abnormality requesting an abnormal process such as an alarm process. A processing request signal is transmitted to the control device 15.

  The control device 15 that has received this abnormality processing request signal performs abnormality processing such as alarm processing.

  Even if it does in this way, the effect similar to Example 1 can be acquired.

FIG. 9 illustrates a configuration in which the number of storage devices 6 placed in the device placement housing 3 is increased in such a storage apparatus. In this configuration, a device non-mounting area is prepared in the device mounting case 3, and the additional storage device 6 ′ is mounted in the device non-mounting area. The storage device 6 ′ to be added is also configured to have the same air cooling means as the storage device 6 described above.
According to the storage device cooling apparatus of the present invention, even if the number of storage devices 6 mounted on the device mounting housing 3 increases or decreases, air cooling adapted to the increase or decrease can be realized.

DESCRIPTION OF SYMBOLS 1 ... Rack 1a ... Bottom plate 1b ... Top plate 1c ... Column 2 ... Equipment mounting housing 3 ... Storage canister 3a ... Storage canister handle 4 ... Cooling air fan 5 ... Cooling air 6, 6 '... Storage equipment 6a ... Storage housing 6a ₁ ... side area 6a ₂ ... upper end area 6a ₃ , 6a ₄ ... lateral end face 6b ... storage control terminal 6c ... Peltier power supply terminal 6d ... temperature signal terminal 7 ... heat transfer plate 7a ... side part 7b ... upper end face part 8 ... Peltier Element 9 ... Radiating plate 9a ... Radiating fin 10 ... Temperature sensor 11 ... Peltier feeding line 12 ... Peltier feeding terminal 13 ... Temperature detection signal line 14 ... Temperature signal terminal 15 ... Control device 15a ... Auxiliary control device 16 ... Control request signal line 17 ... Control request signal terminal.

Claims (4)

A plurality of storage devices in a flat, rectangular parallelepiped storage case are placed side by side in a vertical orientation on the device mounting case in the cooling air flow direction, and cooled along the storage case of the plurality of storage devices placed In a storage device cooling device for a storage device in which cooling air is passed by a blower fan,
High thermal conductivity from the side area of the storage enclosure, which is a part close to the heat source of each storage apparatus, to the upper end area of the storage enclosure, which is the upper surface of the storage apparatus in the mounting form on the apparatus mounting enclosure Place the heat transfer plate in the storage enclosure of each storage device,
Install a heat sink via a Peltier element in the upper end surface area of the storage housing of each heat transfer plate,
A storage device cooling apparatus configured to control a current flowing in a Peltier element installed in each storage device in accordance with the temperature of each storage device.   2. The storage device according to claim 1, wherein the storage device is placed side by side in a cooling air flow direction and a direction crossing the cooling air flow direction in the device mounting housing, and the cooling blower fan is placed side by side. A storage device cooling apparatus that is installed in a device mounting housing for each row (front-rear direction), and that each cooling blower fan controls operation according to the temperature of the storage device in each row.   3. The storage device cooling apparatus according to claim 2, wherein the cooling air blower fan in a row in which a storage device exceeding a set temperature exists also by current control of the Peltier element is accelerated. In the storage device cooling device for allowing cooling air to flow by a cooling blower fan along the storage case of the storage device of a flat and rectangular parallelepiped storage case,
A heat transfer plate with high thermal conductivity is arranged from the side surface region to the end surface region of the storage housing, which is a part close to the heat source of the storage device,
Installing a heat sink via a Peltier element in the housing end face region of the heat transfer plate,
A storage device cooling apparatus configured to control a current flowing through the Peltier element in accordance with a temperature of the storage device.

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