JP2012253191A - Cooling system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To increase the number of computers mounted on a server rack and the like and efficiently cool the computers in a cooling system.SOLUTION: A cooling system includes: an apparatus installation area 12 on which an electronic apparatus 23 is installed; an air conditioner 21 performing air conditioning in the apparatus installation area 12; a cooling area 13 in which a tip 25x of a heat transfer member 25 thermally connecting with a heating component 57 in the electronic apparatus 23 is disposed; a separation wall 11 separating the apparatus installation area 12 from the cooling area 13; a drain hose 63 having one end connecting with the tip 25x and the other end connecting with a heat exchanger 60 exchanging heat of air flow A flowing out from the cooling area 13 with outer air B. A nonwoven cloth 65 or a porous material 65 is disposed at the tip 25x.

Description

  The present invention relates to a cooling system.

  With the development of information technology in recent years, a large amount of data is being handled in the data center. In order to cope with such an increase in the amount of data, it is preferable to install as many computers as possible in the server rack installed in the data center.

  However, the number of computers that can be mounted on one server rack is limited depending on the external shape of each computer. Further, even when a large number of computers are mounted on the server rack, it is preferable that each computer can be efficiently cooled.

Japanese Utility Model Publication No. 2010-98063 Japanese Patent Laid-Open No. 02-007456 Japanese Patent Laid-Open No. 04-369255

  An object of the cooling system is to increase the number of computers that can be mounted on a server rack or the like and to efficiently cool the computers.

  According to one aspect of the following disclosure, a device installation area in which an electronic device is installed, an air conditioner that performs air conditioning in the device installation area, and a heat transfer member that is thermally connected to a heat generating component in the electronic device A cooling area in which the front end portion is disposed, a separation wall that separates the device installation area and the cooling area, one end connected to the front end portion, and the other end from the cooling area to the outside air and heat There is provided a cooling system having a drain hose connected to a heat exchanger to be exchanged, wherein a nonwoven fabric or a porous material is disposed at the tip.

  According to another aspect of the disclosure, an electronic device, a heat transfer member thermally connected to a heat generating component in the electronic device, and water circulation for cooling the tip of the heat transfer member with water There is provided a cooling system that includes a system, a shower head that is provided in the middle of the circulation system, and jets the water, and a blower that blows air to the water jetted by the shower head.

  According to the following disclosure, since the tip of the heat transfer member can be cooled by the heat of vaporization of water vaporized from the nonwoven fabric or the porous material, the heat generating component thermally connected to the heat transfer member can be selectively cooled. Can do.

  Further, since the heat of vaporization of water is used in this way, it is not necessary to provide fins on the heat transfer member to increase the efficiency of heat exchange with the airflow in the cooling area. It is possible to prevent the mounting from being hindered by the fins.

  Further, since the tip end portion of the heat transfer member can be efficiently cooled by the water circulation system that cools the tip end portion of the heat transfer member with water, it is not necessary to provide fins on the heat transfer member in the same manner as described above. Electronic devices can be mounted at high density.

FIG. 1 is a cross-sectional view of a server rack according to a preliminary matter. FIG. 2 is a schematic diagram of the cooling system according to the first embodiment. FIG. 3 is a plan view of the heat exchanger according to the first embodiment viewed from the upstream side of the outside air. FIG. 4 is an enlarged cross-sectional view of the server rack and its surroundings according to the first embodiment. FIG. 5 is a cross-sectional view for explaining that computers can be mounted in a server rack with high density in the first embodiment. FIG. 6 is an enlarged cross-sectional view of the server rack and its surroundings according to the second embodiment. FIG. 7 is an enlarged cross-sectional view of a computer and its surroundings according to a first modification of the second embodiment. FIG. 8 is a top view of a computer according to a second modification of the second embodiment. FIG. 9 is a diagram illustrating operating conditions of the cooling system according to the third embodiment. FIG. 10 is a schematic diagram showing the air flow in the pattern 1 of the third embodiment. FIG. 11 is a schematic diagram illustrating the air flow in the pattern 2 of the third embodiment. FIG. 12 is a schematic diagram illustrating the air flow in the pattern 3 of the third embodiment. FIG. 13 is a schematic diagram illustrating the air flow in the pattern 4 of the third embodiment. FIG. 14 is a schematic diagram illustrating the air flow in the pattern 5 of the third embodiment. FIG. 15 is a schematic diagram illustrating the air flow in the pattern 6 of the third embodiment. FIG. 16 is a side sectional view of a server rack and its surroundings according to the fourth embodiment. FIG. 17 is a front sectional view of a server rack and its surroundings according to the fourth embodiment. FIG. 18 is a side cross-sectional view of the server rack and its surroundings according to the fifth embodiment. FIG. 19 is a front sectional view of a server rack and its surroundings according to the fifth embodiment. FIG. 20 is a side cross-sectional view of the water cooling jacket according to the first example of the fifth embodiment. FIG. 21A is a side sectional view of a water cooling jacket according to a second example of the fifth embodiment, and FIG. 21B is a front sectional view thereof. FIG. 22A is a side sectional view of a water cooling jacket according to a third example of the fifth embodiment, and FIG. 22B is a front sectional view thereof.

  Prior to the description of the present embodiment, preliminary matters serving as the basis of the present embodiment will be described.

  In the data center, an air conditioning facility for cooling individual computers in the server rack is provided. The power consumption of the air conditioning facility is said to be comparable to the power consumption in all the server racks in the data center. Therefore, in order to reduce power consumption in the air conditioning equipment, it is preferable to increase the cooling efficiency of each computer in the server rack.

  Below, an example of the cooling method of a computer is demonstrated.

  FIG. 1 is a cross-sectional view of the server rack 22.

  A plurality of computers 23 are mounted on the server rack 22 side by side in the height direction. The computer 23 is a rack mount server, for example, and its height U is standardized to about 44 mm by EIA (American Electronic Industry Association).

  Each computer 23 accommodates a system board 55, and a heat generating component 57 such as a CPU is mounted on the system board 55.

  In order to cool the heat generating component 57, a rod-shaped heat pipe is thermally connected to the heat generating component 57 as the heat transfer member 25. The heat pipe is formed by enclosing water in a decompressed pipe, and the water repeatedly evaporates and condenses in the pipe, whereby the heat at one end of the pipe can be moved to the other end.

  A plurality of fins 25 a are provided at the tip of the heat transfer member 25. Each fin 25a is exposed to an airflow E such as outside air, whereby heat exchange between the heat transfer member 25 and the airflow E is promoted.

  According to this method, the heat generating component 57 can be selectively cooled by the heat transfer member 25, and the cooling efficiency of the computer 23 can be increased.

  However, if the fins 25a are provided as described above, the cooling efficiency of the heat generating component 57 can be increased, but the fins 25a of the computers 23 adjacent to each other in the upper and lower sides mechanically interfere with each other. I can't.

  For example, when the length L of the heat transfer member 25 is 400 mm, the diameter D is 16 mm, and the height H of the fin 25a is 100 mm, the cooling capacity of one heat transfer member 25 is about 200 W, which means that two CPUs Corresponds to the ability to cool. However, since the upper and lower fins 25a with each other do not interfere, must be the total height of the two computers 23 3U (132 mm) or more.

  In this case, even in the case of a server rack 22 having a height of 42U and capable of accommodating 42 computers 23, only 14 (= 42U / 3U) computers 23 can be accommodated, and the computers 23 can be accommodated in the server rack 22 with high density. You will not be able to.

  Hereinafter, embodiments will be described.

(First embodiment)
FIG. 2 is a schematic diagram of the cooling system according to the first embodiment. In FIG. 2, the same elements as those described in FIG. 1 are denoted by the same reference numerals as those in FIG. 1, and description thereof is omitted below.

  The computer room is separated by a separation wall 11 into a rack installation area (an example of an equipment installation area) 12 in which a server rack 22 that houses a computer 23 is arranged, and a cooling area 13 through which low-temperature air passes.

  In FIG. 2, only one server rack 22 is illustrated, but a number of racks 22 are installed in the rack installation area 12. Each server rack 22 stores a plurality of computers 23. Each computer 23 is provided with a fan (not shown) that introduces air from the front side (left side in FIG. 2) of the rack 22 and discharges air from the rear side (right side in FIG. 1). The computer 23 is an example of an electronic device.

  In the present embodiment, as illustrated in FIG. 2, the heat transfer member 25 protrudes from each computer 23 in the horizontal direction. An opening covered with a rubber film 11 a is formed in the separation wall 11, and the tip of the heat transfer member 25 penetrates the film 11 a and is led out into the cooling area 13.

  As will be described later, a heat pipe can be used as the heat transfer member 25.

  Further, a water absorbing material 65 described later is provided at the tip of the heat transfer member 25 in place of the fins described in the preliminary matter.

  A cold air flow path 14 is provided under the floor of the rack installation area 12. In addition, a grill (ventilation opening) 12a is installed on the floor of the rack installation area 12, and low temperature air is supplied from the cold air flow path 14 to the front side of the rack 22 through the grill 12a.

  On the other hand, a hot air flow path 15 is provided on the back of the ceiling of the rack installation area 12, and an opening 12 b that communicates between the rack installation area 12 and the hot air flow path 15 is provided on the ceiling on the back side of the rack 22. It has been.

  In the present embodiment, an area (cold aisle) where cold air is supplied via the grill 12a and an area (hot aisle) where hot air is discharged from the rack 22 are separated by partitions 24a and 24b. ing. However, these partitions 24a and 24b are not essential, and may be installed as necessary.

  The cold air flow path 14 is connected to an air outlet of the air conditioner 21 and is connected to an air supply duct (first air supply duct) 32 via a damper 44 and a duct 31. The air supply duct 32 communicates with the outdoors, and a fan 51 is disposed in the air supply duct 32. The outside air B is introduced into the air supply duct 32 by the rotation of the fan 51. The first air intake port of the air conditioner 21 is also connected to the air supply duct 32 via the damper 43 and the duct 35. A fan 52 that rotates in conjunction with the air conditioner 21 is disposed under the air outlet of the air conditioner 21.

  The hot air flow path 15 is connected to the second air intake port of the air conditioner 21 via the damper 42 and the duct 33, and is connected to the exhaust duct (first exhaust duct) 34 via the damper 41. Yes. The exhaust duct 34 communicates with the outdoors.

  A cold air passage 16 is provided under the floor of the cooling area 13, and a hot air passage 17 is provided behind the ceiling. A grill (ventilation opening) 13a is disposed on the floor of the cooling area 13, and cold air is supplied from the cold air flow path 16 to the cooling area 13 through the grill 13a. 65 is exposed.

  In addition, an opening 13 b that communicates between the cooling area 13 and the hot air flow path 17 is provided on the ceiling of the cooling area 13.

  A damper 45 is disposed between the cold air passage 14 and the cold air passage 16. When the damper 45 is open, the cold air passage 14 and the cold air passage 16 are in communication, and when the damper 45 is closed, the cold air passage 14 and the cold air passage 16 are disconnected. Further, a damper 47 is disposed between the hot air channel 15 and the hot air channel 17. When the damper 47 is open, the hot air passage 15 and the hot air passage 17 are in communication, and when the damper 47 is closed, the hot air passage 15 and the hot air passage 17 are disconnected.

  The cold air flow path 16 is connected to an air supply duct (second air supply duct) 36 via a damper 46. The air supply duct 36 communicates with the outside, and a fan 53 is disposed inside the damper 46. The rotation of the fan 53 introduces the outside air B into the cooling area 12 through the air supply duct 36, the damper 46, and the grill 12a. The hot air flow path 17 is connected to an exhaust duct (second exhaust duct) 37 via a damper 48. This exhaust duct 37 communicates with the outdoors.

  Further, a heat exchanger 60 is provided in the hot air flow path 17 in front of the damper 48. Airflow A having flowed from the cooling area 13 in the warm air passage 17 is cooled is the external air B and a heat exchanger in the heat exchanger 60, and is discharged outdoors.

  Control unit 28 is connected to a sensor unit 29b for detecting the temperature and humidity of a computer room and the sensor portion 29a that detects the temperature and humidity of the outside air B. Control unit 28, these sensor portion 29a, controls the opening and closing state of the fan 51 to 53 on / off and the air conditioner 21 of the damper 41 to 48 in accordance with the output of 29b.

  In the present embodiment, the air conditioner 21 has a function of adjusting the temperature and humidity of air supplied from the air outlet. However, an air conditioner that performs only temperature adjustment of air may be used, and a humidifier and a dehumidifier may be provided separately from the air conditioner. In addition, it is preferable that filters be arranged in the air supply ducts 32 and 36 and the exhaust ducts 34 and 37 that communicate with the outdoors in order to prevent dust from entering the room.

  FIG. 3 is a plan view of the heat exchanger 60 viewed from the upstream side of the outside air B. FIG.

  As shown in FIG. 3, the heat exchanger 60 has a plurality of pipes 60b through which the outside air B passes. Furthermore, each pipe 60b is provided with a metallic fin 60a that promotes heat exchange between the airflow A and the outside air B.

  FIG. 4 is an enlarged sectional view of the server rack 22 and its surroundings.

  As shown in FIG. 4, a water absorbing material 65 that holds water is provided at the distal end portion 25 x of the heat transfer member 25. As the water absorbing material 65, a nonwoven fabric such as felt can be used. A porous material such as pumice or activated carbon may be used as the water absorbing material 65.

  Further, a waterproof pan 66 is provided below the heat exchanger 60. The water contained in the water-absorbing material 65 is vaporized and taken into the air stream A, then cooled and liquefied by the heat exchanger 60 and collected by the waterproof pan 66.

  Then, both ends of the drain hose 63 are connected to the waterproof pan 66 and the absorbent material 65, respectively. The water collected by the waterproof pan 66 is returned to the water absorbing material 65 through the drain hose 63.

  Thus, in this embodiment, water circulates independently between the water absorbing material 65 and the heat exchanger 60. Then, the heat transfer member 25 is cooled by the vaporization heat of water contained in the water absorbent material 65, thereby to selectively cool the heat generating components 57 such as a CPU.

  The amount of water contained in the water absorbing material 65 is set according to the cooling capacity required for the heat transfer member 25. Since the latent heat of vaporization of water is about 2500 J / g, when a cooling capacity of 200 W is required as in the preliminary matter, about 0.08 (= 200/2500) g of water is vaporized per second. What is necessary is just to let 24 g of water be contained in the water absorbing material 65 in order to continue vaporization for 5 minutes.

  And the water absorption material 65 which concerns on this embodiment does not require the space of a height direction like the fin 25a (refer FIG. 1). Therefore, as shown in FIG. 5, without absorbent material 65 between the computer 23 that vertically adjacent interference, it is possible to mount the machine 23 at high density server rack 22.

  For example, when the height of each computer 23 is 2U (88 mm), 21 computers 23 can be mounted on the server rack 22 having a height of 42U, and the number of mounted computers is 1.5 times that of the preliminary items. can do.

  In addition, when it is difficult to collect all the water vaporized from the water absorbing material 65 with the heat exchanger 60, or when the duration of vaporization of water in the water absorbing material 65 is 5 minutes or more, it is contained in the water absorbing material 65. It is thought that the amount of water to be gradually reduced.

  In this case, as shown in FIG. 4, it is preferable to provide a water supply unit 62 in the middle of the drain hose 63 and a determination unit 69 such as a personal computer.

  The determination unit 69 determines whether or not the water supply material 65 should be replenished with water. If it is determined that the water supply material 65 should be replenished, the determination unit 69 controls the valve 62a provided in the water supply unit 62 to be in an open state, thereby It has a function to replenish water. The determination is preferably performed using a moisture meter 61 that measures the moisture value of the water absorbing material 65 or a hygrometer 67 that measures the humidity of the airflow A downstream from the heat transfer member 25.

When utilizing moisture meter 61 monitors the determination unit 69 has been measured in the moisture meter 61 water content W _m, when the said moisture value W _m becomes equal to or less than the predetermined moisture value W _0, the water absorbent material It is determined that 65 should be replenished with water.

When the hygrometer 67 is used, the determination unit 69 monitors the humidity H _m measured by the hygrometer 67, and when the humidity H _m falls below the predetermined humidity H ₀ , Judge that you should replenish.

  Thus, by supplying water to the water absorption material 65 from the water supply part 62, it can prevent that the water content of the water supply material 65 falls, and can maintain the cooling efficiency of the heat-transfer member 25 in a high state.

(Second Embodiment)
FIG. 6 is an enlarged cross-sectional view of the server rack 22 and its surroundings according to the present embodiment. In FIG. 6, the same elements as those described in the first embodiment are denoted by the same reference numerals as those in the first embodiment, and description thereof is omitted below.

  As shown in FIG. 6, in the present embodiment, a plurality of metal fins 25 a are provided at the tip of the heat transfer member 25. As a material for the fin 25a, copper or aluminum having a higher thermal conductivity coefficient than other metals can be used.

  The height h of each fin 25a is set to be lower than the height H of the calculator 23.

  Furthermore, the water absorbing material 65 described in the first embodiment is provided not only on the tip portion of the heat transfer member 25 but also on the surface of each fin 25a. The rest is the same as in the first embodiment.

  In the present embodiment, since the water absorbing material 65 is also provided on the surface of the fin 25a in this way, the amount of water that can be held by the water absorbing material 65 can be increased more than in the first embodiment, and the water is stable for a long time. The heat transfer member 25 can be cooled.

For example, the case without the fins 25a, when the length L ₁ of the distal end portion of the heat transfer member 25 is 50 mm, the diameter D of the heat transfer member 25 is 16 mm, the thickness T of the water absorbing member 65 is 5 mm, the water absorbent material 65 The volume of is about 12.6 cm ³ (= 50 mm × 16 mm × 3.14 × 5 mm).

On the other hand, when the fins 25a are provided as in the present embodiment, the volume of the water absorbing material 65 can be increased to about 69.0 cm ³ when the planar shape of each fin 25a is a square having a side of 50 mm. In calculating the volume of the water absorbing material 65, it is assumed that the space between the six fins 25a is 10 mm and the water absorbing material 65 is provided only on one surface of each fin 25a. In this case, by subtracting the volume (0.5 cm × (0.8 cm) ² × 3.14) where the heat transfer member 25 is inserted in the water absorbing material 65, the volume of the water absorbing material 65 is 0.5 cm × ( 5 cm × 5 cm− (0.8 cm) ² × 3.14) × 6, which is about 69.0 cm ³ as described above.

  Next, a modification of this embodiment will be described.

(First modification)
FIG. 7 is an enlarged cross-sectional view of the computer 23 and its surroundings according to this modification.

As shown in FIG. 7, in this example, the interval P ₁ between the fins 25 a of the computer 23 on the upstream side of the airflow A is narrower than the interval P ₂ between the fins 25 a of the computer 23 on the downstream side of the airflow A. To do.

  If it does in this way, since the flow of the airflow A becomes difficult to be inhibited by the fins on the upstream side, the fins 25a on the downstream side are well exposed to the airflow A, and the cooling efficiency of the heat transfer member 25 on the downstream side decreases. Can be suppressed.

(Second modification)
FIG. 8 is a diagram of each computer 23 according to the present modification viewed from above.

  As shown in FIG. 8, in this example, the fins 25a in one computer 23 are not overlapped with the fins 25a in the other computer 23 when each computer 23 is viewed from above.

  If it does in this way, since it can suppress that the flow of the airflow A is inhibited by the fin 25a in one computer 23, it becomes easy to cool the heat-transfer member 25 of the other computer 23 with the airflow A, and each heat-transfer member 25. The cooling efficiency can be increased.

(Third embodiment)
In the present embodiment, the operation of the cooling system described in the first and second embodiments will be described with reference to FIGS.

  Here, it is assumed that the heat generating component 57 in the computer 23 has a temperature of 35 ° C. or higher. In addition, the circulating air volume is set so that the temperature of the air discharged from the computer 23 is about 30 ° C. when the temperature of the air introduced into the rack installation area 12 is about 20 ° C.

  The introduction of the outside air B into the rack installation area 12 is determined by the temperature and humidity of the outside air B. When the outside air B is introduced into the rack installation area 12, the temperature of the outside air B is allowed up to 30 ° C. In addition, the absolute humidity (0.0099kg / kg.DA) when the temperature is 20 ° C and the relative humidity is 50% is set as the standard humidity, and when the outside air B is introduced into the rack installation area 12, the humidity is adjusted to the standard humidity. The humidity range in which the electric power required for dehumidification is less than or equal to a predetermined value was defined as the reference range.

  The control unit 28 controls the air conditioner 21, the dampers 41 to 48, and the fans 51 to 53 according to the temperature and humidity of the outside air B, and sets the operation state in any one of the following patterns 1 to 6. FIG. 9 is a diagram illustrating operating conditions in patterns 1 to 6.

(Pattern 1)
Pattern 1 is a case where the temperature of the outside air B is less than 20 ° C. and the humidity is out of the reference range. In this case, the control unit 28 opens the dampers 42, 46, 48, closes the dampers 41, 43, 44, 45, 47, turns on the fans 52, 53, and turns off the fan 51. FIG. 10 is a schematic diagram showing the air flow in the pattern 1.

  When the humidity of the outside air B is out of the reference range, introducing the outside air B into the rack installation area 12 increases the power required for humidification or dehumidification, and can sufficiently obtain the effect of reducing the power consumption of the air conditioning equipment. Disappear. Therefore, in the pattern 1, the outside air B is not introduced into the rack installation area 12, and the air in the rack installation area 12 is cooled by the air conditioner 21. On the other hand, the temperature of the outside air B is sufficiently low, the cooling area 13 and introducing outside air B, cooling the heat-generating components 57 of the computer 23 via the heat transfer member 25.

(Pattern 2)
Pattern 2 is a case where the temperature of the outside air B is less than 20 ° C. and the humidity is within the reference range. In this case, the control unit 28 opens the dampers 41, 42, 43, 46, and 48, closes the dampers 44, 45, and 47, and turns on the fans 51, 52, and 53. FIG. 11 is a schematic diagram showing the air flow in the pattern 2.

  In pattern 2, since the temperature of the outside air B is low and the humidity is within the reference range, the outside air B is introduced into the rack installation area 12. However, the introduction of external air B to the rack installation area 12 as humidity decreases as the temperature rises, it is conceivable that deviates from the reference range. Therefore, in pattern 2, outside air B is introduced through the air conditioner 21, a part of the air passing through the hot air flow path 15 is taken into the air conditioner 21, and the temperature and humidity are adjusted by the air conditioner 21 before the rack installation area. 12 is introduced. An amount of air corresponding to the amount of air introduced into the room is exhausted from the exhaust duct 34.

  On the other hand, outside air B is introduced into the cooling area 13 as it is, and the heat generating component 57 in the computer 23 is cooled via the heat transfer member 25.

(Pattern 3)
Pattern 3 is a case where the temperature of the outside air B is 20 ° C. to 30 ° C. and the humidity is out of the reference range. In this case, the control unit 28 opens the dampers 42, 46, 48, closes the dampers 41, 43, 44, 45, 47, turns on the fans 52, 53, and turns off the fan 51. FIG. 12 is a schematic diagram showing the air flow in the pattern 3.

  In pattern 3, since the humidity of the outside air B is out of the reference range, when the outside air B is introduced into the rack installation area 12, the power required for adjusting the humidity increases, and the effect of reducing the power consumption of the air conditioning equipment is sufficiently obtained. I can't do that. Therefore, in the pattern 3, the outside air B is not introduced into the rack installation area 12.

  On the other hand, since the temperature of the outside air B is sufficient to cool the heat generating component 57 in the computer 23, the outside air B is introduced into the cooling area 13 and the heat generating component 57 in the computer 23 is connected via the heat transfer member 25. Cooling.

(Pattern 4)
Pattern 4 is a case where the temperature of the outside air B is 20 ° C. to 30 ° C. and the humidity is within the reference range. In this case, the control unit 28 opens the dampers 41, 44, 46, and 48, closes the dampers 42, 43, 45, and 47, turns on the fans 51 and 53, and turns off the fan 52. FIG. 13 is a schematic diagram showing the air flow in the pattern 4.

  In the pattern 4, the temperature and humidity of the outside air B are within the appropriate ranges. Therefore, the outside air B is introduced into the rack installation area 12 without going through the air conditioner 21, and the corresponding air is discharged from the exhaust duct 34. Further, outside air B is also introduced into the cooling area 13 to cool the heat generating component 57 in the computer 23 via the heat transfer member 25.

(Pattern 5)
Pattern 5 is a case where the temperature of the outside air B is 30 ° C to 35 ° C. In this case, the control unit 28 opens the dampers 42, 46, 48, closes the dampers 41, 43, 44, 45, 47, turns on the fans 52, 53, and turns off the fan 51. FIG. 14 is a schematic diagram showing the air flow in the pattern 5.

  Since the temperature of the pattern 5 outside air B is high, it is impossible to sufficiently obtain the effect of reducing the power consumption of the air conditioning facilities to introduce outside air B to the rack installation area 12. Therefore, in the pattern 5, the outside air B is not introduced into the rack installation area 12. However, since the temperature of the outside air B is lower than the temperature of the heat generating component 57, the outside air B is introduced into the cooling area 13 and the heat generating component 57 in the computer 23 is cooled via the heat transfer member 25.

(Pattern 6)
Pattern 6 is a case where the temperature of the outside air B is 35 ° C. or higher. In this case, the control unit 28 opens the dampers 42, 45, 47, closes the dampers 41, 43, 44, 46, 48, turns on the fan 52, and turns off the fans 51, 53. FIG. 15 is a schematic diagram showing the air flow in the pattern 6.

  In the pattern 6, since the temperature of the outside air B is high, the outside air B is not introduced into either the rack installation area 12 or the cooling area 13. In this case, air whose temperature and humidity are adjusted by the air conditioner 21 is supplied to the rack installation area 12 and the cooling area 13.

  As described above, the cooling system according to the present embodiment, appropriate to introduce the outside air B to the rack installation area 12, and the cooling area 13 in accordance with the temperature and humidity of the outside air B. Thereby, the power required for air conditioning in the computer room can be greatly reduced. As a result of simulation by the present inventor, in the cooling system according to the present embodiment, outside air B can be introduced into the rack installation area 12 for about 80 days in one year, and outside air B is introduced into the cooling area 13 for about 120 days. be able to.

  Further, in the cooling system according to the present embodiment, air whose temperature and humidity are adjusted is supplied into the rack installation area 12, so that malfunction and failure of the computer 23 due to static electricity or condensation are avoided.

  Incidentally, it may cause a failure of the computer 23 such as dust in a computer room and introducing outside air B like windy day invade. For this reason, when there is a possibility that dust or the like may enter the computer room, it is preferable to operate with the pattern 6 regardless of the temperature and humidity of the outside air B. The operation pattern described above is merely an example, temperature and humidity when the control unit 28 controls the damper 41 to 48 and the fan 51 to 53 may be appropriately changed.

(Fourth embodiment)
In the first to third embodiments, the tip of the heat transfer member 25 is cooled by the heat of vaporization of water contained in the water absorbing material 65.

  On the other hand, in this embodiment, the front-end | tip part of a heat-transfer member is cooled by circulating liquid water as follows.

  FIG. 16 is a side cross-sectional view of the server rack 22 and its surroundings according to the present embodiment. In FIG. 16, the same elements as those described in the first embodiment are denoted by the same reference numerals as those in the first embodiment, and the description thereof is omitted below.

  As shown in FIG. 16, in this embodiment, not provided an opening closed by film 11a described in the first embodiment (see FIG. 2) in the separation wall 11.

  FIG. 17 is a front sectional view of the server rack 22 and its surroundings.

  As shown in FIG. 17, a water circulation system 70 is provided around the server rack 22. The circulation system 70 includes a pipe 71, a pump 72, and a shower head 73.

  Among these, the pump 72 is used to circulate cooling water W in the circulation system 70.

  The pipe 71 is, for example, a stainless pipe, and water W circulates inside the pipe 71. An opening 71 a is provided in the middle of the pipe 71, the tip of the heat transfer member 25 such as a heat pipe is inserted into the opening 71 a, and the tip is directly cooled by the water W.

  On the other hand, the shower head 73 injects the water W warmed by the contact with the heat transfer member 25. Thus, a part of the water W ejected from the shower head 73 is evaporated by the wind generated by the blower 74 and is cooled by the latent heat of evaporation.

  According to the present embodiment described above, since the heat of the heat transfer member 25 such as a heat pipe is directly taken away by the water W, the tip of the heat transfer member 25 is air-cooled as in the first to third embodiments. Compared with, the front-end | tip part of the heat-transfer member 25 can be cooled efficiently.

  Therefore, it is not necessary to provide the fins 25a (see FIG. 1) as a preliminary matter at the tip of the heat transfer member 25, and the interval between the computers 23 adjacent to each other in the upper and lower directions is not limited by the fins 25a. The computer 23 can be installed in

  When the heat transfer member 25 is water-cooled as in the present embodiment, the cooling capacity of the heat transfer member 25 is 1 kW or more. This value is sufficient for cooling the heat generating component 57 such as a CPU.

  If 21 computers 23 having a heating value of 200 W are mounted on one server rack 22, the total heating value is 42 kW. In order to cool the water W whose temperature has been increased by the heat generation amount to the original temperature, the water W that has come out of the shower head 73 may be evaporated by about 1.6 (= 4200/2500) g per second.

  Further, since the total amount of water W flowing through the circulation system 70 by in this manner to evaporate the water W becomes less and less, preferably to replenish an appropriate water circulation system 70.

  Furthermore, in this embodiment, since the water W is cooled by the wind generated by the blower 74, the entire system can be saved as compared with the case where the water W is cooled by a device with high power consumption such as a chiller or a refrigerator. Energy can be realized.

(Fifth embodiment)
Similarly to the fourth embodiment, the tip of the heat transfer member 25 is also water-cooled in this embodiment.

  FIG. 18 is a side cross-sectional view of the server rack 22 and its surroundings according to the present embodiment, and FIG. 19 is a front cross-sectional view thereof.

  Incidentally, in FIG. 18 and FIG. 19, the same components as described in the fourth embodiment are denoted by the same reference numerals as in the fourth embodiment, and their explanation will be omitted herein.

  As shown in FIG. 18, in the present embodiment, a metallic water cooling jacket 80 is provided on the heat transfer member 25.

  The water cooling jacket 80 is put on the tip of the heat transfer member 25 as shown in FIG. A tube 81 is connected to the water cooling jacket 80, and water W is supplied to the tube 81 from the middle of the pipe 71.

  The tube 81 according to this embodiment is provided exclusively for each of the water cooling jackets 80, and the plurality of water cooling jackets 80 are not connected by the tubes 81. Thus, by cooling the heat transfer members 25 in parallel with the water W, the water W heated by the one water cooling jacket 80 is not supplied to the other water cooling jackets 80 via the tubes 81. Each of the plurality of heat transfer members 25 can be efficiently cooled with cold water W.

  There are various types of water cooling jackets 80 that can be used in this embodiment. Examples of these will be described below.

(First example)
FIG. 20 is a side sectional view of the water cooling jacket 80 according to the first example.

  The water cooling jacket 80 according to this example includes a water W supply port 80a and a drain port 80b. Further, the water cooling jacket 80 is formed with an opening 80e into which the front end portion of the heat transfer member 25 is inserted. In order to prevent water leakage between the opening 80e and the outer peripheral side surface of the heat transfer member 25. O-ring 85 is provided.

  According to such a water cooling jacket 80, the tip of the heat transfer member 25 is directly exposed by the water W supplied from the supply port 80a, and the heat transfer member 25 is cooled by the water W. By exposing the heat transfer member 25 to the water W in this way, the heat of the heat transfer member 25 can be efficiently taken away by the water W.

(Second example)
FIG. 21A is a side sectional view of a water cooling jacket 80 according to the second example, and FIG. 21B is a front sectional view thereof. In FIGS. 21A and 21B, the same elements as those in the first example are denoted by the same reference numerals, and the description thereof is omitted below.

  In this example, the water cooling jacket 80 is provided with a recess 80y into which the tip of the heat transfer member 25 can be inserted.

  In addition, as shown in FIG. 21B, the water cooling jacket 80 is formed with slits 80s connected to the recess 80y. The interval between the slits 80s can be adjusted by a screw 88, and the water cooling jacket 80 is mechanically firmly fixed to the heat transfer member 25 by tightening the screw 88 in a state where the heat transfer member 25 is inserted into the recess 80y. be able to.

  In this example, even if the water-cooling jacket 80 is removed from the heat transfer member 25, no water leaks from between them, so that maintenance is easier compared to the first example.

  Furthermore, since the heat transfer member 25 is not directly exposed to water, the surface of the heat transfer member 25 is not likely to be corroded by water, and it is not necessary to apply corrosion prevention processing to the heat transfer member 25.

(Third example)
FIG. 22A is a side sectional view of a water cooling jacket 80 according to the third example, and FIG. 22B is a front sectional view thereof.

  In this example, the water cooling jacket 80 is divided into upper and lower parts. Then, the gap 80s formed between the upper and lower water cooling jackets 80 is narrowed by two screws 88.

  Also in this example, as in the second example, water leakage does not occur between the heat transfer member 25 and the water cooling jacket 80, so that maintenance is easy and corrosion prevention processing is performed because the heat transfer member 25 is not exposed to water. There is no need to apply to the heat transfer member 25.

  As mentioned above, although each embodiment was described in detail, each embodiment is not limited to the above. For example, even when the heat transfer member 25 is water-cooled as in the fourth embodiment or the fifth embodiment, the cooling system may be operated under the operation conditions of patterns 1 to 6 (see FIG. 9) of the third embodiment. .

  The following additional notes are disclosed for each embodiment described above.

(Appendix 1) Device installation area where electronic devices are installed;
An air conditioner for performing air conditioning in the device installation area;
A cooling area in which a tip portion of a heat transfer member thermally connected to a heat generating component in the electronic device is disposed;
A separation wall separating the device installation area and the cooling area;
One end is connected to the tip, and the other end has a drain hose connected to a heat exchanger for exchanging heat with the outside airflow from the cooling area,
A cooling system, wherein a nonwoven fabric or a porous material is disposed at the tip.

(Supplementary Note 2) A water supply unit connected to the drain hose and replenishing the nonwoven fabric or the porous material with water,
And determining whether or not the water should be replenished, and further comprising a determination unit for replenishing the non-woven fabric or the porous material by controlling the water supply unit when it is determined that the water should be replenished. The cooling system according to claim 1, wherein the cooling system is characterized.

(Additional remark 3) It further has a moisture meter which measures the moisture value of the nonwoven fabric or the porous material,
The determination unit monitors the moisture value measured by the moisture meter, and determines that the water should be replenished when the moisture value falls below a predetermined moisture value. The cooling system described.

(Additional remark 4) It further has a hygrometer which measures the humidity of the air current downstream from the tip part,
The cooling according to claim 2, wherein the determination unit monitors the humidity measured by the hygrometer, and determines that the water should be replenished when the humidity falls below a predetermined humidity. system.

(Additional remark 5) It is further provided in the said front-end | tip part of the said heat-transfer member, and has further several heat radiation fin of the height lower than the height of the said electronic device,
The cooling system according to any one of appendix 1 to appendix 4, wherein the nonwoven fabric or the porous material is also provided on the surface of the heat radiating fin.

(Appendix 6) A plurality of the electronic devices are provided in the height direction,
The cooling system according to appendix 5, wherein a distance between the plurality of fins is wider in the electronic device upstream of the airflow than in the electronic device downstream of the airflow.

(Appendix 7) A plurality of the electronic devices are provided in the height direction,
The cooling system according to appendix 5, wherein the fins of one electronic device do not overlap the fins of the other electronic device when the plurality of electronic devices are viewed from above.

(Appendix 8) A sensor unit for detecting the temperature and humidity of the outside air;
A control unit that controls the air conditioner and individually determines whether or not to introduce the outside air into the device installation area and the cooling area according to the temperature and humidity of the outside air detected by the sensor unit; The cooling system according to any one of appendices 1 to 7, characterized in that:

(Additional remark 9) The 1st cold air flow path which is provided under the floor of the said apparatus installation area, and communicates with the blower outlet of the said air conditioner,
A first ventilation port provided on the floor of the device installation area to communicate between the device installation area and the first cold air flow path;
A first air supply duct communicating outdoors;
A first damper that is disposed between the first cold air flow path and the first air supply duct and whose open / closed state is controlled by the control unit;
A first hot air flow path that is provided behind the ceiling of the device installation area and communicates with an air intake of the air conditioner;
A first opening provided on a ceiling of the device installation area and communicating between the device installation area and the first hot air flow path;
A first exhaust duct communicating outdoors;
A second damper disposed between the first hot air flow path and the first exhaust duct, the open / close state of which is controlled by the control unit;
A second cold air flow path provided under the floor of the cooling area;
A second ventilation port provided on the floor of the cooling area to communicate between the cooling area and the second cold air flow path;
A second air supply duct that communicates outdoors;
A third damper that is arranged between the second air supply duct and the second cold air flow path and whose open / close state is controlled by the control unit;
A second hot air flow path provided behind the ceiling of the cooling area;
A second opening provided on the ceiling of the cooling area to communicate between the cooling area and the second hot air flow path;
A second exhaust duct communicating outdoors,
A fourth damper disposed between the second hot air flow path and the second exhaust duct and controlled to be opened and closed by the control unit;
The cooling system according to appendix 8, characterized by comprising:

(Appendix 10) Electronic equipment,
A heat transfer member thermally connected to a heat generating component in the electronic device;
A water circulation system for cooling the tip of the heat transfer member with water;
A shower head that is provided in the middle of the circulation system and that jets the water;
A blower that blows air on the water jetted by the shower head;
A cooling system comprising:

(Additional remark 11) The said heat-transfer member is provided with two or more,
The cooling system according to appendix 10, wherein the circulation system cools the tip of each of the plurality of heat transfer members in parallel with the water.

  (Additional remark 12) The said front-end | tip part is not directly exposed to the said water, The cooling system of Additional remark 11 characterized by the above-mentioned.

DESCRIPTION OF SYMBOLS 12 ... Rack installation area, 12a ... Grill, 12b ... Opening part, 13 ... Cooling area, 14, 16 ... Cold air flow path, 15, 17 ... Hot air flow path, 21 ... Air conditioner, 22 ... Server rack, 23 ... Computer, 24a, 24b ... partition, 25 ... heat transfer member, 25a ... fin, 28 ... control unit, 29a, 29b ... sensor unit, 31-37 ... duct, 41-48 ... damper, 51-53 ... fan, 55 ... system board 57 ... Heat generating parts, 60 ... Heat exchanger, 60a ... Fin, 60b ... Piping, 61 ... Moisture meter, 62 ... Water supply unit, 62a ... Valve, 63 ... Drain hose, 65 ... Water supply material, 66 ... Waterproof pan, 67 DESCRIPTION OF SYMBOLS ... Hygrometer, 69 ... Judgment part, 70 ... Circulation system, 71 ... Piping, 71a ... Opening, 72 ... Pump, 73 ... Shower head, 74 ... Blower, 80 ... Water cooling jacket, 80a ... Water supply port, 80b ... Exhaust Mouth, 80e ... opening, 80s ... slit, 80 y ... recess, 85 ... O-ring, 88 ... screw.

Claims (6)

Equipment installation area where electronic equipment is installed;
An air conditioner for performing air conditioning in the device installation area;
A cooling area in which a tip portion of a heat transfer member thermally connected to a heat generating component in the electronic device is disposed;
A separation wall separating the device installation area and the cooling area;
One end is connected to the tip, and the other end has a drain hose connected to a heat exchanger for exchanging heat with the outside airflow from the cooling area,
A cooling system, wherein a nonwoven fabric or a porous material is disposed at the tip. A water supply unit connected to the drain hose and replenishing the nonwoven fabric or the porous material with water,
And determining whether or not the water should be replenished, and further comprising a determination unit for replenishing the non-woven fabric or the porous material by controlling the water supply unit when it is determined that the water should be replenished. The cooling system of claim 1, wherein: It further has a moisture meter for measuring the moisture value of the nonwoven fabric or the porous material,
The said determination part monitors the moisture value measured with the said moisture meter, and when this moisture value becomes below a predetermined moisture value, it is judged that the said water should be replenished. As described in the cooling system. A sensor unit for detecting the temperature and humidity of the outside air;
A control unit that controls the air conditioner and individually determines whether or not to introduce the outside air into the device installation area and the cooling area according to the temperature and humidity of the outside air detected by the sensor unit; The cooling system according to any one of claims 1 to 3, wherein: A first cold air flow path provided below the floor of the equipment installation area and communicating with the air outlet of the air conditioner;
A first ventilation port provided on the floor of the device installation area to communicate between the device installation area and the first cold air flow path;
A first air supply duct communicating outdoors;
A first damper that is disposed between the first cold air flow path and the first air supply duct and whose open / closed state is controlled by the control unit;
A first hot air flow path that is provided behind the ceiling of the device installation area and communicates with an air intake of the air conditioner;
A first opening provided on a ceiling of the device installation area and communicating between the device installation area and the first hot air flow path;
A first exhaust duct communicating outdoors;
A second damper disposed between the first hot air flow path and the first exhaust duct, the open / close state of which is controlled by the control unit;
A second cold air flow path provided under the floor of the cooling area;
A second ventilation port provided on the floor of the cooling area to communicate between the cooling area and the second cold air flow path;
A second air supply duct that communicates outdoors;
A third damper that is arranged between the second air supply duct and the second cold air flow path and whose open / close state is controlled by the control unit;
A second hot air flow path provided behind the ceiling of the cooling area;
A second opening provided on the ceiling of the cooling area to communicate between the cooling area and the second hot air flow path;
A second exhaust duct communicating outdoors,
The cooling according to claim 4, further comprising: a fourth damper disposed between the second hot air flow path and the second exhaust duct and controlled to be opened and closed by the control unit. system. Electronic equipment,
A heat transfer member thermally connected to a heat generating component in the electronic device;
A water circulation system for cooling the tip of the heat transfer member with water;
A shower head that is provided in the middle of the circulation system and that jets the water;
A blower that blows air on the water jetted by the shower head;
A cooling system comprising:

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