JP2013042023A - Server and server cooling structure - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a server which can be installed as a back-to-back arranged pair in a hot aisle/cold aisle type air flow room, and a server cooling structure using the same.SOLUTION: A server 10 according to the prevent invention comprises: a first ventilation passage 20, provided at a side on one side of a half server enclosure 11 so as to extend in a front-back direction, which has a first communication port 201 communicating with the inside of the half server enclosure 11 formed therein, and also is open at opposite ends to the outside; a second ventilation passage 23, provided at a side on the other side of the half server enclosure 11 so as to extend in a front-back direction, which has a second communication port 202 communicating with the inside of the half server enclosure 11 formed therein, and also is open at a rear side end to the outside; a first fan 24, provided in the first communication port 201, which can be switched between normal and reverse rotations; and a second fan 25, provided in the second communication port 202, which can be switched between normal and reverse rotations.

Description

  The present invention relates to a server that can be installed in a back-to-back state in a hot aisle / cold aisle airflow room, and a server cooling structure using the server.

  A server in which various electronic components are housed in a housing includes a cooling structure as means for cooling the internal electronic components. As this cooling structure, there is conventionally known a structure that sucks air from the front side of the housing, cools the electronic components with the air, and then exhausts air from the back side of the housing (see, for example, Patent Document 1). ).

  And a server provided with such a cooling structure may be installed in a pair back to back from the front side and the rear side of the rack for server installation. In this case, one server sucks air from the front side of the rack and exhausts it to the center part of the rack, and the other server sucks air from the rear side of the rack and exhausts it to the center part of the rack. In this way, the air discharged from both servers rises at the center of the rack, thereby forming a so-called blow-up type air flow.

JP 2004-319628 A

  However, the server having the cooling structure described in Patent Document 1 has a problem that a pair cannot be installed back to back from the front side and the rear side of the rack in a so-called hot aisle / cold aisle airflow room. The purpose of hot aisle / cold aisle airflow indoors is to efficiently cool the room by collecting cool air on one of the front and rear sides of the server and collecting warm air on the other side. To do.

  The reason why this problem occurs is that an air flow configured when a pair of servers having the cooling structure described in Patent Document 1 are installed back to back, that is, an air flow in which the air discharged from both servers rises at the center of the rack. This is because cold air is collected on one of the front side and rear side of the rack and does not match the air flow in the room where warm air is collected on the other side.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to provide a server that can be installed in a back-to-back state in a hot aisle / cold aisle airflow room, and server cooling using the server. To provide a structure.

  The server according to the present invention is a server in which an electronic device is housed in a housing, and is provided on one side of the housing so as to extend in the front-rear direction, and communicates with the inside of the housing. A first air passage formed with a first series of openings and having both ends opened to the outside of the housing; and provided on the other side of the housing to extend in the front-rear direction. A second communication port that communicates with the second air passage, and a rear-side end portion that is open to the outside of the housing and the first serial port, and is capable of switching between forward and reverse rotation. A fan and a second fan provided at the second communication port and capable of switching between forward and reverse rotation are provided.

  A server cooling structure according to the present invention is provided on one side of a first server casing in which an electronic device is accommodated so as to extend in the front-rear direction, and communicates with the inside of the first server casing. A first air passage with both ends opened to the outside of the first server casing and a front side end opened to the cold aisle, and the other side of the first server casing. A second ventilation opening provided in the front and rear direction, and having a second communication port communicating with the inside of the first server housing and having a rear side end opening outside the first server housing. And a third communication port formed to extend in the front-rear direction on one side portion of the second server housing that houses the road and the electronic device, and communicates with the inside of the second server housing. The rear side end opens to the outside of the second server housing and the first communication A third vent path connected to the rear side end of the path, and a fourth vent which extends in the front-rear direction on the other side of the third server casing and communicates with the inside of the second server casing. A communication port is formed, both ends are opened to the outside of the second server housing, and the rear side end is connected to the rear side end of the second air passage, while the front side end is A fourth air passage that opens in the hot aisle, a first fan that is provided at the first communication port and can be switched between forward and reverse rotation, and a second fan that is provided at the second communication port and can be switched between forward and reverse rotation. Two fans, a third fan provided at the third communication port and capable of switching forward / reverse rotation, and a fourth fan provided at the fourth communication port and capable of switching forward / reverse rotation. Features.

  According to the server of the present invention, when a pair is installed in a back-to-back state, it is possible to configure an air flow that passes through the pair of servers from the front side of one server and reaches the front side of the other server. .

It is a schematic cross-sectional view which shows one usage example of the server which concerns on 1st embodiment of this invention. It is a cross-sectional view. It is a schematic cross-sectional view which shows the other usage example of the server which concerns on 1st embodiment of this invention. It is a schematic cross-sectional view which shows the server which concerns on 2nd embodiment of this invention. It is a schematic cross-sectional view which shows one usage example of the server cooling structure using the server which concerns on 1st embodiment of this invention. It is a schematic cross-sectional view which shows the other usage example of the server cooling structure using the server which concerns on 1st embodiment of this invention.

Hereinafter, a server according to a plurality of embodiments of the present invention and a server cooling structure using the same will be described with reference to the drawings.
(First embodiment)
As shown in FIG. 1, the server 10 according to the first embodiment of the present invention includes a front plate 12, a rear plate 13, one side plate 14, the other side plate 15 facing the one side plate 14, and a bottom plate. 16 and a rack mount type half server housing 11 having a top plate 17.

The server 10 is disposed on one side of the half server casing 11 so as to extend in the front-rear direction, and includes a first air passage 20 having one end 18 and the other end 19 opened to the outside. A first series opening 201 is formed on one end 18 side of the first air passage 20 so as to communicate with the inside of the half server housing 11.
The server 10 is arranged to extend in the front-rear direction on the other side of the half server housing 11 facing the first air passage 20, one end 21 is closed, and the other end 22 is opened. A second air passage 23 is provided. A second communication port 202 is formed on the other end 22 side of the second air passage 23 so as to communicate with the inside of the half server housing 11.

The server 10 includes a first fan 24 that is disposed in the first series opening 201 and can switch between forward and reverse rotations, and a second fan 25 that is disposed in the second communication port 202 and can switch between forward and reverse rotations. .
The server 10 includes an auxiliary fan 26 that is disposed at one end 18 of the first air passage 20 and can switch between forward and reverse rotations.

The first fan 24, the second fan 25, and the auxiliary fan 26 are electrically connected to a control circuit (not shown).
Therefore, the first fan 24, the second fan 25, and the auxiliary fan 26 are rotated forward or backward by the current supplied from the control circuit.

Next, a usage example of the server 10 will be described.
In the server 10, one end 18 of the first air passage 20 and the auxiliary fan 26 are thermally connected to the cold aisle, and the other end 22 of the second air passage 23 is thermally connected to the hot aisle. .

The auxiliary fan 26, the first fan 24, and the second fan 25 are rotated forward by the control circuit.
When the auxiliary fan 26 is rotated forward, the cold air of the cold aisle is sucked into the first air passage 20 in order to generate a negative pressure on the first fan 24 side.

The first fan 24 rotates in the positive direction to generate a negative pressure inside the half server housing 11, so that the cold air introduced into the first air passage 20 by the auxiliary fan 26 is removed from the half server housing 11. Aspirate inside.
As a result, cold air is introduced into the half server housing 11.
And the cool air introduced into the inside of the half server housing 11 rises in temperature and becomes warm by cooling an electronic component (not shown).

The second fan 25 sucks warm air inside the half server housing 11 into the second air passage 23 in order to generate a negative pressure in the second air passage 23 by rotating forward.
Then, the warm air introduced into the second air passage 23 is discharged from the other end 22 of the second air passage 23 to the hot aisle side.
Therefore, an air flow from the one end 18 of the first air passage 20 and the auxiliary fan 26 through the inside of the half server housing 11 to the other end 22 of the second air passage 23 can be configured.

Next, another usage example of the server 10 will be described.
As shown in FIG. 2, in the server 10, one end 18 of the first air passage 20 and the auxiliary fan 26 are thermally connected to the hot aisle, and the other end 22 of the second air passage 23 is cold aisle. Thermally connected to.

The auxiliary fan 26, the first fan 24, and the second fan 25 are reversely rotated by the control circuit.
The second fan 25 is reversely rotated to generate a negative pressure in the half server housing 11, so that the cold air of the cold aisle is sucked into the second air passage 23 and the inside of the half server housing 11. To introduce.
As a result, cold air is introduced into the half server housing 11.
And the cool air introduced into the inside of the half server housing 11 rises in temperature and becomes warm by cooling the electronic components.

The first fan 24 sucks warm air from the inside of the half server housing 11 into the first air passage 20 in order to generate a negative pressure in the first air passage 20 by being reversely rotated.
The auxiliary fan 26 is reversely rotated to discharge the warm air introduced into the first air passage 20 by the first fan 24 to the hot aisle side in order to generate a negative pressure on the hot aisle side.
Therefore, an air flow from the other end portion 22 of the second air passage 23 through the inside of the half server housing 11 to the one end portion 18 of the first air passage 20 and the auxiliary fan 26 can be configured.

As described above, according to the server 10 of the first embodiment, the first fan 24 and the second fan 25 are set to be correct regardless of whether they face cold aisle or hot aisle. This can be done by reverse rotation.
Therefore, according to the server 10 of the first embodiment, versatility can be expanded with the same structure.

  Further, according to the server 10 of the first embodiment, by providing the auxiliary fan 26 in addition to the first fan 24 and the second fan 25, it is possible to enhance the air flow and improve the cooling efficiency.

(Second embodiment)
Next, a server according to the second embodiment of the present invention will be described.
In the following embodiments, components that are the same as those in the first embodiment described above or functionally similar components are denoted by the same or corresponding reference numerals in the drawings, and the description is simplified or omitted. To do.

As shown in FIG. 3, in the server 30 according to the second embodiment of the present invention, a plurality of first series openings 201 are formed in the first air passage 20. The first series ports 201 are respectively provided with first fans 31 and 32 that can switch between forward and reverse rotations.
In the server 30, a plurality of second communication ports 202 are formed in the second air passage 23. The second communication ports 202 are respectively provided with second fans 33 and 34 that can switch between forward and reverse rotations.
The first fans 31 and 32 and the second fans 33 and 34 are not limited to two as shown in FIG. 3, but may be three or more.

  According to the server 30 of the second embodiment, by providing the plurality of first fans 31 and 32 and the plurality of second fans 33 and 34, it is possible to enhance the air flow and improve the cooling efficiency.

(Third embodiment)
Next, a server cooling structure using the server according to the first embodiment of the present invention will be described. FIG. 4 is a schematic cross-sectional view showing one usage example of the server cooling structure 40 using the server according to the first embodiment of the present invention.
The server cooling structure 40 includes a first half server housing 41 and a second half server housing 42 that are installed back to back and are accommodated in the server rack 1.
That is, the server cooling structure 40 is configured by preparing a pair of the servers 10 of the first embodiment and combining the rear plates 13 together on the back surface.

The server cooling structure 40 includes a first air passage 46 that is disposed on one side plate 43 of the first half server housing 41 so as to extend in the front-rear direction and that has one end 44 and the other end 45 opened. . A first continuous port 461 is formed on one end 44 side of the first air passage 46 so as to communicate with the inside of the first half server housing 41.
The server cooling structure 40 is arranged to extend in the front-rear direction on the other side plate 47 of the first half server housing 41 facing the first air passage 46, one end 48 is closed, and the other end 49. Is provided with a second air passage 50 that is opened. A second communication port 501 is formed on the other end 49 side of the second air passage 50 so as to communicate with the inside of the second half server housing 42.

The server cooling structure 40 is disposed so as to extend in the front-rear direction on one side plate 51 of the second half server housing 42, one end 52 communicates with the first air passage 46, and the other end 53 is blocked. The third ventilation path 54 is provided. A third communication port 541 is formed on one end 52 side of the third air passage 54 so as to communicate with the inside of the second half server housing 42.
The server cooling structure 40 is disposed so as to extend in the front-rear direction on the other side plate 55 of the second half server housing 42 facing the third air passage 54, and one end portion 56 is communicated with the second air passage 50. The fourth end passage 58 is provided with the other end 57 opened. A fourth communication port 581 is formed on one end 56 side of the fourth ventilation path 58 so as to communicate with the inside of the second half server housing 42.

The server cooling structure 40 includes a first fan 59 that is disposed in the first series opening 461 and can switch between forward and reverse rotation.
The server cooling structure 40 includes a second fan 60 disposed at the second communication port 501 and capable of switching between forward and reverse rotation.

The server cooling structure 40 includes a third fan 61 disposed at the third communication port 541 and capable of switching between forward and reverse rotation.
The server cooling structure 40 includes a fourth fan 62 that is disposed in the fourth communication port 581 and that can switch between forward and reverse rotations.
The server cooling structure 40 is disposed at one end 44 of the first air passage 46, and is disposed at the first auxiliary fan 63 capable of switching forward and reverse rotation, and the other end 57 of the fourth air passage 58, And a second auxiliary fan 64 capable of switching between forward and reverse rotation.

Next, a usage example of the server cooling structure 40 will be described.
In the server cooling structure 40, one end 44 of the first air passage 46 and the first auxiliary fan 63 are thermally connected to the cold aisle, and the other end 57 of the fourth air passage 58 and the second auxiliary fan 64. Is thermally connected to the hot aisle.

The first auxiliary fan 63, the first fan 59, the second fan 60, the third fan 61, the fourth fan 62, and the second auxiliary fan 64 are rotated forward by the control circuit.
The first auxiliary fan 63 sucks cold air from the cold aisle into the first air passage 46 and the third air passage 54 in order to generate a negative pressure on the first fan 59 side by rotating forward.

The first fan 59 rotates in the positive direction to generate a negative pressure inside the first half server housing 41, so that the cold air introduced into the first air passage 46 is transferred to the first half server housing 41. Aspirate inside.
At the same time, the third fan 61 rotates in the positive direction to generate a negative pressure inside the second half server housing 42, so that the cool air introduced into the third air passage 54 is transferred to the second half server housing 42. Suck into the body 42.

As a result, cold air is introduced into the first half server housing 41 and the second half server housing 42.
Then, the cool air introduced into the first half server housing 41 and the cool air introduced into the second half server housing 42 rise in temperature and become warm air by cooling the electronic components.

The second fan 60 sucks warm air inside the first half server housing 41 into the second air passage 50 in order to generate a negative pressure in the second air passage 50 by rotating forward.
The fourth fan 62 sucks warm air inside the second half server housing 42 into the fourth ventilation path 58 in order to generate a negative pressure in the fourth ventilation path 58 by rotating forward.
The second auxiliary fan 64 rotates in the positive direction to generate the warm air introduced into the second air passage 50 and the warm air introduced into the fourth air passage 58 in order to generate a negative pressure on the hot aisle side. Drain to hot aisle side.
Therefore, the first air passage 46 passes through the first half server housing 41 and the second half server housing 42 from the one end 44 of the first air passage 46 and the first auxiliary fan 63, and the fourth air passage 58. The air flow to the other end 57 and the second auxiliary fan 64 can be configured.

Next, another usage example of the server cooling structure 40 will be described.
As shown in FIG. 5, the server cooling structure 40 includes the other end 57 of the fourth air passage 58 and the second auxiliary fan 64 that are thermally connected to the cold aisle, and one end of the first air passage 46. 44 and the first auxiliary fan 63 are thermally connected to the hot aisle.

The first auxiliary fan 63, the first fan 59, the second fan 60, the third fan 61, the fourth fan 62, and the second auxiliary fan 64 are reversely rotated by the control circuit.
The second auxiliary fan 64 is reversely rotated to suck the cold air of the cold aisle into the fourth ventilation path 58 and the second ventilation path 50 in order to generate a negative pressure on the fourth fan 62 side.

The fourth fan 62 is reversely rotated to generate a negative pressure inside the second half server housing 42, so that the cold air introduced into the fourth air passage 58 is removed from the second half server housing 42. Aspirate inside.
At the same time, the second fan 60 is reversely rotated to generate a negative pressure in the first half server housing 41, so that the cold air introduced into the second air passage 50 is removed from the first half server housing 41. Suck into the body 41.

As a result, cold air is introduced into the first half server housing 41 and the second half server housing 42.
Then, the cool air introduced into the first half server housing 41 and the cool air introduced into the second half server housing 42 rise in temperature and become warm air by cooling the electronic components.

The third fan 61 sucks warm air inside the second half server housing 42 into the third air passage 54 in order to generate a negative pressure in the third air passage 54 by being reversely rotated.
The first fan 59 sucks warm air inside the first half server housing 41 into the first air passage 46 in order to generate a negative pressure in the first air passage 46 by being reversely rotated.
The first auxiliary fan 63 rotates in the reverse direction to generate warm air introduced into the first air passage 46 and warm air introduced into the third air passage 54 in order to generate a negative pressure on the hot aisle side. Drain to hot aisle side.
Accordingly, the other end 57 of the fourth air passage 58 and the second auxiliary fan 64 pass through the insides of the two first half server housings 41 and the second half server housing 42 to form the first air passage 46. The air flow reaching one end 44 of the first and the first auxiliary fan 63 can be configured.

According to the server cooling structure 40 of the third embodiment, a pair of servers having the same structure are combined to pass through the inside of the first half server casing 41 and the second half server casing 42 combined back to back. Air can be circulated.
Therefore, according to the server cooling structure 40 of the third embodiment, versatility can be expanded with the same structure.

  Moreover, according to the server cooling structure 40 of 3rd embodiment, by further providing the 1st auxiliary | assistant fan 63 and the 2nd auxiliary | assistant fan 64, the flow of air can be strengthened and cooling efficiency can be improved.

  In addition, the server of this invention and the server cooling structure using the same are not limited to each embodiment mentioned above, A suitable deformation | transformation, improvement, etc. are possible.

As described above, according to the server of the present invention and the server cooling structure using the server, versatility can be expanded with the same structure.
As a result of the above, it is possible to mass-produce parts having a single structure, so that productivity can be improved and manufacturing can be advantageously performed in terms of cost, and the industrial applicability of the present invention can be said to be great.

1 server rack 10 server 11 half server housing 12 front plate 13 rear plate 14 one side plate 15 other side plate 16 bottom plate 17 top plate 18 one end 19 other end 20 first air passage 201 202 Second communication port 21 One end 22 The other end 23 Second air passage 24 First fan 25 Second fan 26 Auxiliary fan 30 Server 31 First fan 32 First fan 33 Second fan 34 Second fan 40 Server cooling structure 41 First half server housing 42 Second half server housing 43 One side plate 44 One end 45 The other end 46 The first air passage 461 The first passage 47 The other side plate 48 One end Portion 49 Other end portion 50 Second air passage 501 Second communication port 51 One side plate 52 One end portion 53 Other end portion 54 Third air passage 541 Third communication port 55 Other side plate 56 One end 57 the other end 58 a fourth air passage 581 fourth communication port 59 first fan 60 second fan 61 third fan 62 fourth fan 63 first auxiliary fan 64 second auxiliary fan

Claims (5)

A server in which an electronic device is housed in a housing,
A first vent that is provided on one side of the casing so as to extend in the front-rear direction, has a first series of openings that communicate with the interior of the casing, and has both ends open to the outside of the casing. Road,
A second communication port is formed on the other side of the housing so as to extend in the front-rear direction, and a second communication port communicating with the inside of the housing is formed, and a rear side end opens to the outside of the housing. An airway,
A first fan provided in the first series passage and capable of switching between forward and reverse rotation;
A second fan provided at the second communication port and capable of switching between forward and reverse rotation;
A server comprising:   2. The server according to claim 1, further comprising an auxiliary fan that is provided in the front side opening of the first air passage and is capable of switching between forward and reverse rotations.   3. The server according to claim 1, wherein a plurality of the first series of openings are formed in the first air passage, and the first fan is provided in each of the first series of openings.   The server according to any one of claims 1 to 3, wherein a plurality of the second communication ports are formed in the second air passage, and the second fans are provided in the second communication ports, respectively. . A first serial port is formed on one side of the first server housing containing the electronic device so as to extend in the front-rear direction, and communicates with the inside of the first server housing. A first ventilation path whose part opens to the outside of the first server housing and whose front side end opens to the cold aisle;
A second communication port is formed at the other side of the first server casing so as to extend in the front-rear direction, and communicates with the interior of the first server casing. A second air passage opening to the outside of the housing;
A third communication port is formed on one side of the second server housing containing the electronic device so as to extend in the front-rear direction, and communicates with the inside of the second server housing. A third air passage having an end opened to the outside of the second server housing and connected to the rear side end of the first air passage;
A fourth communication port is formed on the other side of the third server casing so as to extend in the front-rear direction, and communicates with the inside of the second server casing. A fourth vent path that opens to the outside of the body and whose rear side end is connected to the rear side end of the second vent path, while the front side end opens to the hot aisle;
A first fan provided in the first series passage and capable of switching between forward and reverse rotation;
A second fan provided at the second communication port and capable of switching between forward and reverse rotation;
A third fan provided at the third communication port and capable of switching between forward and reverse rotation;
A fourth fan provided at the fourth communication port and capable of switching between forward and reverse rotation;
A server cooling structure comprising:

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