KR20120110362A - System for managing temperature of datacenter - Google Patents

Abstract

PURPOSE: A temperature control system of a data center is provided to improve energy efficiency by reducing useless control air. CONSTITUTION: A supply unit(10) supplies control air. The control air controls inner temperature of a data center. A first control unit(20) is connected to the supply unit. The first control unit produces a first temperature area of the data center. A second control unit(30) produces a second temperature area. The second temperature area is connected to the first temperature area. A collection unit(40) collects the control air.

Description

Temperature Management System in Data Centers {SYSTEM FOR MANAGING TEMPERATURE OF DATACENTER}

The present invention relates to a temperature management system of a data center, and more particularly, to a temperature management system of a data center capable of improving energy efficiency by managing airflow in a data center having a temperature region partitioned at different temperatures. It is about.

In a typical data center, a plurality of servers through which predetermined data is input and output are managed. The plurality of servers are supported by predetermined supporting means such as racks. Meanwhile, the data center is classified into a cold zone having a relatively low temperature and a hot zone having a relatively higher temperature than the cold zone, thereby managing servers.

On the other hand, since the server is very sensitive to heat, constant temperature control is required for stable use of the servers provided in the cold zone and the hot zone. The temperature control of the cold zone and the hot zone is generally controlled by supplying air corresponding to a desired temperature. However, when the air of the different temperature is provided separately to the cold zone and the hot zone, a problem of energy waste is caused. In addition, since both the cold zone and the hot zone are provided in an open state, there is a problem that the supplied air is leaked unnecessarily.

The present invention has been made in view of the above problems, and an object thereof is to provide a temperature management system of a data center that can improve energy efficiency.

Another object of the present invention is to provide a temperature management system of a data center that can maintain the inside of the data center at an appropriate temperature.

The temperature management system of the data center according to the present invention for achieving the above object, a supply unit for supplying the control air for controlling the temperature inside the data center having a plurality of servers, connected to the supply unit and the control air A first management unit configured to form a first temperature zone of the data center, the control air communicating with the first temperature zone and receiving the controlled air via the first temperature zone, and neighboring the first temperature zone. And a second management unit forming a second temperature zone of the data center, and a recovery unit connected to the second temperature zone to recover the regulated air.

According to one side, the first management unit includes at least one first guide portion for closing one side of the first temperature region that does not face the second temperature region, to guide the control air to the second temperature region The second management unit includes at least one second guide portion for communicating between one side of the second temperature zone facing the recovery unit and the recovery unit, wherein the plurality of the plurality of management units via the first temperature zone. The controlled air heated by the server is guided to the recovery unit.

According to one side, the first and second guides, respectively, the first and second cover body having a polygonal plate shape to cover one side of the first and second temperature region, respectively, and the first and second cover body It includes a first and a second protector for supporting the edge of each.

According to one side, the first and the second protective body has a plurality of rod-shaped rectangular cross-section in which the first and second support grooves are formed on each surface, respectively, are provided in plurality in the first and second cover body, respectively And the edges of the first and second cover bodies are respectively inserted into the first and second support grooves in a protected state by the first and the second buffer members having elastic materials, and the first and second neighboring ones are respectively adjacent to each other. The protective member is connected by first and second connecting bodies respectively inserted into the first and second supporting grooves.

According to one side, a plurality of supports having an open side for supporting the plurality of servers in the data center is provided adjacent to each other, the first management unit is a pair of at least one of the plurality of supports facing each other A first temperature region partitioned by a first support, the second management unit being partitioned by at least one pair of second supports adjacent to and facing each other at least one of the pair of first supports; 2 Form a temperature zone.

According to one side, the first management unit is provided with at least one first guide for closing the open top between the at least one pair of first support, to guide the control air to the adjacent second temperature zone side And the second management unit is at least one second installed to guide the controlled air heated and introduced by the plurality of servers supported by the first support to an open upper portion between the at least one pair of second supports. It is provided with a guide.

According to one side, the recovery unit includes a recovery duct for recovering the control air in the second temperature region, and a temperature control unit connected to the recovery duct to recool the control air, the second guide portion is the 2, the upper portion of the temperature range and the recovery duct.

According to another aspect of the present invention, a temperature management system of a data center may include: a supply unit supplying regulated air for controlling a temperature inside a data center having a plurality of servers, and connected to the supply unit to receive the regulated air; And a first management unit for forming a first temperature zone of the data center, the control air heated by the server provided in the first temperature zone in communication with the first temperature zone, and receiving the first temperature zone. And a second management unit for forming a second temperature zone of the data center adjacent to the data center, and a recovery unit connected to the second temperature zone for recovering and recooling the controlled air. The unit is provided with guide means for guiding the controlled air to be recovered to the recovery unit via the first and second temperature zones without leakage.

According to one side, the guide means, at least one first guide portion for closing one side of the first temperature region that does not face the second temperature region, and one side of the second temperature region facing the recovery unit And at least one second guide portion communicating with the recovery unit.

According to the present invention having the configuration as described above, first, after passing the first temperature region to the control air, it can be used for temperature control by guiding the controlled air heated by the server in the first temperature region to the second temperature region. As a result, unnecessary consumption of the regulated air can be reduced, thereby contributing to the improvement of energy efficiency.

Second, as the inside of the data center can be managed at a constant temperature, it can contribute to improving server management efficiency.

Third, by recovering the heated control air, it is possible to minimize the formation of unnecessary heating space due to the heated control air.

1 is a configuration diagram schematically showing a temperature management system of a data center according to an embodiment of the present invention;
FIG. 2 is a perspective view schematically illustrating the first and second management units shown in FIG. 1; FIG.
3 is a plan view schematically illustrating the first guide unit illustrated in FIG. 2;
4 is a cross-sectional view schematically showing a state cut along the line IV-IV of FIG.
5 is an enlarged view schematically showing area V of FIG. 3;
FIG. 6 is a plan view schematically illustrating the second guide unit illustrated in FIG. 2, and
FIG. 7 is a cross-sectional view schematically illustrating a state cut along the line VII-VII of FIG. 6.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

Referring to FIG. 1, the temperature management system 1 of a data center according to an exemplary embodiment of the present invention may include a supply unit 10, a first management unit 20, a second management unit 30, and a recovery unit ( 40, the internal temperature of the data center 100 including a plurality of servers S is managed.

The supply unit 10 supplies the control air (A) for adjusting the internal temperature of the data center 100. The supply unit 10 is an air-cooled cooling means is employed to supply the cooled controlled air (A). For reference, since the technology of the air-cooled cooling means can be understood from the known technology, a detailed description thereof will be omitted. In addition, the arrow shown in Figure 1 shows the flow of the control air (A).

The first management unit 20 is connected to the supply unit 10 to receive the control air (A), and forms a partitioned first temperature zone (T1) of the interior of the data center (100). At this time, as the first management unit 20 receives the control air A from the supply unit 10 employing the air-cooled cooling means, the temperature of the first temperature region T1 is cooled to a predetermined temperature.

The second management unit 30 communicates with the first temperature zone T1 to receive the control air A via the first temperature zone T1 so as to be adjacent to the first temperature zone T1. A second temperature region T2 partitioned among the center 100 is formed. At this time, the control air A supplied to the second temperature region T2 of the second management unit 30 is heated by heat generated from the server S of the first temperature region T1. By the flow of the control air A, the temperature of the second temperature region T2 is managed higher than the first temperature region T1.

For reference, inside the data center 100, a plurality of supports 21 and 31 for supporting a plurality of servers S are provided to be adjacent to each other. In this case, the first management unit 20 forms a first temperature region T1 partitioned by at least one pair of first support members 21 facing each other among the plurality of supports 21 and 31. In addition, the second management unit 30 is a second temperature zone (parted by at least one pair of second supports 31 adjacent to each other adjacent to at least one of the pair of first supports 21 ( T2) is formed.

Here, as shown in FIG. 2, the first and second support bodies 21 and 31 have a shape like a kind of shelf and the sides are open, so that the first temperature region T1 is defined. The control air A may be introduced into the second temperature region T2 partitioned by the second support 31 through the first support 21 to be formed. The first and second support members 21 and 31 have distinguished the support members 21 and 31 supporting the server S for convenience of description, and may have the same structure and shape.

For reference, as shown in FIG. 2, the front surface of each of the first and second support bodies 21 and 31 is provided with a door D, and is closed to selectively enter and exit the operator.

The first and second management units 20 and 30 also show the first and second guides 22 and 32 as shown in FIGS. 1 and 2 for the effective flow of the regulated air A. FIG. Like, includes.

The first guide portion 22 closes the open upper portion between the at least one pair of first supports 21 facing each other. Accordingly, the control air A, which is supplied from the supply unit 10 and cools the first temperature region T1 of the first management unit 20, is heated by the heat of the server S while the second management unit ( 30 can be smoothly moved to the second temperature region (T2) side. That is, the first guide part 22 can prevent unnecessary leakage of the control air (A) and control in the flow direction of the control air (A).

As illustrated in FIG. 3, the first guide part 22 may include a first cover body 23 that covers one side of the first temperature region T1, that is, an upper portion thereof, and a portion of the first cover body 23. And a first protector 24 supporting the rim.

The first cover body 23 has a polygonal plate shape, and in the present exemplary embodiment, the first cover body 23 has a rectangular plate shape. In addition, the first cover body 23 may be formed of a transparent acrylic material so that the inside or outside of the first temperature region T1 may be visually checked from the outside for convenience of maintenance / repair.

The first protective member 24 has a plurality of rod-shaped cross sections, and a plurality of first protective members 24 are provided at the edges of the first cover body 23 having the polygonal plate shape. At this time, as shown in Figure 4, each surface of the first protective member 24, that is, the first supporting grooves 25 are formed in the longitudinal direction, respectively, four surfaces. Here, one of the four first support grooves 25 formed on four surfaces of the first protective member 24 has one side edge of the first cover body 23 by the first buffer 26. It is inserted and supported in a protected state. For reference, the first buffer 26 is formed of an elastic material such as a kind of rubber pad to compensate for the play of the first cover body 23 in the first support groove 25.

On the other hand, as shown in Figure 5, the plurality of first protection member 24 is connected to each other by a first connecting member (27). In the present embodiment, the first protective member 24 is cut and installed in accordance with the length of each side of the first cover member 23 having a square plate shape, thereby providing four. Accordingly, the first connecting member 27 has a "-" shape and is inserted into the first supporting grooves 25 of the four first protecting members 24, thereby adjoining the first protecting members 24. Interconnect them. At this time, the first connector 27 is the first three of the four support grooves 25 formed in the first protection member 24, the remaining three first support grooves that do not support the first cover body 23 It is good to insert all of the (25) to interconnect / fix the mutually adjacent first connector (27). The first connector 27 is fixed by the bolt (B) after connecting the neighboring first protection member 24.

On the other hand, when the first protective member 24 protects any one side of the first cover member 23 in plural, the first connecting member 27 has a "-" shape and is provided in parallel with each other. Of course, the protection body 24 may be interconnected.

In addition, the second guide part 32 is an open upper portion between the at least one pair of second support bodies 31 to control air A introduced in a heated state through the first temperature region T1 and will be described later. It is guided to communicate with the recovery unit 40. Accordingly, the second guide part 32 blocks the heated control air A from being re-introduced into the first temperature region T1. As shown in FIG. 6, the second guide part 32 also includes a second cover body 33 and a second protector 34 similarly to the first guide part 22. In addition, the second protector 34 also includes four second support grooves 35 to support the second cover body 33 with the second buffer 36 therebetween. A plurality of second protectors 34 are also provided and connected to each other by a second connector (not shown), but the configuration of the second connector (not shown) has the same configuration as that of the first connector (not shown). Omit illustration.

The recovery unit 40 is connected to the second temperature zone (T2) to recover the control air (A) to re-cool, thereby circulating. Specifically, the recovery unit 40 is connected to the second temperature region (T2) recovery duct 41 for recovering the control air (A), and is connected to the recovery duct 41 to control air (A) It includes a temperature control unit 42 for recooling. The temperature control unit 42 is connected to the supply unit 10 to supply the re-cooled control air (A).

Meanwhile, the recovery duct 41 communicates with the second temperature region T2 of the second management unit 30 by the second guide part 32. In this case, the second guide portion 32 is installed inclined between the upper portion and the recovery duct 41 between the pair of second support 31, as shown in Figures 1 and 2, the control air (A) ) To prevent leakage.

The temperature management operation of the temperature management system 1 of the data center according to the present invention having the above configuration will be described with reference to FIG.

First, as shown in FIG. 1, the controlled air A cooled from the supply unit 10 flows into the first temperature region T1 partitioned by the first management unit 20, thereby providing a first temperature region. T1 is cooled to a constant temperature. The second air temperature partitioned by the second management unit 30 adjacent to the control air A is passed through a plurality of servers S supported by the first support 21 forming the first temperature region T1. Move to area T2. At this time, the control air (A) is not leaked by the first guide portion 22, and moves to the second temperature area (T2) in a heated state by the heat generated from the server (S). Accordingly, the second temperature region T2 is constantly maintained at a relatively higher temperature than the first temperature region T1 by the heated control air A. FIG.

The control air A via the second temperature region T2 is guided by the second guide part 32 and moves to the recovery duct 41 of the recovery unit 40. The control air (A) recovered by the recovery duct 41 is introduced into the temperature control unit 42 and re-cooled and then supplied to the supply unit 10 to be supplied for cooling the first temperature region T1 again. , Circulated.

Although the present invention has been described with reference to the preferred embodiments thereof, it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit and scope of the invention as defined in the following claims. It can be understood that

1: temperature control system 10: supply unit
20: first management unit 21: first support
22: first guide unit 30: second management unit
31: second support 32: second guide
40: recovery unit 100: data center

Claims (11)

As a temperature management system of a data center having a plurality of servers,
A supply unit for supplying controlled air for controlling a temperature inside the data center;
A first management unit connected to the supply unit to receive the control air to form a first temperature region of the data center;
A second management unit communicating with the first temperature zone and receiving the control air via the first temperature zone to form a second temperature zone of the data center adjacent to the first temperature zone; And
A recovery unit connected to the second temperature zone to recover the controlled air;
Temperature management system of the data center comprising a.
The method of claim 1,
The first management unit includes at least one first guide part for closing one side of the first temperature area that does not face the second temperature area, to guide the control air to the second temperature area,
The second management unit includes at least one second guide portion for communicating between one side of the second temperature zone facing the recovery unit and the recovery unit, by the plurality of servers via the first temperature zone. A temperature management system of a data center for guiding the heated controlled air to the recovery unit.
The method of claim 2,
The first and second guide parts respectively include first and second cover bodies having a polygonal plate shape to cover one side of the first and second temperature regions, respectively, and edges of the first and second cover bodies, respectively. Supporting first and second protectors;
Temperature management system of the data center comprising a.
The method of claim 3,
The first and the second protective body has a plurality of rod-shaped rectangular cross-section in which the first and second support grooves are formed on each surface, respectively, are provided in the plurality of first and second cover bodies, respectively,
The edges of the first and second cover bodies are inserted into the first and second support grooves, respectively, while being protected by the first and second buffer members having elastic materials. The protector is a temperature management system of a data center connected by first and second connectors respectively inserted into the first and second support grooves, respectively.
The method of claim 1,
In the data center, a plurality of supports having open sides for supporting the plurality of servers are provided to be adjacent to each other.
The first management unit forms a first temperature region partitioned by at least one pair of first supports facing each other of the plurality of supports, and the second management unit is at least one of the pair of first supports. And a second temperature zone partitioned by at least one pair of second supports facing each other adjacent to each other.
The method of claim 5,
The first management unit includes at least one first guide portion for closing an open upper portion between the at least one pair of first supports, to guide the control air to the neighboring second temperature region,
The second management unit has at least one second guide installed to guide the controlled air heated and introduced by the plurality of servers supported by the first support to an open upper portion between the at least one pair of second supports. Temperature management system of a data center equipped with a wealth.
7. The method according to claim 2 or 6,
The recovery unit includes a recovery duct for recovering the control air in the second temperature region, and a temperature control unit connected to the recovery duct to recool the control air.
And the second guide portion communicates an upper portion of the second temperature region with the recovery duct.
As a temperature management system of a data center having a plurality of servers,
A supply unit for supplying controlled air for controlling a temperature inside the data center;
A first management unit connected to the supply unit to receive the control air to form a first temperature region of the data center;
A second management for communicating with the first temperature zone and receiving the controlled air heated by the server provided in the first temperature zone to form a second temperature zone of the data center adjacent to the first temperature zone; unit; And
A recovery unit connected to the second temperature region to recover and recool the control air;
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And said first and second management units comprise guide means for guiding recovery to said recovery unit via said first and second temperature zones without leaking said controlled air.
9. The method of claim 8,
The guide means includes at least one first guide part for closing one side of the first temperature area that does not face the second temperature area, and one side of the second temperature area that faces the recovery unit and the recovery unit. A temperature management system of a data center including at least one second guide unit for communicating therebetween.
10. The method of claim 9,
The first and second guide parts respectively include first and second cover bodies having a polygonal plate shape to cover one side of the first and second temperature regions, respectively, and edges of the first and second cover bodies, respectively. Supporting first and second protectors;
Temperature management system of the data center comprising a.
11. The method according to claim 9 or 10,
The first management unit is formed to face each other to form a first temperature region by at least one pair of first supports whose sides are opened to support the server, wherein the second management unit is the pair of first supports A second temperature region is formed by at least one pair of second supports having side portions opened to support the server and adjacent to each other adjacent to at least one of
And the first and second guide parts are respectively installed in an open upper portion between the pair of first and second supports.

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