KR102204641B1 - Independent air conditioning system for Data center - Google Patents

Abstract

According to the present invention, the server rack module 100 to which the server 1 is mounted; A cooling module 200 for cooling air heated by heat generation of the server 1; And a power supply module 300 for supplying power to the server 1 and the cooling module 200; but, a server rack having a length direction (a) by which a plurality of server rack modules 100 are combined A data center independent air conditioning system is provided, characterized in that (10) is formed, and two or more server racks (10) are formed to face each other along the length direction (a).
According to the present invention, it is possible to operate an independent air conditioning system for each individual server rack installed in a data center, thereby maximizing the efficiency of server heat removal.

Description

Data center independent air conditioning system and data center air conditioning management method using the same{Independent air conditioning system for Data center}

The present invention relates to a data center independent air conditioning system. In more detail, the infrastructure facilities such as servers installed in the data center are modularized to increase the convenience of facility construction, and the air conditioning system can be independently operated for each module to increase the energy efficiency of the operation of the air conditioning system. A data center independent air conditioning system and a data center air conditioning management method using the same.

Data center is a facility that manages information system equipment such as computer devices in a certain space in order to provide information and communication services pursuant to Notification No. 2012-29 of the Korea Communications Commission, and is a major facility (central monitoring room, constant temperature and humidity facility, computer room, electric power It is defined as a facility including a monitoring room, storage battery facility, self-generation facility, water substation facility, communication equipment room, and disaster prevention center).

In the data center, ICT equipment such as servers and storage are centrally integrated in the interior space of the building to integrate and manage equipment necessary for IT service provision, and operate reliably, 24 hours a day, 365 days a year.

The data center is the most important infrastructure for the implementation and fostering of ICBM, the fourth industry, and is a core infrastructure for promoting national informatization strategies, such as cloud computing, big data analysis, IoT implementation, e-government, smart office, and e-commerce. It acts as a data hub that stores and processes all information occurring in the industry.

Data centers correspond to high-density energy-intensive buildings that use about 40 times more energy than general buildings.

Accordingly, the energy consumption of data centers has doubled every four years for the past 10 years, and heat removal according to the increased power consumption is a major problem.

Conventionally, in order to solve the heat generation problem generated by the server 62 installed in the data center, the floor 61 is spaced apart, and cold air is supplied through the spaced space under the floor, and then through the intake and exhaust system of the server. The heat generated inside the server was removed. In addition, the warm air heated in the heat removal process was transferred to the external cooler 63 through the exhaust system 64 of the ceiling, thereby circulating air (FIG. 1).

However, such a conventional data center air conditioning system has a problem that the cold air delivered from the floor cannot be delivered to the inside of the server and flows into the exhaust part of the ceiling, thereby reducing the efficiency of heat removal (Fig. 3), and the hot air used for heat removal is again There was a problem that a hot spot was generated by flowing into the server (FIG. 4).

The present invention was derived to solve the problem of the conventional data center air conditioning system, and an object of the present invention is to maximize the efficiency of heat removal by allowing an independent air conditioning system to be operated for each individual server rack installed in the data center. It is to provide a data center independent air conditioning system and a data center air conditioning management method using the same.

Another object of the present invention is to provide a data center independent air conditioning system that is easy to install and reinstall by modularizing server racks, cooling systems and walls installed in a data center, and a data center air conditioning management method using the same.

Another object of the present invention is to provide a data center independent air conditioning system and a data center air conditioning management method using the same, which enables determining the optimal cooling system operation by measuring the temperature of the shielded internal space for each individual module in real time.

According to an aspect of the present invention, a server rack module 100 to which the server 10 is mounted; A cooling module 200 for cooling air heated by heat generated by the server 10; And a power supply module 300 for supplying power to the server 10 and the cooling module 200; but, a server rack having a length direction (a) by which a plurality of the server rack modules 100 are combined A data center independent air conditioning system is provided, characterized in that (10) is formed, and two or more server racks (10) are formed to face each other along a length direction (a).

In this case, a first space 51 in which the intake part 11 of the server 10 mounted on the server rack 10 is exposed; And a second space 52 through which the exhaust part 12 of the server 10 mounted on the server rack 10 is exposed; a wall module 400 that closes the first space 51 It may be a data center independent air conditioning system, characterized in that it further comprises.

In addition, the wall module 400 includes a ceiling wall 410 closing the upper portion of the first space 51; And side walls 420 for closing both sides of the first space 51, wherein the side walls 420 include door walls 421 for opening and closing the first space 51; It may be a data center independent air conditioning system comprising a.

In addition, the cooling module 200 is formed between a plurality of the server rack module 100 forming the server rack 10, the exhaust part 210 of the cooling module 200 is the first space It is formed in 51, and the intake part 220 of the cooling module 200 may be a data center independent air conditioning system, characterized in that it is formed in the second space 52.

In addition, a second wall module 500 that shields the second space 52 and separates the second space 52 from the first space 51; data further comprising: It may be a center independent air conditioning system.

In addition, a first temperature sensor (610) for generating first temperature information by sensing the temperature of the first space (51); And a second temperature sensor 620 that senses the temperature of the second space 52 to generate second temperature information. The data center independent air conditioning system may further include.

In addition, a display unit 700 to display the first temperature information and the second temperature information; And a control unit 800 for controlling the cooling module 200 according to the first temperature information and the second temperature information. The data center independent air conditioning system may further include.

According to another embodiment of the present invention, in a data center air conditioning management method using an independent data center air conditioning system, heating air in the second space 52 is inhaled through the intake part 220 of the cooling module 200. A first step (S100); A second step (S200) of producing cooling air by cooling the heated air inhaled by the cooling module 200 in the first step (S100); And a third step (S300) of exhausting the cooling air produced in the second step (S200) to the first space 51 through the exhaust part 210 of the cooling module 200. A data center independent air conditioning system is provided.

According to the present invention, it is possible to operate an independent air conditioning system for each individual server rack installed in a data center, thereby maximizing the efficiency of server heat removal.

According to the present invention, a server rack installed in a data center, a cooling system, and a wall are modularized, so that construction is convenient and installation and relocation are easy.

According to the present invention, it is possible to determine the optimal cooling system operation by measuring the temperature of the shielded internal space for each individual module in real time.

1 is a structural diagram of a data center air conditioning system according to the prior art.
2 and 3 are diagrams showing problems of a data center air conditioning system according to the prior art.
4 is a perspective view of a data center independent air conditioning system according to an embodiment of the present invention.
5 is a cross-sectional view of a data center independent air conditioning system according to an embodiment of the present invention.
6 is a perspective perspective view of an independent data center air conditioning system according to another embodiment of the present invention.
7 is a longitudinal sectional view showing the air flow of the independent data center air conditioning system according to an embodiment of the present invention.
8 is a cross-sectional view showing the air flow of the independent data center air conditioning system according to an embodiment of the present invention.

An embodiment of a data center independent air conditioning system and a data center air conditioning management method using the same according to the present invention will be described in detail with reference to the accompanying drawings, and in the description with reference to the accompanying drawings, the same or corresponding components are the same drawings. Numbers are assigned and redundant descriptions thereof will be omitted.

In addition, terms such as first and second used hereinafter are merely identification symbols for distinguishing the same or corresponding elements, and the same or corresponding elements are limited by terms such as first and second. no.

In addition, the term “couple” does not mean only a case in which each component is in direct physical contact with each other in the contact relationship between each component, but a different component is interposed between each component, and the component is It should be used as a concept that encompasses each contact.

The present invention relates to a data center independent air conditioning system.

Specifically, it efficiently cools heat generated by devices such as servers installed in the data center, and enables the installation of data center facilities using modular subsidiary materials.

The data center independent air conditioning system according to an embodiment of the present invention includes a server rack module 100 in which the server 1 is mounted, a cooling module 200 for cooling air heated by heat from the server 1, and a server 1 ) And a power supply module 300 for supplying power to the cooling module 200 (FIG. 5).

The server 1 in the present invention refers to all devices or equipment that cause heat generation installed in a data center, and is not limited to a computer data storage device.

The server rack module 100 refers to a unit unit for configuring a device installation location such as the server 1 configured in a frame manner.

According to an embodiment of the present invention, a plurality of server rack modules 100 are combined to form a server rack 10 having a longitudinal direction (a) (FIG. 4).

In this case, two or more server racks 10 may be formed to face each other along the length direction (a) (FIG. 7).

A plurality of server racks 10 may be formed in one room of the data center, and the number of server racks 10 to be installed may vary depending on the purpose and purpose of use of the data center.

In the data center independent air conditioning system according to an embodiment of the present invention, the intake part 11 of the server 1 mounted on the server rack 10 is exposed, and the first space 51 and the server rack 10 are mounted. It may include a second space 52 to which the exhaust part 12 of the server 1 is exposed (FIG. 7).

In this case, the first space 51 may be closed by the wall module 400.

As will be described later, the first space 51 is a space in which cooling air is discharged from the exhaust part 210 of the cooling module 200, and allows the cooling air to stay in the first space 51 It is possible to increase the ratio of the cooling air that is inhaled into the intake part.

Accordingly, it is possible to efficiently cool the heated air generated by heat generation of the server 1 by preventing the separation of cooling air (FIG. 3), which was a problem in the conventional data center air conditioning system.

The wall module 400 may include a ceiling wall 410 that closes an upper portion of the first space 51 and a side wall 420 that closes both sides of the first space 51. In this case, the side wall 420 may be a door wall 421 responsible for opening and closing the first space 51 (FIG. 4).

Accordingly, it is possible for a worker to easily access the inside of the first space 51.

In addition, the data center independent air conditioning system according to another embodiment of the present invention shields the second space 52 and separates the second space 52 from the first space 51 ( 500) may be further included (FIG. 6).

As will be described later, the second space 52 is a space where the heated air discharged from the exhaust part 12 of the server 1 stays, and the second space 52 is shielded by using the second wall module 500. The heated air on the second space 52 is prevented from spreading.

Accordingly, it is possible to solve the problem of recirculation of heated air (FIG. 2), which was a problem in the conventional data center air conditioning system.

The cooling module 200 is a configuration for cooling the heated air heated by the heat generated by the server 1, and may be formed between a plurality of server rack modules 100 forming the server rack 10 (FIG. 5 ).

In the conventional air conditioning system of a data center, a separate cooler is provided outside the server room to cool the heated air discharged through the server room ceiling exhaust structure, and then inject the cooling air back to the bottom of the floor plate.

In comparison with this, in the present invention, in order to increase the cooling efficiency of the server (1) heat generation and to increase the re-cooling efficiency of the heated air, a cooler is mounted on a rack with a cooler formed between the server rack modules 100 on which the server 1 is mounted It facilitates the supply of cooling air and increases the re-cooling efficiency of the heated air.

It is preferable that the exhaust part 210 of the cooling module 200 is formed in the first space 51, and the intake part 220 of the cooling module 200 is formed in the second space 52 (FIG. 7) .

In this case, the heated air heated by the heat generated by the server 1 is discharged to the second space 52, and the heated air in the second space 52 is transferred into the cooler through the intake part 220 of the cooling module 200. It is brought in. The heated air introduced into the cooler is converted into cooling air by the action of the cooler, and the cooling air is discharged to the first space 51 through the exhaust part 210 of the cooling module 200. The cooling air discharged onto the first space 51 is introduced into the server 1 through the intake part 11 of the server 1 and serves to remove heat from the server 1.

In this case, the location of the exhaust part 210 of the cooling module 200 is preferably formed higher than the intake part 11 of the server 1. In addition, the position of the intake part 220 of the cooling module 200 is preferably formed to be lower than the exhaust part 12 of the server 1.

This is to increase the efficiency of intake and exhaust according to the temperature of the air.

In the data center independent air conditioning system according to an embodiment of the present invention, the temperature of the first temperature sensor 610 and the second space 52 to generate first temperature information by sensing the temperature of the first space 51 Accordingly, a second temperature sensor 620 for generating second temperature information may be further included (FIG. 7).

The temperature information sensed by the temperature sensor 600 may be externally displayed by the display unit 700.

In addition, by using the control unit 800 that controls the cooling module 200, the manager can determine the optimal degree of operation of the cooling module 200 according to the temperature information.

Alternatively, the controller 800 may control the cooling module 200 according to a preset algorithm in consideration of the first temperature information and the second temperature information. For example, when the second temperature information is higher than a predetermined upper value, the degree of operation of the cooling module 200 may be increased so that the first temperature information is lowered. Conversely, when the second temperature information is lower than a predetermined lower value, the degree of operation of the cooling module 200 may be reduced so that the first temperature information increases.

Accordingly, it is possible to efficiently use energy for the operation of the data center air conditioning system.

Hereinafter, a data center air conditioning management method using an independent data center air conditioning system according to an embodiment of the present invention will be described.

The data center air conditioning management method includes a first step (S100) of inhaling heated air from the second space 52 to the intake unit 220 of the cooling module 200, and from the first step (S100) to the cooling module 200. The cooling air produced in the second step (S200) and the second step (S200) of producing cooling air by cooling the inhaled heated air is transferred to the first space 51 through the exhaust part 210 of the cooling module 200. It may include a third step (S300) of exhausting.

Since the above is only described with respect to some of the preferred embodiments that can be implemented by the present invention, as well known, the scope of the present invention should not be limited to the above embodiments and should not be interpreted. It will be said that both the technical idea and the technical idea together with the fundamental are included in the scope of the present invention.

1: server
10: server rack
100: server rack module
200: pipe rack segmentation module
300: power supply module
400: wall module
500: second wall module
600: temperature sensor
700: display unit
800: control unit

Claims (8)

Server rack module 100 to which the server 1 is mounted;
A cooling module 200 for cooling the air heated by the heat generated by the server 1; And
Including; a power supply module 300 for supplying power to the server (1) and the cooling module (200),
The plurality of server rack modules 100 are combined to form a server rack 10 having a longitudinal direction (a),
Two or more server racks 10 are formed to face each other along the length direction (a),
A first space 51 in which the intake part 11 of the server 1 mounted on the server rack 10 is exposed; And
Including; a second space 52 to which the exhaust part 12 of the server 1 mounted on the server rack 10 is exposed,
A wall module 400 closing the first space 51; further includes,
The cooling module 200 is
It is formed between a plurality of the server rack module 100 forming the server rack 10,
The exhaust part 210 of the cooling module 200 is formed in the first space 51,
The intake part 220 of the cooling module 200 is formed in the second space 52,
A second wall module 500 that shields the second space 52 and separates the second space 52 from the first space 51;
Data center independent air conditioning system, characterized in that further comprising.
delete The method of claim 1,
The wall module 400 is
A ceiling wall 410 closing the upper portion of the first space 51; And
Including; side walls 420 closing both sides of the first space 51,
The side wall 420 is
And a door wall (421) responsible for opening and closing the first space (51).
delete delete The method of claim 3,
A first temperature sensor 610 that senses the temperature of the first space 51 to generate first temperature information; And
A second temperature sensor 620 that senses the temperature of the second space 52 to generate second temperature information;
Data center independent air conditioning system, characterized in that it further comprises.
The method of claim 6,
A display unit 700 to display the first temperature information and the second temperature information; And
A control unit 800 for controlling the cooling module 200 according to the first temperature information and the second temperature information;
Data center independent air conditioning system, characterized in that it further comprises.
In the data center air conditioning management method using the data center independent air conditioning system of claim 7,
A first step (S100) of inhaling heated air in the second space 52 through the intake part 220 of the cooling module 200;
A second step (S200) of producing cooling air by cooling the heated air inhaled by the cooling module 200 in the first step (S100); And
A third step (S300) of exhausting the cooling air produced in the second step (S200) to the first space 51 through the exhaust part 210 of the cooling module 200;
Data center air conditioning management method comprising a.

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