KR102525128B1 - Cooling system of data center server using LNG cooling - Google Patents

Abstract

The present invention vaporizes LNG by circulating the cooling liquid in the LNG vaporizer to produce NG (Natural Gas) and supply it to the demand place, and the refrigerant liquid including the cold heat generated in the vaporization process is heat exchanged at 5 ° C or less in the heat exchanger The present invention relates to a cooling system for a data center server using LNG cold heat to cool the server by sending it to a data center. In an LNG vaporization system capable of supplying post-vaporized NG (Natural Gas) to a consumer, a supply pipe and a recovery pipe capable of circulating a refrigerant liquid in the LNG vaporizer, and heat exchange between the ends of the supply pipe and the recovery pipe A configuration comprising a heat exchanger that can be made, a cooling pipe installed at the other end of the heat exchanger to supply the heat-exchanged gas to the server, and a heating pipe for supplying the heat recovered after cooling the server to the heat exchanger It is intended to provide a cooling system for a data center server using LNG cold heat.

Description

Cooling system of data center server using LNG cooling}

The present invention vaporizes LNG by circulating the cooling liquid in the LNG vaporizer to produce NG (Natural Gas) and supply it to the demand place, and the refrigerant liquid including the cold heat generated in the vaporization process is heat exchanged at 5 ° C or less in the heat exchanger It relates to a cooling system for a data center server using LNG cold heat that is sent to a data center to cool the server.

In general, LNG (Liquefied Natural Gas) is a colorless, odorless, and transparent ultra-low temperature (-162 ° C) liquefied gas that is reduced to 1/600 in volume by cooling natural gas from production areas for transportation and storage. It is transported to the LNG reception base and stored in a specially designed LNG storage tank, and the stored LNG is vaporized in an LNG vaporizer for supply and supplied to the customer. LNG has a total of 200 Kcal of cold energy per 1 kg, and a vaporization process is required to supply the gas to consumers.

There are three main LNG vaporization processes in the existing LNG receiving base: a method of inflowing seawater from the sea and heating it using the heat of seawater, a method of burning natural gas and vaporizing LNG using the combustion heat, and a method of vaporizing LNG using the heat of the air There is a way to vaporize using .

As a conventional example, a method of introducing seawater from the sea and heating it using the heat of the seawater will be described in more detail through drawings.

As shown in FIG. 1, when LNG, which is -162 ° C. liquefied gas stored in an LNG tank from an LNG carrier, is supplied by the high-pressure pump 1, it is vaporized to be sent to each customer through a seawater vaporizer 10.

In the seawater vaporizer (10), when LNG passes through the heat pipe, seawater (S) is supplied through the pipe (P1) and sprayed, and the LNG is vaporized and sent to the consumer (20) through the pipe (11) in the NG state. will lose

At this time, the seawater (S) that has passed through the seawater vaporizer (10) is discarded back to the sea with seawater through the pipe (P2) in a state where heat is deprived.

However, since the temperature of seawater is as low as 5° C. or lower in the winter season, the performance of the seawater vaporizer 10 deteriorates, resulting in a decrease in the vaporization efficiency of LNG in the seawater vaporizer 10.

As described above, in the winter season, the temperature of seawater often drops below 5 ° C., so it is natural that the amount of LNG vaporization is significantly reduced or the efficiency is significantly reduced even if LNG vaporization is achieved.

In order to solve the above problems, a gas combustion vaporizer 30 is provided to increase the vaporization performance of LNG. When this passes, the LNG is heated and vaporized by the flame of the gas burner 31, and the heated LNG is combined with the vaporized NG (Natural Gas) through the seawater vaporizer 10 to supply the customer 20 to be sent to

However, since the conventional LNG vaporization process system necessarily uses the gas combustion vaporizer 30 to compensate for the deterioration in the vaporization efficiency of the seawater vaporizer 10 in winter, the temperature of the seawater decreases as the temperature drops. Since it decreases in proportion to it, the proportion of use of the gas combustion type vaporizer 30 increases accordingly, and the amount of gas used in the winter season significantly increases compared to the summer season. Accordingly, there are problems in that the amount of gas burner 31 increases and consumption of fuel (LNG) of the burner increases, resulting in a huge cost burden and an increase in greenhouse gases.

In addition, a server in a data center is operated to control it. Conventionally, a separate cooling system is provided to cool the server, resulting in excessive maintenance costs.

Looking at the characteristics of the prior art of the vaporization method as described above, in the vaporization process using seawater, a large amount of seawater is introduced into the seawater pump, and as the seawater falls from the top of the LNG vaporizer, the LNG at -162 ° C flowing inside the pipe of the LNG vaporizer is converted to 0 ° C. of natural gas gas, and the temperature of the seawater is lowered by about 5 to 7 ° C and discharged into the sea. While the advantage of using seawater is that it uses a large amount of natural energy, by releasing low-temperature seawater, the temperature of coastal seawater is lowered, causing a problem of changing the marine environment.

In addition, as the servers in the data center are cooled separately by a separate cooling method, a serious problem such as double maintenance cost is caused.

Therefore, in recent years, the refrigerant liquid in the vaporizer is used to cool the server in the data center simply and easily by using the refrigerant liquid exchanged through the heat exchanger without causing a problem with environmental change, and the cooled heat is guided to the vaporizer to improve vaporization efficiency and server There is a need for a technology to increase the cooling efficiency.

The present invention was invented to solve the above-mentioned conventional problems, and the main purpose of the present invention is to configure a vaporizer and a heat exchanger in a way that continuously circulates through a pipe, and then mix a glycerin compound, alcohol and water inside the pipe It is characterized by filling the cooling liquid to easily vaporize the LNG induced by the high-pressure pump.

Another object of the present invention is to connect the server of the data center and the heat exchanger by a pipe, so that the refrigerant supplied from the vaporizer is exchanged by the heat exchanger and circulated to the server, thereby simply and easily cooling the server using the refrigerant of the vaporizer Its characteristic is to significantly reduce server cooling maintenance costs.

Another object of the present invention is that the refrigerant of the vaporizer is designed to easily and easily cool the server in the heat exchanger, and the heat cooled by the server is supplied to the vaporizer to create an effect that can promote the vaporization of LNG. .

The present invention that can achieve the above object is as follows. That is, the cooling system of a data center server using LNG cold heat according to the present invention supplies cryogenic liquefied gas in an LNG tank to an LNG vaporizer by a high-pressure pump, vaporizes it, and then vaporizes the vaporized NG (Natural Gas) to the customer. In the LNG vaporization system capable of supplying, a supply pipe and a recovery pipe capable of circulating a refrigerant liquid in the LNG vaporizer, a heat exchanger capable of heat-exchanging the ends of the supply pipe and the recovery pipe, and the other end of the heat exchanger It consists of a configuration including a cooling pipe installed to supply the heat-exchanged gas to the server, and a heating pipe for supplying the heat recovered after cooling the server to the heat exchanger.

The refrigerant liquid is preferably used by diluting a glycerin compound, alcohol, and water at a constant ratio to maintain a temperature capable of vaporizing LNG.

It is configured by further installing a pump capable of forcibly circulating the refrigerant liquid at one point of the supply pipe.

The cooling pipe is configured by further installing a blower to forcibly circulate the gas transported to the server.

The effect of the cooling system of the data center server using LNG cold heat according to the present invention will be described as follows.

First, the vaporizer and the heat exchanger are continuously circulated through the pipe by filling the inside of the pipe with a cooling liquid containing a mixture of glycerin compound, alcohol and water, evaporating the LNG induced by the high-pressure pump while circulating with the refrigerant liquid. This is to create the effect of saving the natural environment by preventing cold heat from leaking to the outside.

Second, as the server of the data center is connected to the heat exchanger by the hot pipe inside the heat exchanger, and the refrigerant supplied from the vaporizer is exchanged by the heat exchanger and circulated to the server, the server is cooled simply and easily using the refrigerant of the vaporizer, and the heat pipe By recovering the exchanged cold heat after cooling by the cold heat pipe to be interlocked with the vaporizer, the effect of significantly reducing the server cooling maintenance cost is created.

Third, the refrigerant of the vaporizer is heat exchanged in the heat exchanger to easily and easily cool the server, and the heat cooled by the server is supplied to the vaporizer to create an effect that can promote the vaporization of LNG.

1 is a schematic diagram illustrating a conventional LNG vaporization process system.
2 is a schematic diagram of an LNG vaporization process system to which the present invention is applied.

Hereinafter, a preferred embodiment of the present invention will be described in detail based on the accompanying drawings.

2 is a diagram schematically showing an LNG vaporization process system to which the present invention is applied.

As shown in the drawing, the colorless and odorless ultra-low temperature (-162 ° C) liquefied gas filled inside the LPG tank 100 is forcibly supplied to the LPG vaporizer 200 by the high pressure pump 101 to supply the vaporized NG to the demand place ( 300), the supply pipe 400 and the recovery pipe 400' are installed in the LPG vaporizer 200, and the heat exchanger ( 500) is configured.

At this time, the supply pipe 400 and the recovery pipe 400' are filled with refrigerant liquid, and a pump 401 is installed at one point of the supply pipe 400 to forcefully transport the refrigerant liquid.

The refrigerant liquid is used by diluting a glycerin compound, alcohol, and water at a constant ratio to maintain a temperature capable of vaporizing LNG.

In addition, a cooling pipe 600 for supplying the heat-exchanged gas to the server 700 is installed on the other side of the heat exchanger 500, and the heat recovered after cooling the server 700 is transferred to the heat exchanger 500. It is configured by installing a heating pipe 600' for supplying.

At this time, it is preferable to install a blower 601 at one point of the cooling pipe 600 so that gas flowing inside the cooling pipe 600 and the heating pipe 600' can be forcibly circulated. is to connect and connect a plurality of cooling pipes 600 and heating pipes 600' in parallel when cooling one or more.

The cooling system of the server 700 of the data center 800 using the cold heat of LNG according to the present invention configured as described above pumps the ultra-low temperature LNG of the LNG tank 100 due to the operation of the high-pressure pump 101 when the LNG vaporizes first, thereby increasing the LPG vaporizer. When sent to 200, the refrigerant liquid filled in the supply pipe 400 and the recovery pipe 400' installed to be connected to the LPG vaporizer 200 and the heat exchanger 500 is forcibly transported by the pump 401 at a cryogenic temperature. By vaporizing the LNG, the NG is supplied to the consumer 300.

At this time, the cold heat vaporized by the LNG by the refrigerant liquid is heat exchanged with the heat of the server 700 described later in the heat exchanger 500, and continuously circulates to vaporize the ultra-low temperature LNG so that NG can be continuously supplied to the customer 300. there will be

In addition, the refrigerant liquid evaporated while circulating through the supply pipe 400 and the return pipe 400' emits the refrigerant in the heat exchanger 500, and the cooled gas is transferred to the server 700 of the data center 800 through the cooling pipe. After dissipating heat by supplying it through 600, the hot air that has been dissipated heats the cooling fluid while continuously circulating and being supplied to the heat exchanger 500 through the heating pipe 600'.

At this time, a blower 601 is installed in the cooling pipe 600 to forcibly blow the cold gas exchanged in the heat exchanger 500 to dissipate heat from the server 700, and the server 700 uses the discarded cold heat. Since heat is dissipated, it is possible to significantly reduce maintenance costs as well as to protect the natural environment by not adopting a separate heat dissipation means.

Although specific embodiments of the present invention have been described in detail above, the present invention is not limited thereto, and various modifications can be made by those skilled in the art to which the present invention belongs. Variations are included within the scope of the present invention.

100: LNG tank 101: high pressure pump
200: LPG vaporizer 300: Demand
400: supply pipe 400': return pipe
401: pump
500: heat exchanger
600: cooling pipe 600': heating pipe
601: blower
700: server 800: data center

Claims (4)

In the LNG vaporization system that supplies the cryogenic liquefied gas in the LNG tank to the LNG vaporizer by the high-pressure pump to vaporize it and then supply the vaporized NG (Natural Gas) to the customer,
A supply pipe and a recovery pipe capable of circulating liquid refrigerant in the LNG vaporizer, a heat exchanger capable of heat-exchanging ends of the supply pipe and recovery pipe, and a heat exchanger installed at the other end of the heat exchanger to supply the heat-exchanged gas to the server. A cooling pipe and a heating pipe for supplying heat recovered after cooling the server to a heat exchanger,
The refrigerant liquid including the cold heat generated in the vaporization process is heat-exchanged at 5℃ or less in the heat exchanger and sent to the data center to cool the server.
The refrigerant liquid dilutes the glycerin compound, alcohol and water at a constant rate to maintain a temperature capable of vaporizing LNG,
A pump capable of forcibly circulating the refrigerant liquid is further installed at one point of the supply pipe,
The cooling system of the data center server using LNG cold heat, characterized in that the cooling pipe is configured by further installing a blower to forcibly circulate the gas transported to the server. delete delete delete

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