KR102473595B1 - Cold water and cold air generator - Google Patents

Abstract

The present invention provides a cold water and cold air generator comprising: a first heat exchanger; a second heat exchanger installed downstream of the first heat exchanger; an air flow line through which air flows through the first heat exchanger and the second heat exchanger; a water flow line through which water flows through the first heat exchanger; a first cryogenic flow line provided in the first heat exchanger and through which a cryogenic fluid having a lower temperature than air and water flowing through the air flow line and the water flow line flows; and a second cryogenic flow line provided in the second heat exchanger and through which the cryogenic fluid passing through the first cryogenic flow line flows. According to the cold water and cold air generator of the present invention, by providing the first cryogenic flow line through which a cryogenic fluid having a lower temperature than air and water flows in the first heat exchanger flowing through the air flow line and the water flow line, all water and air from the first heat exchanger are cooled and supplied to a data center, thereby reducing unnecessary facility maintenance costs and energy loss for cooling air and water on the side of the data center.

Description

Cold water and cold air generator {Cold water and cold air generator}

The present invention relates to a cold water and cold air generator, and more particularly, to a cold water and cold air generator that generates air and water through a heat exchanger.

Servers, network equipment, and enterprise equipment installed in data centers generate a large amount of heat. Therefore, data centers that operate these equipment operate facilities for cooling heat.

In order to cool the heat of the data center, cold air and water must be supplied to each equipment. In general, for this purpose, cold water and cold air are generated from a heat exchanger that cools water and air, respectively, and supplied to the heat source of the data center. have.

However, in this case, since each heat exchanger for generating water and air is provided and installed, the cost of maintaining the facility increases.

In addition, since separate devices for cooling air and water are installed separately, the cost of equipment and energy consumption increases accordingly.

Korean Patent Registration No. 10-1821929 (Title of Invention: Rack Mount Server Cooling System for Data Center)

The present invention has been created to solve the above problems, and an object of the present invention is to provide a cold water and cold air generator that cools water and air supplied to a data center through a single heat exchanger.

The present invention, a first heat exchanger; a second heat exchanger installed downstream of the first heat exchanger; an air flow line through which air flows through the first heat exchanger and the second heat exchanger; a water flow line through which water flows through the first heat exchanger; a first cryogenic flow line provided in the first heat exchanger and through which cryogenic fluid having a lower temperature than air and water flowing through the air flow line and the water flow line flows; and a second cryogenic flow line provided in the second heat exchanger and through which the cryogenic fluid passing through the first cryogenic flow line flows.

The first cryogenic flow line includes a first line provided on an upstream side of the first heat exchanger, a second line branched from the first line and provided adjacent to the air flow line, and A third line branched from the first line to the opposite side of the second line and provided adjacent to the water flow line, a fourth line extending downstream from the second line, and a third line extending downstream from the third line. Contains 5 lines.

The first cryogenic flow line is branched at a connection between the second line and the fourth line, and a sixth line through which the air supplied through the air flow line passes, and the third and fifth lines A seventh line branched from the connection portion of, connected to the sixth line, and through which the water supplied through the water flow line passes across, provided between the sixth line and the seventh line, It further includes an eighth line connected to the fourth line and the fifth line and extending downstream, and a ninth line extending downstream from a portion where the fourth, fifth, and eighth lines meet.

It further includes an on-off valve provided in the first cryogenic flow line, wherein the on-off valve includes: a first valve provided at a portion where the first line, the second line, and the third line are connected to each other; A second valve and a third valve spaced apart from the first valve and provided in the fourth and fifth lines, respectively, and a fourth valve and a fifth valve respectively disposed in the sixth line and the seventh line; and a sixth valve provided in the eighth line.

In the 1-1 mode, the first valve closes the third line and connects the first line and the second line to each other, the second valve closes the fourth line, The fourth valve opens the sixth line, the fifth valve closes the seventh line, and the sixth valve opens the eighth line, and the cryogenic fluid introduced into the first line is discharged to the ninth line via the second line and the sixth line and the eighth line.

In the 1-2 mode, the first valve closes the second line and connects the first line and the third line to each other, the third valve closes the fifth line, The fourth valve closes the sixth line, the fifth valve opens the seventh line, and the sixth valve opens the eighth line, and the cryogenic fluid introduced into the first line is discharged to the ninth line via the eighth line through the third line and the seventh line.

In the second mode, the first valve closes the third line and connects the first line and the second line to each other, the second valve closes the fourth line, and The valve opens the sixth line, the fifth valve opens the seventh line, and the sixth valve closes the eighth line, and the cryogenic fluid introduced into the first line, The second line, the sixth line, and the seventh line are discharged to the ninth line via the fifth line.

In the third mode, the first valve closes the second line and connects the first line and the third line to each other, the third valve closes the fifth line, and the fourth The valve opens the sixth line, the fifth valve opens the seventh line, and the sixth valve closes the eighth line, and the cryogenic fluid introduced into the first line, The third line, the seventh line, the sixth line, and the fourth line are discharged to the ninth line.

The first cryogenic flow line further includes a tenth line connected between the first line and the eighth line.

In the 4-1 mode, the first valve connects the first line and the tenth line, closes the second line and the third line, and the second valve opens the fourth line. The fourth valve opens the sixth line, the fifth valve closes the seventh line, and the sixth valve closes the eighth line and flows into the first line. The cryogenic fluid is discharged through the 10th line and the 6th line to the 9th line via the 4th line.

In the 4-2 mode, the first valve connects the first line and the tenth line, closes the second line and the third line, and the fourth valve closes the sixth line. make it,

The fifth valve opens the seventh line, and the sixth valve closes the eighth line, and the cryogenic fluid introduced into the first line flows through the tenth line, the seventh line, and the It is discharged to the ninth line through the fifth line.

In a fifth mode, the first valve connects the first line and the tenth line, closes the second line and the third line, and the fourth valve closes the sixth line; The fifth valve closes the seventh line, the sixth valve opens the eighth line, and the cryogenic fluid introduced into the first line passes through the eighth line through the tenth line. and is discharged through the ninth line.

According to the cold water and cold air generator according to the present invention, the first cryogenic flow line through which the cryogenic fluid having a lower temperature than air and water flows is provided in the first heat exchanger flowing through the air flow line and the water flow line, thereby exchanging the first heat. All water and air from the air are cooled and supplied to the data center, thereby reducing unnecessary facility maintenance costs and energy loss for cooling air and water on the data center side.

1 is a view showing a cold water and cold air generator according to the present invention.
FIG. 2 is a detailed view of a first cryogenic flow line shown in FIG. 1 as a first embodiment of the present invention.
FIG. 3 is a diagram showing the flow of cryogenic fluid in the 1-1 mode in FIG. 2 .
FIG. 4 is a view showing the flow of cryogenic fluid in the first-second mode in FIG. 2 .
FIG. 5 is a view showing the flow of cryogenic fluid in the second mode in FIG. 2 .
FIG. 6 is a view showing the flow of cryogenic fluid in the third mode in FIG. 2 .
FIG. 7 is a detailed view of a first cryogenic flow line shown in FIG. 1 as a second embodiment of the present invention.
FIG. 8 is a view showing the flow of cryogenic fluid in the 4-1 mode in FIG. 7 .
FIG. 9 is a view showing the flow of cryogenic fluid in the 4-2 mode in FIG. 7 .
FIG. 10 is a view showing the flow of cryogenic fluid in the fifth mode in FIG. 7 .

Although the present invention has been described with reference to the embodiments shown in the drawings, this is only exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. Therefore, the true technical scope of protection of the present invention should be determined by the technical spirit of the appended claims.

1 to 6, the cold water and cold air generator 100 according to the present invention includes a first heat exchanger 110, a second heat exchanger 120, an air flow line 130, a water flow line 140, A first cryogenic flow line 150 and a second cryogenic flow line 160 are included.

The first heat exchanger 110 allows heat exchange between incoming air and water.

The second heat exchanger 120 is installed to be connected to a downstream side of the first heat exchanger.

Here, the second heat exchanger 120 supplies air to a data center (not shown) through the air flow line 130 described below.

The air flow line 130 passes through the first heat exchanger 110 and the second heat exchanger 120, and air flows therethrough.

The water flow line 140 passes through the first heat exchanger 110 and allows water to flow and be supplied to the data center.

The first cryogenic flow line 150 is provided in the first heat exchanger 110, and the cryogenic fluid having a lower temperature than air and water flowing through the air flow line 130 and the water flow line 140 are allowed to flow adjacently so that air and water are cooled.

In this case, the cryogenic fluid may be liquefied natural gas, liquefied petroleum gas, or liquefied natural gas, but is not necessarily limited thereto.

And, the first cryogenic flow line 150 is branched from the first line 151 provided on the upstream side of the first heat exchanger 110 and is branched from the first line 151 to flow the air. A second line 152 provided to be adjacent to the line 130, and a second line 152 branched from the first line 151 to the opposite side of the second line 152 and provided adjacent to the water flow line 140. It includes three lines 153, a fourth line 154 extending downstream from the second line 152, and a fifth line 155 extending downstream from the third line 153.

At this time, the first cryogenic flow line 150 diverges from the connection portion of the second line 152 and the fourth line 154, and the air supplied through the air flow line 130 passes through it. The sixth line 156, which is branched from the connection portion of the third line 153 and the fifth line 155, is connected to the sixth line 156, and the water flow line 140 It is provided between the seventh line 157 through which the water supplied through passes across and the sixth line 156 and the seventh line 157, and the fourth line 154 and the fifth line ( 155) and the eighth line 158 extending downstream, and the ninth line extending downstream from the point where the fourth line 154, the fifth line 155, and the eighth line 158 meet. It further includes line 159.

The second cryogenic flow line 160 is provided in the second heat exchanger 120, and the cryogenic fluid passing through the first cryogenic flow line 150 flows.

Here, the second cryogenic flow line 160 allows the air cooled through the air flow line 130 to be dehumidified and supplied to the data center when the air passes through the second heat exchanger 120. .

Meanwhile, the cold water and cold air generator 100 according to the present invention further includes an on/off valve 170 provided in the first cryogenic flow line 150, and the on/off valve 170 includes the first line 151 ) and the second line 152 and the third line 153 are connected to each other, the first valve 171, and the fourth line 154 spaced apart from the first valve 171 And the second valve 172 and the third valve 173 respectively provided in the fifth line 155, and the fourth valve respectively disposed in the sixth line 156 and the seventh line 157 ( 174), a fifth valve 175, and a sixth valve 176 provided in the eighth line 158.

Hereinafter, with reference to FIGS. 2 to 6 , water and air are cooled in the first heat exchanger 110 of the cold water and cold air generator 100 according to the first embodiment of the present invention and supplied to the data center. The flow of the cryogenic fluid for each mode of the first cryogenic flow line 150 will be described in more detail.

Referring to FIG. 3, in the 1-1 mode, the first valve 171 closes the third line 153, connects the first line 151 and the second line 152, , The second valve 172 closes the fourth line 154, the fourth valve 174 opens the sixth line 156, and the fifth valve 175, The seventh line 157 is closed, and the sixth valve 176 opens the eighth line 158.

At this time, the cryogenic fluid introduced into the first line 151 is discharged to the ninth line 159 via the second line 152 and the sixth line 156 and the eighth line 158. Let it be.

The 1-1 mode is a mode in which only cold air is generated, and the air supplied to the inside of the first heat exchanger 110 is cooled by exchanging heat with the cryogenic fluid flowing along the sixth line 156 .

Referring to FIG. 4, in the 1-2 mode, the first valve 171 closes the second line 152 and connects the first line 151 and the third line 153 to each other, , The third valve 173 closes the fifth line 155, the fourth valve 174 closes the sixth line 156, and the fifth valve 175, The seventh line 157 is opened, and the sixth valve 176 opens the eighth line 158.

At this time, the cryogenic fluid introduced into the first line 151 is discharged to the ninth line 159 via the third line 153 and the seventh line 157 and the eighth line 158. Let it be.

The 1-2 mode is a mode in which only cold water is generated, and the water supplied into the first heat exchanger 110 is cooled by exchanging heat with the cryogenic fluid flowing along the seventh line 157.

Referring to FIG. 5, in the second mode, the first valve 171 closes the third line 153, connects the first line 151 and the second line 152, and The second valve 172 closes the fourth line 154, the fourth valve 174 opens the sixth line 156, and the fifth valve 175 The seventh line 157 is opened, the sixth valve 176 closes the eighth line 158, and the cryogenic fluid introduced into the first line 151 is transferred to the second line 152 , discharged to the ninth line 159 via the fifth line 155 through the sixth line 156 and the seventh line 157.

At this time, the cryogenic fluid introduced into the first line 151 passes through the second line 152, the sixth line 156 and the seventh line 157, and then the fifth line 155. It is discharged through the ninth line (159).

Here, the cryogenic fluid comes in contact with the air flow line 130 to first cool the air, and then comes in contact with the water flow line 140 to cool the water.

The second mode generates both cold water and cold air, and the water and air supplied to the inside of the first heat exchanger 110 exchange heat with the cryogenic fluid flowing along the first cryogenic flow line 150, It cools down. At this time, the cryogenic fluid of the first cryogenic flow line 150 first flows into the sixth line 156 and then flows into the seventh line 157 . Therefore, in the second mode, the cryogenic fluid in the sixth line 156 and the air first exchange heat to cool the air, and then the cryogenic fluid in the seventh line 157 and water exchange heat to cool the water. That is, the second mode may be a mode in which the cooling load applied to the air is greater than the cooling load applied to the water.

Referring to FIG. 6, in the third mode, the first valve 171 closes the second line 152, connects the first line 151 and the third line 153, and The third valve 173 closes the fifth line 155, the fourth valve 174 opens the sixth line 156, and the fifth valve 175 The seventh line 157 is opened, and the sixth valve 176 closes the eighth line 158.

At this time, the cryogenic fluid introduced into the first line 151 passes through the third line 153, the seventh line 157, the sixth line 156, the fourth line 154, and then the third line 154. It is discharged in 9 lines (159).

Here, the cryogenic fluid comes into contact with the water flow line 140 to cool water first, and then comes into contact with the air flow line 130 to cool the air.

The third mode is a mode in which both cold water and cold air are generated, and the water and air supplied to the inside of the first heat exchanger 110 exchange heat with the cryogenic fluid flowing along the first cryogenic flow line 150, It cools down. At this time, the cryogenic fluid of the first cryogenic flow line 150 first flows into the seventh line 157 and then flows into the sixth line 156 . Accordingly, in the third mode, the cryogenic fluid in the seventh line 157 and the water first exchange heat to cool the water, and then the cryogenic fluid in the sixth line 156 and the air exchange heat to cool the air. That is, the third mode may be a mode in which the cooling load applied to water is greater than the cooling load applied to air.

According to the cold water and cold air generating device 100 according to the first embodiment of the present invention, when only cold air or cold water is required, the 1-1 mode or the 1-2 mode is operated, and cold water and cold air are simultaneously generated. If you want to operate the second mode or the third mode, in particular, if you want to differentiate the cooling load applied to either cold water or cold air from the other, use either the second mode or the third mode By selecting and implementing, the operator can select and operate a mode suitable for temperature control of the data center, and thus, the temperature of the data center can be optimally controlled.

Hereinafter, referring to FIGS. 7 to 10, in the cold water and cold air generator 100 according to the second embodiment of the present invention, water and air are cooled in the first heat exchanger 110 and supplied to the data center. The shape of each mode of the first cryogenic flow line 150 will be described in more detail.

At this time, the first cryogenic flow line 150 further includes a tenth line 269 connected between the first line 151 and the eighth line 158.

8, in the 4-1 mode, the first valve 171 connects the first line 151 and the tenth line 269, and the second line 152 and the third The line 153 is closed, the second valve 172 opens the fourth line 154, the fourth valve 174 opens the sixth line 156, and the The fifth valve 175 closes the seventh line 157, and the sixth valve 176 closes the eighth line 158.

At this time, the cryogenic fluid introduced into the first line 151 is discharged to the ninth line 159 via the fourth line 154 through the tenth line 269 and the sixth line 156. Let it be.

The 4-1 mode performs substantially the same function as the 1-1 mode. That is, the 4-1 mode is a mode that generates only cold air, and the air supplied into the first heat exchanger 110 is cooled by exchanging heat with the cryogenic fluid flowing along the sixth line 156.

Referring to FIG. 9, in the 4-2 mode, the first valve 171 of the first cryogenic flow line 150 connects the first line 151 and the tenth line 269, The second line 152 and the third line 153 are closed, the fourth valve 174 closes the sixth line 156, and the fifth valve 175 closes the seventh The line 157 is opened, and the sixth valve 176 closes the eighth line 158.

At this time, the cryogenic fluid introduced into the first line 151 is discharged to the ninth line 159 via the tenth line 269, the seventh line 157, and the fifth line 155. Let it be.

The 4-2 mode performs substantially the same function as the 1-2 mode. That is, the 4-2 mode generates only cold water, and the liquid (floating water) supplied to the inside of the first heat exchanger 110 exchanges heat with the cryogenic fluid flowing along the seventh line 157. it is cooled

Referring to FIG. 10, in the fifth mode, the first valve 171 of the first cryogenic flow line 150 connects the first line 151 and the tenth line 269, The second line 152 and the third line 153 are closed, the fourth valve 174 closes the sixth line 156, and the fifth valve 175 closes the seventh line ( 157) is closed, and the sixth valve 176 opens the eighth line 158.

At this time, the cryogenic fluid introduced into the first line 151 is discharged to the ninth line 159 via the eighth line 158 through the tenth line 269 .

The fifth mode is a mode for performing a dehumidification function. In the fifth mode, moisture present in the air is removed through the first heat exchanger 110 and the second heat exchanger 120 . At this time, the first heat exchanger 110 assists in dehumidifying, and most of the moisture in the air is still removed in the second heat exchanger 120.

100: water chiller 110: first heat exchanger
120: second heat exchanger 130: air flow line
140: water flow line 150: first cryogenic flow line
151: first line 152: second line
153: 3rd line 154: 4th line
155: 5th line 156: 6th line
157: 7th line 158: 8th line
159: 9th line 160: 2nd cryogenic flow line
170: open/close valve 171: first valve
172: second valve 173: third valve
174: 4th valve 175: 5th valve
176: 6th valve 269: 10th line

Claims (12)

a first heat exchanger;
a second heat exchanger installed downstream of the first heat exchanger;
an air flow line through which air flows through the first heat exchanger and the second heat exchanger;
a water flow line through which water flows through the first heat exchanger;
a first cryogenic flow line provided in the first heat exchanger and through which cryogenic fluid having a lower temperature than air and water flowing through the air flow line and the water flow line flows; and
A second cryogenic flow line provided in the second heat exchanger and through which the cryogenic fluid passing through the first cryogenic flow line flows;
The first cryogenic flow line,
A first line provided on an upstream side of the first heat exchanger;
A second line branched from the first line and provided adjacent to the air flow line;
A third line branched from the first line to the opposite side of the second line and provided adjacent to the water flow line;
A fourth line extending downstream from the second line;
Cold water and cold air generator comprising a fifth line extending downstream from the third line.
delete The method of claim 1,
The first cryogenic flow line,
A sixth line branched at a connection between the second and fourth lines and through which the air supplied through the air flow line passes;
A seventh line branched from the connection portion of the third and fifth lines, connected to the sixth line, and through which water supplied through the water flow line passes across;
An eighth line provided between the sixth line and the seventh line, connected to the fourth line and the fifth line and extending downstream;
The cold water and cold air generator further comprising a ninth line extending downstream from a portion where the fourth line, fifth line, and eighth line meet. The method of claim 3,
Further comprising an on-off valve provided in the first cryogenic flow line,
The on-off valve is
A first valve provided at a portion where the first line, the second line, and the third line are connected to each other;
A second valve and a third valve spaced apart from the first valve and provided in the fourth line and the fifth line, respectively;
A fourth valve and a fifth valve disposed in the sixth line and the seventh line, respectively;
Cold water and cold air generating device including a sixth valve provided in the eighth line. The method of claim 4,
In the 1-1 mode,
The first valve closes the third line and connects the first line and the second line to each other,
The second valve closes the fourth line,
The fourth valve opens the sixth line,
The fifth valve closes the seventh line,
The sixth valve opens the eighth line,
The cryogenic fluid introduced into the first line is discharged to the ninth line via the second line, the sixth line, and the eighth line. The method of claim 4,
In the 1-2 mode,
The first valve closes the second line and connects the first line and the third line to each other,
The third valve closes the fifth line,
The fourth valve closes the sixth line,
The fifth valve opens the seventh line,
The sixth valve opens the eighth line,
The cryogenic fluid introduced into the first line is discharged to the ninth line via the third line and the seventh line and the eighth line. The method of claim 4,
In the second mode,
The first valve closes the third line and connects the first line and the second line to each other,
The second valve closes the fourth line,
The fourth valve opens the sixth line,
The fifth valve opens the seventh line,
The sixth valve closes the eighth line,
The cryogenic fluid introduced into the first line is discharged to the ninth line via the second line, the sixth line, and the seventh line through the fifth line. The method of claim 4,
In the third mode,
The first valve closes the second line and connects the first line and the third line to each other,
The third valve closes the fifth line,
The fourth valve opens the sixth line,
The fifth valve opens the seventh line,
The sixth valve closes the eighth line,
The cryogenic fluid introduced into the first line is discharged to the ninth line through the third line, the seventh line, the sixth line, and the fourth line. The method of claim 4,
The first cryogenic flow line further comprises a tenth line connected between the first line and the eighth line. The method of claim 9,
In the 4-1 mode,
The first valve connects the first line and the tenth line, closes the second line and the third line,
The second valve opens the fourth line,
The fourth valve opens the sixth line,
The fifth valve closes the seventh line,
The sixth valve closes the eighth line,
The cryogenic fluid introduced into the first line is discharged to the ninth line via the fourth line through the tenth line and the sixth line. The method of claim 9,
In the 4-2 mode,
The first valve connects the first line and the tenth line, closes the second line and the third line,
The fourth valve closes the sixth line,
The fifth valve opens the seventh line,
The sixth valve closes the eighth line,
The cryogenic fluid introduced into the first line is discharged to the ninth line via the tenth line, the seventh line, and the fifth line. The method of claim 9,
In the fifth mode,
The first valve connects the first line and the tenth line, closes the second line and the third line,
The fourth valve closes the sixth line,
The fifth valve closes the seventh line,
The sixth valve opens the eighth line,
The cryogenic fluid introduced into the first line is discharged to the ninth line via the eighth line through the tenth line.

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