JP7238331B2 - Immersion tank liquid level adjustment device - Google Patents

Description

The present invention relates to a liquid level adjustment device for a liquid immersion tank.

In recent years, the development of a liquid immersion cooling system in which electronic devices such as servers installed in data centers are immersed in a liquid coolant has been developed, and liquid immersion tanks used in the liquid immersion cooling system have also been proposed (for example, , see Patent Document 1).

Japanese Patent Application Laid-Open No. 2018-10980

Incidentally, electronic devices cooled by the liquid immersion cooling method may be immersed in or removed from the liquid immersion bath as required for increasing or decreasing the number of devices or for maintenance work. When the electronic device is moved in and out of the liquid immersion tank, the liquid level of the coolant in the liquid immersion tank changes accordingly. When the liquid level of the coolant in the liquid immersion tank becomes low, other immersed electronic devices are exposed from the coolant, and the exposed electronic devices are not properly cooled. On the other hand, when the liquid level of the refrigerant in the liquid immersion tank becomes high, it is conceivable that the refrigerant overflows from the liquid immersion tank. Patent Document 1 does not solve these inconveniences.

In one aspect, an object of the invention disclosed in this specification is to appropriately adjust the liquid level of the coolant in the liquid immersion bath.

In one aspect, a variable volume member capable of expanding and contracting in volume while being installed in a coolant stored in a liquid immersion tank, a valve section for adjusting the amount of air in the variable volume member, and the variable volume Based on the observation results of an air introduction section that introduces air into the member, a liquid level observation section that observes the liquid level height of the refrigerant stored in the liquid immersion tank, and the liquid level observation section a control unit that controls the valve unit and the air introduction unit and adjusts the liquid level height.

The present invention can appropriately adjust the liquid level of the coolant in the liquid immersion tank.

FIG. 1 is a configuration diagram showing an outline of a liquid immersion cooling system in which a liquid level adjustment device for a liquid immersion bath according to an embodiment is incorporated. FIG. 2A is an explanatory diagram showing how the volume variable member expands, and FIG. 2B is an explanatory diagram showing how the volume variable member contracts. FIG. 3 is a flow chart showing an example of the operation of the liquid level adjustment device of the embodiment.

BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings. However, in the drawings, the dimensions, ratios, etc. of each part may not be illustrated so as to completely match the actual ones. In addition, depending on the drawings, for the convenience of explanation, there are cases where components that actually exist are omitted, or dimensions are drawn with exaggeration.

First, with reference to FIG. 1, an outline of a liquid immersion cooling system 1 in which a liquid level adjustment device (hereinafter simply referred to as “adjustment device”) 50 for an immersion bath according to an embodiment is incorporated will be described. The liquid immersion cooling system 1 includes a liquid immersion tank 2 , a lid 3 for opening and closing an upper opening of the liquid immersion tank 2 , and a coolant 4 stored in the liquid immersion tank 2 . The liquid immersion cooling system 1 also includes a cooling distribution unit (CDU) 30 and an adjustment device 50 .

A vertically extending rail member 5 is provided in the liquid immersion tank 2 . An electronic device 6 to be cooled is installed on the rail member 5 . The electronic device 6 is detachable from the rail member 5 . In this embodiment, a first area AR1, a second area AR2, and a third area AR3 are provided as equipment mounting areas, and rail members 5 are provided in each area so that the electronic equipment 6 can be installed. It's becoming The number of electronic devices 6 can be increased or decreased, and can be removed from the liquid immersion tank 2 during maintenance work. Note that the number of device mounting areas is an example, and is not limited to this.

The coolant 4 in this embodiment has electrical insulation and thermal conductivity. For example, a fluorine-based insulating refrigerant such as Fluorinert (trademark of 3M Company) manufactured by 3M Company can be suitably used as the refrigerant 4 . Fluorinert is an example of the refrigerant 4, and other refrigerants may be used.

The refrigerant circulation device 30 includes a heat exchanger 31 connected to the liquid immersion tank 2 via a first circulation pipe 32a and a second circulation pipe 32b. The refrigerant 4 is sent from the liquid immersion tank 2 to the heat exchanger 31 through the first circulation pipe 32a, cooled by the heat exchanger 31, and then returned to the liquid immersion tank 2 from the heat exchanger 31 through the second circulation pipe 32b. returned. The coolant 4 is thus maintained at a temperature suitable for cooling the electronic device 6 by circulating between the coolant circulation device 30 and the liquid immersion tank 2 .

The adjustment device 50 includes a liquid level observation section 7 , a variable volume member 8 , an introduction valve 9 , an air compressor 11 as an air introduction section, a discharge valve 12 and a control section 14 . Further, the adjustment device 50 includes an open/close sensor 3a1 incorporated in the hinge portion 3a of the lid 3. As shown in FIG.

The liquid surface height observation unit 7 is attached to the upper edge of the side wall of the liquid immersion tank 2, and is slidably mounted on a rod-shaped guide portion 7a extending in the vertical direction. Includes a float 7b that can float on 4s. The liquid level observation unit 7 can detect the liquid level of the refrigerant 4 by detecting the position of the float 7b that moves according to the liquid level.

The variable volume member 8 can expand and contract in volume while being installed in the coolant 4 stored in the liquid immersion tank 2 . When the variable volume member 8 is expanded within the refrigerant 4, the position of the liquid surface 4s of the refrigerant 4 can be raised. On the other hand, when the variable volume member 8 is contracted in the refrigerant 4, the position of the liquid surface 4s of the refrigerant 4 can be lowered. The variable volume member 8 has an expandable and contractible bellows shape.

The variable volume member 8 is installed in the liquid immersion tank 2, and it suffices if its volume is expanded and contracted to adjust the position of the liquid surface 4s of the coolant 4. However, in this embodiment, the liquid immersion tank 2 is designed to be compact. However, from the viewpoint of suppressing the usage amount of the refrigerant 4, they are arranged as follows. That is, the variable volume member 8 is arranged below the installation area of the electronic device 6 in each of the first area AR1, the second area AR2, and the third area AR3. The expandable and bellows-shaped volume variable member 8 is installed so as to expand and contract in the vertical direction of the liquid immersion tank 2 . Thereby, the variable volume member 8 can be expanded and contracted within the range of each region.

In the first area AR1, the second area AR2, and the third area AR3, when the electronic equipment 6 is removed, a space for storing the electronic equipment 6 becomes available. Therefore, by expanding the variable volume member 8 in this empty space, the space inside the liquid immersion tank 2 can be effectively utilized. As a result, the inside of the liquid immersion tank 2 can be designed compactly, the density of the liquid immersion tank 2 can be increased, and the amount of refrigerant 4 used can be reduced. When the electronic device 6 is installed, the variable volume member 8 can be stored under the electronic device 6 in a contracted state, so that it does not interfere with the electronic device 6.例文帳に追加

The variable volume member 8 is made of a waterproof and airtight material. Although the variable volume member 8 of this embodiment is made of vinyl, it may be made of plastic or the like. The variable volume member 8 expands when air is introduced inside, and contracts when the air is discharged from the inside. For this purpose, the adjusting device 50 comprises an inlet pipe 10 and an outlet pipe 13 . An air compressor 11 is arranged in the introduction pipe 10 . The end of the discharge pipe 13 is an open end 13a so that the air can be released to the atmosphere.

The introduction pipe 10 and each volume variable member 8 are connected via an introduction valve 9 so as to control the state of air introduction. Also, the discharge pipe 13 and each volume variable member 8 are connected via a discharge valve 12 so as to control the state of air discharge. The introduction valve 9 and the discharge valve 12 function as valve portions that adjust the amount of air in the volume variable member 8 . Both the introduction valve 9 and the discharge valve 12 are electrically operated valves.

Here, expansion and contraction of the volume variable member 8 will be described with reference to FIGS. 2(A) and 2(B). Referring to FIG. 2A, when the air compressor 11 operates with the introduction valve 9 opened and the discharge valve 12 closed, air is introduced into the variable volume member 8, causing the variable volume member 8 to Inflate. When the variable volume member 8 expands, the position of the liquid surface 4s of the refrigerant 4 rises. When the electronic device 6 is taken out from the liquid immersion bath 2, the liquid level is maintained by performing such an operation, and the other electronic devices 6 are prevented from being exposed from the liquid surface 4s.

On the other hand, referring to FIG. 2B, when the introduction valve 9 is closed and the discharge valve 12 is opened, the air is discharged from the variable volume member 8 and the variable volume member 8 contracts. do. When the variable volume member 8 contracts, the position of the liquid surface 4s of the coolant 4 descends. When the electronic device 6 is newly immersed in the liquid immersion tank 2 , the liquid level is maintained by performing such an operation, and the coolant 4 is prevented from overflowing the liquid immersion tank 2 .

The adjusting device 50 has a control section 14 . The control unit 14 has, as a hardware configuration, for example, an arithmetic circuit having a CPU (Central Processing Unit), a program memory, a data memory, other RAMs (Random Access Memories), ROMs (Read Only Memories), and the like. Mainly equipped with a microcomputer consisting of The control unit 14 is electrically connected to the open/close sensor 3a1, the liquid level observation unit 7, the introduction valve 9, the air compressor 11 and the discharge valve 12, and based on the observation result of the liquid level observation unit 7 , the introduction valve 9 , the air compressor 11 and the discharge valve 12 are controlled. The controller 14 thereby adjusts the liquid level. Note that the control unit 14 of the present embodiment can select which of the plurality of volume variable members 8 to operate. An example of the process of adjusting the liquid level by the adjusting device 50 will be described below with reference to FIG. 3 .

Here, before explaining each step, the state of each volume variable member 8 when the liquid immersion cooling system 1 is in operation will be explained. The variable volume member 8 provided for each of the first area AR1, the second area AR2, and the third area AR3 varies in its expansion/contraction state depending on the installation state of the electronic device 6 in each area. That is, the variable volume member 8 in the area where the electronic equipment 6 is installed is contracted, and the variable volume member 8 in the area where the electronic equipment 6 is taken out is expanded. Further, when the liquid immersion cooling system 1 is in operation, the introduction valve 9 and the discharge valve 12 are closed, and the air compressor 11 is also stopped.

In step S1, the control unit 14 determines whether or not the lid 3 is open based on the detection result of the open/close sensor 3a1. When the control unit 14 determines NO in step S1, the determination in step S1 is performed again. The process of step S1 is repeated until YES is determined in step S1. The open/closed state of the lid 3 is determined considering that the electronic device 6 is put in and taken out of the liquid immersion tank 2 and the liquid surface height adjustment is required when the lid 3 is open. It is what I did. By making the determination in step S1, when the lid 3 is closed and the liquid immersion cooling system 1 is in operation, for example, even if the liquid level changes for a short period of time due to an earthquake or the like, adjustment can be made. Device 50 does not work. If YES is determined in step S1, the process proceeds to step S2.

In step S2, the variable volume member 8 to be operated is selected. For example, when taking out the electronic device 6 from the first area AR1 or immersing the electronic device 6 in the first area AR1, the variable volume member 8 provided in the first area AR1 is selected. That is, the variable volume member 8 provided in the area to which the electronic device 6 is to be put in and taken out is selected. In this embodiment, this selection is made by the operator. For example, the rail member 5 is provided with a sensor for detecting attachment and detachment of the electronic device 6, and the variable volume member 8 to be operated is selected based on the detection result of the sensor. You may do so.

In step S3 following step S2, liquid level control is started, and in step S4, the control unit 14 acquires information about the liquid level from the liquid level observation unit 7. FIG. Then, in step S5, it is determined whether or not the liquid level is higher than a preset upper limit. Here, the upper limit value is the upper limit of the allowable range of the liquid surface 4 s set so that the electronic device 6 installed in the liquid immersion tank 2 is not exposed from the coolant 4 or overflows. When YES is determined in step S5, the process proceeds to step S6. It should be noted that, for example, when the electronic device 6 is newly immersed, the liquid level rises, so it is determined YES in step S5.

At step S6, the discharge valve 12 is opened. As a result, air begins to escape from inside the variable volume member 8 and the variable volume member 8 contracts. In step S7 subsequent to step S6, the control unit 14 again acquires information about the liquid level height from the liquid level observation unit 7, and in step S8, the liquid level height reaches the preset upper limit value. determine whether it is higher than When YES is determined in step S8, the processing from step S7 is repeated. The processes of steps S7 and S8 are continued until NO is determined in step S8, that is, until the liquid level is determined to be equal to or lower than the upper limit.

If NO is determined in step S8, the process proceeds to step S9. At step S9, the discharge valve 12 is closed. After performing the process of step S9, it progresses to step S15. In step S15, similarly to step S1, it is determined whether or not the lid 3 is open based on the detection result of the open/close sensor 3a1. When the control unit 14 determines YES in step S15, it repeats the processing from step S4. As a result, the liquid level can be maintained at a desired position while the electronic device 6 is being loaded and unloaded. When it is determined NO in step S15, that is, when the lid 3 is closed, it is determined that the electronic device 6 has been taken in and out, and the process proceeds to step S16 to stop the control.

On the other hand, when the control unit 14 determines NO in step S5, the process proceeds to step S10. In step S10, it is determined whether or not the liquid level is below the lower limit. Here, the lower limit value is the lower limit of the permissible range of the liquid surface 4 s set so that the electronic device 6 installed in the liquid immersion tank 2 is not exposed from the coolant 4 or overflows. When the control unit 14 determines YES in step S10, the process proceeds to step S11. For example, if the electronic device 6 is taken out, the liquid level will drop, so it is determined YES in step S10.

In step S11, the air compressor 11 is operated and the introduction valve 9 is opened. As a result, air begins to be introduced into the variable volume member 8 and the variable volume member 8 expands. In step S12 subsequent to step S11, the control unit 14 again acquires information about the liquid level height from the liquid level observation unit 7, and in step S13, the liquid level height reaches the preset lower limit value. determine whether it is lower than When YES is determined in step S13, the process from step S12 is repeated. The processes of steps S12 and S13 are continued until NO is determined in step S13, that is, until it is determined that the liquid level is equal to or higher than the lower limit.

If NO is determined in step S13, the process proceeds to step S14. In step S14, the air compressor 11 is stopped and the introduction valve 9 is closed. After performing the process of step S14, it progresses to step S15. Further, even when it is determined as NO in step S10, the processing after step S15 is performed. Since the processing after step S15 is as described above, it is omitted here.

The liquid immersion cooling system 1 of this embodiment includes an adjustment device 50 . As a result, fluctuations in the liquid level of the coolant 4 in the liquid immersion tank 2 due to the number of electronic devices 6 immersed in the liquid immersion tank 2, increase or decrease in the number of electronic devices 6, maintenance work, or the like, due to insertion and removal of the electronic equipment 6 are suppressed. , the liquid level can be maintained within an appropriate range.

The refrigerant 4 generally has a higher specific gravity than water and is expensive. For this reason, it is necessary to reduce the amount of the refrigerant 4 used as much as possible in terms of the load capacity of the place where it is installed and the introduction cost. Therefore, it is desirable to design the liquid level of the coolant 4 in the liquid immersion bath 2 to be as low as possible within the range in which all the electronic devices 6 can be immersed. The adjustment device 50 of the present embodiment can maintain the liquid level within a desired range even when the electronic device 6 is taken in and out. Therefore, there is no need to replenish or discharge the refrigerant each time the work is performed in order to deal with fluctuations in the liquid level due to the insertion and removal of the electronic device 6 . In addition, in order to cope with fluctuations in the liquid level height, the liquid immersion tank 2 is designed to be significantly deeper than the dimensions of the electronic equipment 6, and even if the liquid level position of the coolant 4 fluctuates, the apparatus will not be affected. There is no need to take measures such as filling as much as possible.

Although the preferred embodiments of the present invention have been described in detail above, the present invention is not limited to such specific embodiments, and various modifications, Change is possible.

REFERENCE SIGNS LIST 1 liquid immersion cooling system 2 liquid immersion tank 3 lid 3a hinge 3a1 open/close sensor 4 coolant 4s liquid level 5 rail member 6 electronic device 7 liquid level observation section 7a guide section 7b float 8 volume variable member 9 introduction valve 10 introduction pipe REFERENCE SIGNS LIST 11 air compressor 12 discharge valve 13 discharge pipe 13a open end 14 controller 50 liquid level adjustment device

Claims (4)

a variable volume member capable of expanding and contracting in volume while being installed in a coolant stored in a liquid immersion tank having a plurality of installation areas for electronic devices ;
a valve portion that adjusts the amount of air in the variable volume member;
an air introduction section that introduces air into the variable volume member;
a liquid level observation unit that observes the liquid level of the coolant stored in the liquid immersion tank;
a control unit that controls the valve unit and the air introduction unit based on the observation result of the liquid level observation unit to adjust the liquid level;
with
The variable volume member is arranged under each installation area of the electronic device,
The control unit introduces air through the air introduction unit into the variable volume member arranged in the installation area of the electronic device in which the electronic device taken out from the liquid immersion tank was installed, and controls the variable volume member. expand the volume of
Liquid level adjustment device for liquid immersion bath. 2. The valve part according to claim 1, wherein the valve section includes an introduction valve that opens when air is introduced into the volume variable member, and a discharge valve that opens when air is discharged from the volume variable member. A liquid level adjustment device for the liquid immersion tank described above. 3. The liquid level adjustment device for a liquid immersion tank according to claim 1, wherein the variable volume member has an expandable and contractible bellows shape. An open/close sensor for detecting an open/closed state of a lid of the liquid immersion tank is further provided, and the control unit adjusts the liquid level when the open/close sensor detects the open state of the lid. The liquid level adjustment device for an immersion tank according to any one of claims 1 to 3 .

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