JP7501940B1 - Filter device, cooling system, and method for attaching and detaching a filter - Google Patents

Abstract

[Problem] To provide a filter device, a cooling system, and a method for attaching and detaching a filter that can prevent a decrease in the cooling efficiency of an object to be cooled when a filter is removed. [Solution] The filter device is provided in a pipeline that circulates and supplies a cooling liquid to the object to be cooled, and includes a first pipe and a second pipe that are branched off from the pipeline, a filter provided midway through each of the first pipe and the second pipe, an on-off valve provided upstream and downstream of the filter in each of the first pipe and the second pipe, and an upstream switching mechanism that is provided at a branching point where the pipeline branches off into the first pipe and the second pipe and is capable of selectively closing one of the first pipe and the second pipe. [Selected Figure] Figure 2

Description

This disclosure relates to a filter device, a cooling system, and a method for attaching and detaching a filter.

A cooling system for cooling a computer device or the like uses a coolant that circulates through a pipe to cool the object. In such a cooling system, impurities such as dust contained in the coolant or products generated within the pipe can cause the flow path within the pipe to become clogged.
For this reason, the pipeline is equipped with a filter to collect impurities. Over time, the collected impurities accumulate on the filter. For this reason, the filter can be removed from the pipeline for cleaning or replacement.

For example, Patent Document 1 discloses a configuration in which a filter replacement mechanism is provided in the middle of a circulation pipe that circulates and supplies a cooling liquid to a cooling target. This filter replacement mechanism has a first flow path section and a second flow path section in parallel. The first flow path section and the second flow path section each have a filter and an on-off valve provided on the upstream side and downstream side of the filter. With this configuration, the filter can be removed by closing the on-off valves on the upstream side and downstream side in either the first flow path section or the second flow path section. In addition, by leaving the on-off valves on the upstream side and downstream side in the other of the first flow path section or the second flow path section open, it is possible to continue cooling the cooling target without stopping the circulation of the cooling liquid in the circulation pipe.

JP 2022-45069 A

However, in the configuration disclosed in Patent Document 1, even if the upstream and downstream on-off valves are closed in either the first or second flow path section to remove the filter, the coolant continues to flow up to just before the closed on-off valve. The flowing coolant then hits the closed on-off valve and flows back. The backflowing coolant may then obstruct the flow of coolant in either the first or second flow path section, where the on-off valve is not closed. As a result, the cooling efficiency of the cooling target may decrease when the filter is removed.

The objective of this disclosure is to provide a filter device, a cooling system, and a method for removing and attaching a filter that solves any of the above problems.

A filter device according to one aspect of the present disclosure is a filter device provided in a pipeline that circulates and supplies a cooling liquid to a cooling object, and includes a first pipe and a second pipe that are branched off from the pipeline, a filter provided midway through each of the first pipe and the second pipe, an on-off valve provided upstream and downstream of the filter in each of the first pipe and the second pipe, and an upstream switching mechanism that is provided at a branching point where the pipeline branches off into the first pipe and the second pipe and is capable of selectively closing either the first pipe or the second pipe.

According to the above aspect, it is possible to prevent the cooling efficiency of the cooling object from decreasing when the filter is removed.

FIG. 1 is a diagram illustrating a configuration of a cooling system in a first embodiment of the present disclosure. 1 is a diagram showing a configuration of a filter device in a first embodiment of the present disclosure, and shows a state in which a first pipe is blocked. FIG. 1 is a diagram showing a state in which a second pipe is blocked in a filter device according to a first embodiment of the present disclosure. FIG. 2 is a block diagram showing a functional configuration of a control device in the first embodiment of the present disclosure. FIG. 4 is a flowchart showing the flow of a cooling system management method in the first embodiment of the present disclosure. 4 is a flowchart showing the flow of a method for attaching and detaching a filter in a filter device in the first embodiment of the present disclosure. 1 is a diagram showing a state in which the on-off valve of the second pipe is closed in the filter device according to the first embodiment of the present disclosure. FIG. 1 is a diagram showing a state in which a filter of a second pipe is removed in a filter device according to a first embodiment of the present disclosure. FIG. FIG. 11 is a diagram showing a minimum configuration of a filter device according to a second embodiment of the present disclosure.

Below, we will explain embodiments of the filter device, cooling system, and method for attaching and detaching a filter in a filter device according to the present disclosure, with reference to the drawings.

First Embodiment
FIG. 1 is a diagram showing a configuration of a cooling system 1 in this embodiment.
As shown in FIG. 1, the cooling system 1 includes a water-cooled rack 10, a pipeline 20, a pump 30, a cooling device 40, and a filter device 50A.

The water-cooled rack 10 can accommodate a plurality of computer devices C as objects to be cooled.
The water-cooled rack 10 is a shelf member that supports a plurality of computer devices C.
The water-cooled rack 10 cools a plurality of computer devices C.
The water-cooled rack 10 supplies cooling liquid X to each computer device C and collects cooling liquid X from the computer devices C.
The object to be cooled is not limited to the computer device C.
The cooling liquid X may be water, oil, or other liquid.

The water-cooled rack 10 includes an inlet manifold 11 and an outlet manifold 12 .
The inlet manifold 11 includes a single main pipe 11a and a plurality of branch pipes 11b.
The main pipe 11a is connected to a pipeline 20 which will be described later.
The branch pipes 11b are connected to the main pipe 11a.
The branch pipes 11b are provided so as to branch off from the main pipe 11a.
Each of the multiple branch pipes 11b is connected to an inlet of multiple computer devices C (for example, an inlet of a cold plate that cools the computer devices C).

The outlet manifold 12 includes a single main pipe 12a and a plurality of branch pipes 12b.
The main pipe 12a is connected to a pipeline 20 which will be described later.
The branch pipes 12b are connected to the main pipe 12a.
Each of the multiple branch pipes 12b is connected to the outlets of multiple computer devices C (for example, the inlets of cold plates).

The pipeline 20 is connected to the water-cooled rack 10 .
The pipes 20 circulate and supply the cooling liquid X to a plurality of computer devices C, which are to be cooled, mounted on the water-cooled rack 10 .
The pipe 20 is a pipe that supplies the cooling liquid X to the water-cooled rack 10 and collects the cooling liquid X from the water-cooled rack 10 .
The pipeline 20 includes a cold liquid pipe 21 and a hot liquid pipe 22 .
The cooling liquid pipe 21 supplies the cooling liquid X cooled by a cooling device 40 (described later) to the water-cooled rack 10 .
The hot liquid pipe 22 supplies the high-temperature cooling liquid X collected from the water-cooled rack 10 to the cooling device 40 .

The pump 30 is disposed midway along the pipeline 20 .
In this embodiment, the pump 30 is provided in the middle of the cooling liquid pipe 21 of the pipeline 20 .
The pump 30 may be provided at an intermediate position of the hot liquid pipe 22 of the pipeline 20 .
The pump 30 circulates the cooling liquid X within the pipe 20 .
The pump 30 pumps the cooling liquid X, thereby circulating the cooling liquid X through the water-cooled rack 10 and the pipeline 20 .

The cooling device 40 is installed at a midpoint of the pipeline 20 .
The cooling device 40 is disposed at the boundary between the cold liquid pipe 21 and the hot liquid pipe 22 of the pipeline 20 .
The cooling device 40 cools the cooling liquid X in the pipe 20 .
The cooling device 40 cools the cooling liquid X, which has been warmed by cooling the computer device C, so that it can cool the computer device C again.
As the cooling device 40, a heat exchanger that cools the cooling liquid X by exchanging heat between the cooling liquid X and a refrigerant is used.

FIG. 2 is a diagram showing the configuration of a filter device 50A in the first embodiment of the present disclosure, showing a state in which a first pipe 51 is blocked.
The filter device 50A is installed in the middle of the pipeline 20.
As shown in FIG. 2, the filter device 50A mainly includes a first pipe 51, a second pipe 52, filters 53A and 53B, an upstream switching mechanism 56, and a downstream switching mechanism 57.
The first pipe 51 and the second pipe 52 are disposed midway through the pipeline 20 .
The first pipe 51 and the second pipe 52 are branched into two from the pipe 20 on the upstream side of the pipe 20 in the flow direction of the cooling liquid X.
The first pipe 51 and the second pipe 52 join together downstream in the flow direction of the coolant X in the pipe 20 and are connected to the pipe 20 .
The first pipe 51 and the second pipe 52 are provided in parallel.

The filter 53A is provided in a middle portion of the first pipe 51 .
The filter 53A captures impurities such as dust contained in the cooling liquid X flowing through the first piping 51 and products generated within the pipeline 20 by reaction between the material forming the pipeline 20 and components contained in the cooling liquid X.
The first pipe 51 is provided with an on-off valve 54A upstream of the filter 53A.
The first pipe 51 is provided with an on-off valve 55A downstream of the filter 53A.
The on-off valves 54A and 55A each open and close the flow path in the first pipe 51 .
The filter 53A is detachably provided to the first pipe 51 between the on-off valve 54A and the on-off valve 55A.

The filter 53B is provided in a middle portion of the second pipe 52 .
The filter 53B captures impurities such as dust contained in the cooling liquid X flowing through the second piping 52 and products generated within the pipeline 20 by reaction between the material forming the pipeline 20 and components contained in the cooling liquid X.
The second pipe 52 is provided with an on-off valve 54B upstream of the filter 53B.
The second pipe 52 is provided with an on-off valve 55B downstream of the filter 53B.
The on-off valves 54B and 55B each open and close the flow path in the second pipe 52.
The filter 53B is detachably provided to the second pipe 52 between the on-off valve 54B and the on-off valve 55B.

The upstream switching mechanism 56 is provided at a branching portion 50 r where the pipeline 20 branches into the first pipe 51 and the second pipe 52 .
The upstream switching mechanism 56 is capable of selectively blocking either the first pipe 51 or the second pipe 52 .
The upstream switching mechanism 56 includes an upstream blocking member 56p and an upstream drive portion 56d.
The upstream blocking member 56 p selectively blocks either the first pipe 51 or the second pipe 52 .
The upstream blocking member 56p selectively blocks either the first pipe 51 or the second pipe 52 upstream of the on-off valves 54A, 54B.
The upstream blocking member 56p is a valve element capable of blocking the flow passage 51r in the first pipe 51 and the flow passage 52r in the second pipe 52, respectively.
The upstream blocking member 56p is provided to be movable between a position where it blocks the flow path 51r in the first pipe 51 and a position where it blocks the flow path 52r in the second pipe 52.
The upstream blocking member 56p is, for example, rotatable around an axis 56s, so that it can be moved between a position blocking the flow path 51r in the first piping 51 and a position blocking the flow path 52r in the second piping 52.
The upstream drive unit 56 d drives the upstream blocking member 56 p to switch between the first piping 51 and the second piping 52 .
The upstream drive unit 56d, for example, by rotationally driving the shaft 56s, moves the upstream blocking member 56p between a position where it blocks the flow path 51r in the first piping 51 and a position where it blocks the flow path 52r in the second piping 52.

The downstream switching mechanism 57 is provided at the junction 50j where the first pipe 51 and the second pipe 52 join together.
The downstream switching mechanism 57 is capable of selectively blocking either the first pipe 51 or the second pipe 52 .
The downstream switching mechanism 57 includes a downstream blocking member 57p and a downstream drive portion 57d.
The downstream blocking member 57 p selectively blocks either the first pipe 51 or the second pipe 52 .
The downstream blocking member 57p selectively blocks either the first pipe 51 or the second pipe 52 downstream of the on-off valves 55A and 55B.
The downstream blocking member 57p is a valve element capable of blocking the flow passage 51r in the first pipe 51 and the flow passage 52r in the second pipe 52, respectively.
The downstream blocking member 57p is provided to be movable between a position where it blocks the flow path 51r in the first pipe 51 and a position where it blocks the flow path 52r in the second pipe 52.
The downstream blocking member 57p is, for example, rotatable around an axis 57s, so that it can be moved between a position where it blocks the flow path 51r in the first piping 51 and a position where it blocks the flow path 52r in the second piping 52.
The downstream drive unit 57 d drives the downstream blocking member 57 p to switch between the first piping 51 and the second piping 52 .
The downstream drive unit 57d, for example, rotates the shaft 57s to move the downstream blocking member 57p between a position where it blocks the flow path 51r in the first piping 51 and a position where it blocks the flow path 52r in the second piping 52.

FIG. 3 is a diagram showing a state in which the second pipe 52 is blocked in the filter device 50A according to the present embodiment.
The upstream-side switching mechanism 56 and the downstream-side switching mechanism 57 switch the flow path of the cooling liquid X flowing through the pipeline 20 between the first pipe 51 and the second pipe 52 .
For example, as shown in FIG. 2, when the flow path 51r in the first piping 51 is blocked by the upstream blocking member 56p of the upstream switching mechanism 56 and the downstream blocking member 57p of the downstream switching mechanism 57, the cooling liquid X flowing through the conduit 20 flows into the second piping 52 and passes through the filter 53B.
At this time, the flow path 51r in the first pipe 51 is blocked by an upstream blocking member 56p of the upstream switching mechanism 56 provided at the branching portion 50r and a downstream blocking member 57p of the downstream switching mechanism 57 provided at the merging portion 50j. This prevents the cooling liquid X flowing through the conduit 20 from flowing into the first pipe 51.
Also, for example, as shown in FIG. 3, when the flow path 52r in the second piping 52 is blocked by the upstream blocking member 56p of the upstream switching mechanism 56 and the downstream blocking member 57p of the downstream switching mechanism 57, the cooling liquid X flowing through the conduit 20 flows into the first piping 51 and passes through the filter 53A.
At this time, the flow path 52r in the second pipe 52 is blocked by an upstream blocking member 56p of the upstream switching mechanism 56 provided at the branching portion 50r and a downstream blocking member 57p of the downstream switching mechanism 57 provided at the merging portion 50j. This prevents the cooling liquid X flowing through the conduit 20 from flowing into the second pipe 52.

The configuration of the upstream switching mechanism 56 and the downstream switching mechanism 57 can be appropriately changed as long as they can switch the flow path of the cooling liquid X flowing through the pipeline 20 between the first pipe 51 and the second pipe 52.
For example, the upstream switching mechanism 56 and the downstream switching mechanism 57 may each individually include a first blocking member that blocks the flow path 51r in the first pipe 51 and a second blocking member that blocks the flow path 52r in the second pipe 52, and the first blocking member and the second blocking member may be configured to switch the flow path of the cooling liquid X between the first pipe 51 and the second pipe 52.
Furthermore, the upstream switching mechanism 56 and the downstream switching mechanism 57 may each be, for example, a three-way valve.

As shown in FIG. 1 , the cooling system 1 further includes a temperature sensor 60 , a pressure sensor 70 , and a control device 80 .
The temperature sensor 60 is provided downstream of the computer device C that is to be cooled.
The temperature sensor 60 detects the temperature of the cooling liquid X in the line 20 downstream of the computer device C.
The temperature sensor 60 is provided, for example, in each branch pipe 12 b of the outlet manifold 12 of the water-cooled rack 10 .
The temperature sensor 60 is disposed on the branch pipe 12 b provided downstream of each of the multiple computer devices C mounted on the water-cooled rack 10 .
When an abnormality occurs in the computer device C, the temperature of the computer device C rises.
A temperature sensor 60 provided downstream of the computer device C detects a rise in temperature of the cooling liquid X accompanying a rise in temperature of the computer device C.
The temperature sensor 60 outputs data of the detected temperature to the control device 80 .

The pressure sensor 70 detects the pressure of the cooling liquid X in the pipe 20 .
The pressure sensor 70 detects a change in pressure of the cooling liquid X in the pipe 20 caused by clogging of the filters 53A, 53B of the filter device 50A.
The pressure sensor 70 is disposed, for example, downstream of the filters 53A and 53B of the filter device 50A.
As shown in FIG. 2, in this embodiment, the pressure sensor 70 is disposed at, for example, the junction 50j.
When the filters 53A, 53B become clogged due to the accumulation of impurities trapped in the filters 53A, 53B, a pressure drop of the cooling liquid X occurs downstream of the filters 53A, 53B.
A pressure sensor 70 disposed downstream of the filters 53A, 53B of the filter device 50A detects a drop in pressure of the cooling liquid X caused by clogging of the filters 53A, 53B.
The pressure sensor 70 outputs data of the detected pressure to the control device 80 .

The control device 80 monitors the state of the cooling system 1 based on the data output from the temperature sensor 60 and the pressure sensor 70 .
The control device 80 monitors whether or not an abnormality has occurred in the computer device C, which is the object to be cooled, based on the temperature of the cooling liquid X detected by the temperature sensor 60.
The control device 80 monitors the degree of clogging of the filters 53A, 53B based on the pressure of the cooling liquid X detected by the pressure sensor 70.

FIG. 4 is a block diagram showing the functional configuration of the control device 80 in this embodiment.
As shown in FIG. 4 , the control device 80 functionally comprises, for example, a data receiving unit 81 , a temperature abnormality signal output unit 82 , and a pressure abnormality signal output unit 83 .
The data receiving unit 81 receives data output from the temperature sensor 60 and the pressure sensor 70 .
The data receiving unit 81 transfers the data on the temperature of the coolant X received from the temperature sensor 60 to the temperature abnormality signal output unit 82 .
The data receiving unit 81 transfers the data on the pressure of the coolant X received from the pressure sensor 70 to the pressure abnormality signal output unit 83 .

The temperature abnormality signal output unit 82 monitors the temperatures detected by the multiple temperature sensors 60 .
The temperature abnormality signal output unit 82 determines whether or not the temperature detected by the temperature sensor 60 is equal to or higher than a preset reference temperature.
The temperature abnormality signal output unit 82 outputs a temperature abnormality signal when the temperature detected by the temperature sensor 60 is equal to or higher than a preset reference temperature.
The temperature abnormality signal output unit 82 outputs the temperature abnormality signal to, for example, a lamp, a buzzer, a monitor, or the like.
The temperature abnormality signal output unit 82 outputs the temperature abnormality signal to, for example, light a lamp, sound a buzzer, display a message on a monitor, and so on.
In this embodiment, the temperature abnormality signal output unit 82 outputs a temperature abnormality signal to light up LED lamps (not shown) disposed near the multiple computer devices C mounted on the water-cooled rack 10 .
When the temperature detected by one of the multiple temperature sensors 60 is equal to or higher than a reference temperature, the temperature abnormality signal output unit 82 outputs a temperature abnormality signal to, for example, a lamp corresponding to the computer device C where the temperature rise has occurred.

The pressure abnormality signal output unit 83 monitors the pressure detected by the pressure sensor 70 .
The pressure abnormality signal output unit 83 determines whether or not the pressure detected by the pressure sensor 70 is less than a preset reference pressure.
The pressure abnormality signal output unit 83 outputs a pressure abnormality signal when the pressure detected by the pressure sensor 70 is lower than a preset reference pressure.
The pressure abnormality signal output unit 83 outputs the pressure abnormality signal to, for example, a lamp, a buzzer, a monitor, or the like.
The pressure abnormality signal output unit 83 outputs a pressure abnormality signal to, for example, light a lamp, sound a buzzer, display a message on a monitor, and so on.
In this embodiment, the pressure abnormality signal output unit 83 outputs a pressure abnormality signal to light up an LED lamp 85 (see FIG. 2) disposed in the filter device 50A.
By visually checking that the LED lamp 85 is lit, the manager of the cooling system 1 can recognize that a drop in pressure of the cooling liquid X has occurred downstream of the filters 53A, 53B due to clogging of the filters 53A, 53B.

Next, a method for managing the cooling system 1 as described above will be described.
FIG. 5 is a flowchart showing the flow of a method for managing the cooling system 1 in this embodiment.
The data receiving unit 81 of the control device 80 receives temperature data detected by the plurality of temperature sensors 60 and pressure data detected by the pressure sensor 70 at preset time intervals (step S11).
The data receiving unit 81 transfers the temperature data received from the temperature sensor 60 to the temperature abnormality signal output unit 82 .
The data receiving unit 81 transfers the pressure data received from the pressure sensor 70 to the pressure abnormality signal output unit 83 .

The temperature abnormality signal output unit 82 determines whether or not the temperature detected by the temperature sensor 60 is equal to or higher than a preset reference temperature (step S12).
As a result, if the temperature detected by the temperature sensor 60 is not equal to or higher than the preset reference temperature, the process proceeds to step S14.
On the other hand, if the temperature detected by the temperature sensor 60 is equal to or higher than the preset reference temperature in step S12, the temperature abnormality signal output unit 82 outputs a temperature abnormality signal (step S13).
When the temperature detected by one of the plurality of temperature sensors 60 is equal to or higher than a reference temperature, the temperature abnormality signal output unit 82 outputs a temperature abnormality signal to a lamp corresponding to the computer device C where the temperature rise has occurred.
As a result, an LED lamp (not shown) provided near the computer device C that has received the abnormal temperature signal is turned on.
The manager of the cooling system 1 visually recognizes the lighting of the LED lamp and recognizes that the temperature of the computer device C has risen, that is, that some abnormality has occurred in the computer device C.
The administrator recognizes that an abnormality has occurred and inspects and performs maintenance, etc., on the computer device C as necessary.

In step S14, the pressure abnormality signal output unit 83 determines whether or not the pressure detected by the pressure sensor 70 is less than a preset reference pressure.
As a result, if the pressure detected by the pressure sensor 70 is not less than the preset reference pressure, the series of processes ends.
On the other hand, if the pressure detected by the pressure sensor 70 is lower than the preset reference pressure in step S13, the pressure abnormality signal output unit 83 outputs a pressure abnormality signal (step S15).
The LED lamp 85 that receives the pressure abnormality signal turns on.
The manager of the cooling system 1 visually confirms that the LED lamp 85 of the filter device 50A is lit, and thereby recognizes that a drop in pressure of the cooling liquid X has occurred due to clogging of the filters 53A and 53B.
The manager removes one of the filters 53A, 53B in which a pressure abnormality has occurred, that is, the one through which the cooling liquid X is flowing at that time, and performs maintenance such as replacement, removal of impurities, and cleaning as necessary.

FIG. 6 is a flow chart showing the flow of a method for attaching and detaching the filters 53A and 53B in the filter device 50A of this embodiment.
In the case of removing one of the filters 53A and 53B in the filter device 50A, the work is performed according to the flow shown in Fig. 6. Here, for example, as shown in Fig. 2, a case where the filter 53B of the second pipe 52 is clogged while the coolant X is flowing through the filter 53B will be described as an example.
First, the upstream switching mechanism 56 closes either the first pipe 51 or the second pipe 52, and causes the cooling liquid X to flow through the other of the first pipe 51 and the second pipe 52 (step S21).
In this embodiment, as shown in Fig. 3, while the cooling liquid X is flowing through the filter 53B of the second pipe 52, the upstream switching mechanism 56 is operated to close the second pipe 52. As a result, as shown in Fig. 2, the cooling liquid X is flowed through the first pipe 51 and passes through the filter 53B.

Next, the on-off valve in either the first pipe 51 or the second pipe 52 is closed (step S22).
FIG. 7 is a diagram showing a state in which the on-off valves 54B and 55B of the second pipe 52 are closed in the filter device 50A of the present embodiment.
In this embodiment, as shown in FIG. 7, in the second pipe 52, the on-off valves 54B and 55B located upstream and downstream of the filter 53B are closed.

Next, the filter is removed from either the first pipe 51 or the second pipe 52 (step S23).
FIG. 8 is a diagram showing a state in which the filter 53B of the second pipe 52 is removed in the filter device 50A of the present embodiment.
In this embodiment, as shown in FIG. 8, the filter 53B is removed from the second pipe 52.
The filter 53B thus removed is then subjected to required maintenance such as replacement, removal of impurities, and cleaning.

Thereafter, the filter for which maintenance has been completed is attached to either the first pipe 51 or the second pipe 52 (step S24).
In this embodiment, the filter 53B for which maintenance has been completed is attached to the second pipe 52. This returns the system to the state shown in FIG.
Furthermore, the on-off valve is opened in either the first pipe 51 or the second pipe 52 (step S25).
In this embodiment, the on-off valves 54B, 55B on the upstream side and downstream side of the filter 53B are opened in the second pipe 52. This returns the state shown in FIG.

Thereafter, the state in which the coolant X flows through the first pipe 51 may be maintained until it becomes necessary to perform maintenance on the filter 53A of the first pipe 51 .
Also, the upstream switching mechanism 56 may be operated to close the first pipe 51 and cause the cooling liquid X to flow again through the second pipe 52 as shown in FIG.

The filter device 50A of this embodiment as described above includes a first pipe 51 and a second pipe 52 that are branched off from the pipeline 20, filters 53A and 53B that are provided midway through the first pipe 51 and the second pipe 52, on-off valves 54A, 55A, 54B, and 55B that are provided upstream and downstream of the filters 53A and 53B in the first pipe 51 and the second pipe 52, respectively, and an upstream switching mechanism 56 that is provided at a branching section 50r that branches off from the pipeline 20 to the first pipe 51 and the second pipe 52 and that can selectively close either the first pipe 51 or the second pipe 52.

According to such a filter device 50A, one of the first pipe 51 and the second pipe 52 is selectively blocked by the upstream switching mechanism 56 provided in the branch section 50r. As a result, when the cooling liquid X is flowing through one of the first pipe 51 and the second pipe 52, the other of the first pipe 51 and the second pipe 52 is blocked. Therefore, a part of the cooling liquid X flowing through one of the first pipe 51 and the second pipe 52 is prevented from flowing into the other of the first pipe 51 and the second pipe 52. As a result, when replacing the filters 53A and 53B in the other of the first pipe 51 and the second pipe 52, a backflow of the cooling liquid X caused by a part of the cooling liquid X flowing into the other of the first pipe 51 and the second pipe 52 is prevented. As a result, when removing the filters 53A and 53B, it is possible to prevent a decrease in the cooling efficiency of the cooling target.

The filter device 50A of this embodiment is provided at the junction 50j where the first pipe 51 and the second pipe 52 join, and includes a downstream switching mechanism 57 that can selectively block either the first pipe 51 or the second pipe 52. By providing the downstream switching mechanism 57 at the junction 50j of the first pipe 51 and the second pipe 52, it is possible to prevent a decrease in the cooling efficiency of the cooling target when removing the filters 53A and 53B.

In addition, in the filter device 50A of this embodiment, the upstream switching mechanism 56 includes an upstream blocking member 56p that selectively blocks either the first pipe 51 or the second pipe 52, and an upstream drive unit 56d that switches and drives the upstream blocking member 56p between the first pipe 51 and the second pipe 52. As a result, by switching and driving the upstream blocking member 56p with the upstream drive unit 56d, it is possible to selectively block either the first pipe 51 or the second pipe 52 at the branch section 50r.

In addition, in the filter device 50A of this embodiment, the downstream switching mechanism 57 includes a downstream blocking member 57p that selectively blocks either the first pipe 51 or the second pipe 52, and a downstream drive unit 57d that switches and drives the downstream blocking member 57p between the first pipe 51 and the second pipe 52. As a result, by switching and driving the downstream blocking member 57p with the downstream drive unit 57d, it is possible to selectively block either the first pipe 51 or the second pipe 52 at the junction 50j.

The cooling system 1 of this embodiment as described above includes a pipeline 20 that circulates and supplies the cooling liquid X to the object to be cooled, a pump 30 that circulates the cooling liquid X in the pipeline 20, a cooling device 40 that cools the cooling liquid X in the pipeline 20, and a filter device 50A. With this type of cooling system 1, it is possible to provide a cooling system 1 that includes a filter device 50A that can prevent the cooling efficiency of the object to be cooled from decreasing when the filters 53A and 53B are removed.

The cooling system 1 of this embodiment further includes a temperature sensor 60 that is provided downstream of the object to be cooled and detects the temperature of the cooling liquid X in the pipe 20, and a temperature abnormality signal output unit 82 that outputs a temperature abnormality signal when the temperature detected by the temperature sensor 60 becomes equal to or higher than a preset reference temperature. This makes it possible to detect an increase in the temperature of the cooling liquid X in the pipe 20 and thus grasp the occurrence of an abnormality in the computer device C that is the object to be cooled.

The cooling system 1 of this embodiment further includes a pressure sensor 70 that detects the pressure of the cooling liquid X in the pipe 20, and a pressure abnormality signal output unit 83 that outputs a pressure abnormality signal when the pressure detected by the pressure sensor 70 falls below a preset reference pressure. This makes it possible to detect a drop in the pressure of the cooling liquid X in the pipe 20 and to determine whether the filters 53A and 53B are clogged. This allows the filters 53A and 53B to be maintained at an appropriate time.

According to the method for removing and attaching the filters 53A and 53B in the filter device 50A of this embodiment as described above, the method includes a step S21 of blocking one of the first pipe 51 and the second pipe 52 with the upstream switching mechanism 56 and allowing the cooling liquid X to flow through the other of the first pipe 51 and the second pipe 52, a step S22 of closing the on-off valves 54A, 55A, 54B, and 55B upstream and downstream of the filters 53A and 53B in one of the first pipe 51 and the second pipe 52, a step S23 of removing the filters 53A and 53B in one of the first pipe 51 and the second pipe 52, a step S24 of attaching the filters 53A and 53B in one of the first pipe 51 and the second pipe 52, and a step S25 of opening the on-off valves 54A, 55A, 54B, and 55B upstream and downstream of the filters 53A and 53B in one of the first pipe 51 and the second pipe 52. This allows filters 53A and 53B to be attached and detached while preventing a decrease in the cooling efficiency of the object to be cooled.

Second Embodiment
Next, a second embodiment of the present disclosure will be described with reference to Fig. 9. In the description of this embodiment, the description of the same parts as those of the first embodiment will be omitted or simplified.
FIG. 9 is a diagram showing a minimum configuration of a filter device 50B according to the second embodiment of the present invention.
As shown in FIG. 9, the filter device 50B is provided in a pipe 120 that circulates and supplies the cooling liquid X to the object to be cooled.
The filter device 50B includes a first pipe 151, a second pipe 152, filters 153A and 153B, on-off valves 154A, 155A, 154B and 155B, and an upstream switching mechanism 156.
The first pipe 151 and the second pipe 152 are provided so as to branch off from the pipeline 120 .
The filters 153A and 153B are provided midway along the first pipe 151 and the second pipe 152, respectively.
The on-off valves 154A, 155A are provided in the first pipe 151 on the upstream side and downstream side of the filter 153A.
The on-off valves 154B, 155B are provided in the second pipe 152 on the upstream side and downstream side of the filter 153B.
The upstream switching mechanism 156 is provided at a branching portion 150 r where the pipeline 20 branches into a first pipe 151 and a second pipe 152 .
The upstream switching mechanism 156 is capable of selectively blocking either the first pipe 151 or the second pipe 152 .

According to this configuration, either one of the first pipe 151 and the second pipe 152 is selectively blocked by the upstream switching mechanism 156 provided in the branch portion 150r. As a result, when the cooling liquid X is flowing through one of the first pipe 151 and the second pipe 152, the other of the first pipe 151 and the second pipe 152 is blocked. Therefore, a part of the cooling liquid X flowing through one of the first pipe 151 and the second pipe 152 is prevented from flowing into the other of the first pipe 151 and the second pipe 152. As a result, when replacing the filters 153A and 153B in the other of the first pipe 151 and the second pipe 152, a backflow of the cooling liquid X caused by a part of the cooling liquid X flowing into the other of the first pipe 151 and the second pipe 152 is prevented. As a result, when removing the filters 153A and 153B, it is possible to prevent the cooling efficiency of the cooling target from decreasing.

Although preferred embodiments of the present disclosure have been described above with reference to the attached drawings, it goes without saying that the present disclosure is not limited to the above-described embodiments. The shapes and combinations of the components shown in the above-described embodiments are merely examples, and various modifications can be made based on design requirements, etc., without departing from the spirit of the present disclosure.

LIST OF SYMBOLS 1 Cooling system 10 Water-cooled rack 20, 120 Pipe 30 Pump 40 Cooling device 50A, 50B Filter device 50j Junction 50r, 150r Branch 51, 151 First pipe 52, 152 Second pipe 53A, 53B, 153A, 153B Filter 54A, 54B, 55A, 55B, 154A, 154B, 155A, 155B Opening/closing valve 56, 156 Upstream switching mechanism 56d Upstream drive unit 56p Upstream blocking member 57 Downstream switching mechanism 57d Downstream drive unit 57p Downstream blocking member 60 Temperature sensor 70 Pressure sensor 82 Temperature abnormality signal output unit 83 Pressure abnormality signal output unit 156 Upstream switching mechanism C Computer device

Claims (9)

A filter device provided in a pipeline for circulating a cooling liquid to a cooling object,
A first pipe and a second pipe are provided so as to branch off from the pipeline;
a filter provided midway along each of the first pipe and the second pipe;
an on-off valve provided on the upstream side and downstream side of the filter in each of the first pipe and the second pipe,
an upstream switching mechanism provided at a branching portion where the pipeline branches into the first pipe and the second pipe, the upstream switching mechanism being capable of selectively closing one of the first pipe and the second pipe;
A filter device comprising: The filter device according to claim 1 , further comprising a downstream switching mechanism provided at a junction where the first pipe and the second pipe join, the downstream switching mechanism being capable of selectively blocking one of the first pipe and the second pipe. The upstream switching mechanism includes an upstream blocking member that selectively blocks one of the first pipe and the second pipe;
an upstream drive unit that switches and drives the upstream blocking member between the first pipe and the second pipe;
The filter device according to claim 1 or 2, comprising: The downstream switching mechanism includes a downstream blocking member that selectively blocks one of the first pipe and the second pipe;
a downstream drive unit that switches and drives the downstream blocking member between the first pipe and the second pipe;
The filter device according to claim 2 , comprising: A filter device according to claim 1 or 2;
The pipeline;
a pump for circulating the cooling liquid through the pipeline;
a cooling device for cooling the cooling liquid in the pipe;
Equipped with a cooling system. a temperature sensor provided in an outlet pipe connected to an outlet of the cooling liquid of the cooling target, the temperature sensor detecting a temperature of the cooling liquid in the outlet pipe;
a temperature abnormality signal output unit that outputs a temperature abnormality signal when the temperature detected by the temperature sensor becomes equal to or higher than a preset reference temperature;
The cooling system of claim 5 further comprising: A filter device according to claim 2;
The pipeline;
a pump for circulating the cooling liquid through the pipeline;
a cooling device for cooling the cooling liquid in the pipe;
a pressure sensor disposed at the junction and detecting a pressure of the cooling liquid in the pipe;
a pressure abnormality signal output unit that outputs a pressure abnormality signal when the pressure detected by the pressure sensor becomes lower than a preset reference pressure;
Further equipped
Cooling system. The cooling system according to claim 5 , further comprising a water-cooled rack connected to the pipeline and capable of mounting a plurality of computer devices as the cooling targets. a step of blocking the second pipe by the upstream switching mechanism in the filter device according to claim 1 or 2 and causing the cooling liquid to flow through the first pipe ;
closing the on-off valves upstream and downstream of the filter in the second piping;
removing the filter from the second pipe;
attaching the filter to the second pipe;
opening the on-off valves upstream and downstream of the filter in the second piping;
Includes how to install and remove the filter.

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