TW201427579A - Container data center assembly - Google Patents

Abstract

A container data center assembly includes a first cooling system including a cooling apparatus, a first container data center, a sensor, and a second valve connected by pipes in that order, and a second cooling system including the cooling apparatus, a second container data center and a third valve connected by pipes in that order, and a first valve connected between the second container center and the sensor. When the cooling liquid heated by the first container data center is cooler than a preset value, the first valve is opened, and the second valve and the third valve are closed. Thus the cooling liquid heated by the first container data center continues to flow into the second container data center to cool the second container data center.

Description

Container server combination

The present invention relates to a container server combination.

At present, with the more powerful functions of container servers, container servers tend to generate a lot of heat. A common way to dissipate heat is to set up a chiller for each container server. The coolant generated by the chiller flows through the container server to dissipate heat from the container server, but the operating power of the container server is not large. The lower the heat generation, the lower the temperature of the coolant to the container server, the lower the energy of the refrigerator, which is not conducive to energy saving.

In view of the above, it is necessary to provide a container server combination that can effectively save energy.

A container server combination includes a first container server, a second container server, a refrigerator, a first valve, a second valve, a third valve and a temperature sensor, a refrigerator, The first container servo, the temperature sensor, and the second valve are sequentially connected by a pipeline to form a first cooling system, the second valve is opened, and the coolant generated by the refrigerator is transmitted to the first container servo to the first container servo The heat is dissipated; the refrigerator, the third valve and the second container servo are sequentially connected by a pipeline to form a second cooling system, and the third valve is opened, and the coolant generated by the refrigerator is transmitted to the second container through the third valve. The server dissipates heat from the second container server; the first valve is connected between the second container server and the temperature sensor by a pipeline, and after the temperature sensor senses the heat dissipation of the first container server When the temperature of the coolant is lower than the predetermined value, the first valve is opened, and the second valve and the third valve are closed, and the coolant that has cooled the first container server flows into the second container server through the first valve, so as to Second container server Dissipating heat, and then returning the coolant to the refrigerator; when the temperature sensor senses that the temperature of the coolant after dissipating heat to the first container server is higher than a predetermined value, the first valve is closed, and the second valve is opened simultaneously The three valves dissipate heat from the first container server and the second container server respectively.

The container server combination of the invention senses the temperature of the coolant according to the temperature sensor to control the opening and closing of the first valve, the second valve and the third valve, so as to realize sharing or respectively of the first container server and the second container server The use of coolant for heat dissipation is conducive to energy saving and emission reduction according to demand.

Referring to FIG. 1 , a preferred embodiment of the container server combination of the present invention includes a first container server 10 , a second container server 20 , a refrigerator 30 , a first valve 40 , and a second valve 50 . A third valve 60 and a temperature sensor 70.

The refrigerator 30, the first container server 10, the temperature sensor 70, and the second valve 50 are sequentially connected by a pipeline to form a first cooling system 100. The second valve 50 is opened, and the coolant generated by the refrigerator 30 is transmitted to the first container server 10 to dissipate heat from the first container server 10. The coolant that has cooled the first container servo 10 passes through the temperature sensor 70 and the second valve 50 and is returned to the refrigerator 30.

The refrigerator 30, the third valve 60, and the second container server 20 are sequentially connected by a pipeline to form a second cooling system 200. The third valve 60 is opened, and the coolant generated by the refrigerator 30 is transmitted to the second container server 20 through the third valve 60 to dissipate heat from the second container server 20. The coolant that has cooled the second container servo 20 is returned to the refrigerator 30.

A first valve 40 is connected between the second container server 20 and the temperature sensor 70 by a pipeline. When the heat of the first container server 10 is not so large that the temperature of the coolant after the heat dissipation of the first container server 10 is still low, the first valve 40 is opened while the second valve 50 and the third valve 60 are closed. The coolant that has cooled the first container server 10 flows into the second container server 20 through the first valve 40 to dissipate heat from the second container server 20, and then returns the coolant to the refrigerator 30.

Referring to FIG. 2 together, the first valve 40, the second valve 50 and the third valve 60 are both solenoid valves controlled by a controller 80, and when the temperature sensor 70 senses the first container server 10 When the temperature of the coolant after the heat dissipation is lower than a predetermined value (for example, 30 ° C), the temperature sensor 70 sends a low temperature signal to the controller 80, and the controller 80 controls the first valve 40 to open while closing the second valve 50 and The third valve 60. When the temperature sensor 70 senses that the temperature of the coolant after the heat dissipation of the first container server 10 is higher than the predetermined value, the temperature sensor 70 sends a high temperature signal to the controller, and the controller controls the first valve 40 to be closed. At the same time, the second valve 50 and the third valve 60 are opened to respectively transfer the coolant to the first container server 10 and the second container server 20 for heat dissipation.

The container server combination of the present invention controls the opening and closing of the first valve 40, the second valve 50 and the third valve 60 according to the temperature sensor 70 sensing the temperature of the coolant to realize the first container server 10 and the second container. The server 20 shares or separately uses the coolant to dissipate heat, which is beneficial to energy saving and emission reduction according to requirements.

In summary, the present invention complies with the requirements of the invention patent and submits a patent application according to law. The above description is only the preferred embodiment of the present invention, and equivalent modifications or variations made by those skilled in the art will be included in the following claims.

100. . . First cooling system

200. . . Second cooling system

10. . . First container server

20. . . Second container server

30. . . Refrigerator

40. . . First valve

50. . . Second valve

60. . . Third valve

70. . . Temperature sensor

80. . . Controller

1 is a schematic structural view of a preferred embodiment of a container server assembly of the present invention.

2 is a schematic diagram of a control system of a preferred embodiment of a container server combination of the present invention.

100. . . First cooling system

200. . . Second cooling system

10. . . First container server

20. . . Second container server

30. . . Refrigerator

40. . . First valve

50. . . Second valve

60. . . Third valve

70. . . Temperature sensor

80. . . Controller

Claims (1)

A container server combination includes a first container server, a second container server, a refrigerator, a first valve, a second valve, a third valve and a temperature sensor, a refrigerator, The first container servo, the temperature sensor, and the second valve are sequentially connected by a pipeline to form a first cooling system, the second valve is opened, and the coolant generated by the refrigerator is transmitted to the first container servo to the first container servo The heat is dissipated; the refrigerator, the third valve and the second container servo are sequentially connected by a pipeline to form a second cooling system, and the third valve is opened, and the coolant generated by the refrigerator is transmitted to the second container through the third valve. The server dissipates heat from the second container server; the first valve is connected between the second container server and the temperature sensor by a pipeline, and after the temperature sensor senses the heat dissipation of the first container server When the temperature of the coolant is lower than the predetermined value, the first valve is opened, and the second valve and the third valve are closed, and the coolant that has cooled the first container server flows into the second container server through the first valve, so as to Second container server Dissipating heat, and then returning the coolant to the refrigerator; when the temperature sensor senses that the temperature of the coolant after dissipating heat to the first container server is higher than a predetermined value, the first valve is closed, and the second valve is opened simultaneously The three valves dissipate heat from the first container server and the second container server respectively.