阅读说明：本技术 一种热管、相变材料与浸没式液冷相结合的散热系统 (Heat pipe, phase change material and immersed liquid cooling combined heat dissipation system ) 是由 刘昱 孙海逸 李钟勇 崔峥 王鑫煜 任霄汉 邵卫 王兵 张宇川 王宏标 陈帆 于 2019-09-18 设计创作，主要内容包括：本发明提供了一种热管、相变材料与浸没式液冷相结合的散热系统,所述系统包括箱体、冷却液进口、冷却液出口、热管、动力泵、冷媒源和封装箱,所述箱体中充满冷却液体,所述封装箱设置在箱体内,所述封装箱中包括服务器和相变材料,所述服务器包围在相变材料的内部,所述热管的蒸发端设置在相变材料中,热管的冷凝端延伸穿出到封装箱的外部；所述箱体上分别设置冷却液体进口和出口,供冷却液体进出箱体；所述冷却液体进口和出口由管路分别与冷媒源及动力泵连接,形成“冷媒源-动力泵-冷却液进口-箱体-冷却液出口-动力泵-冷媒源”的散热循环。本发明使用热管输运产生的热量,利用了液体相变传热,相较于常规的对流换热具有更快的散热响应速度,同时也有更高的散热效率,能够很好地解决高热流密度的散热问题。(The invention provides a heat pipe, phase change material and immersed liquid cooling combined heat dissipation system, which comprises a box body, a cooling liquid inlet, a cooling liquid outlet, a heat pipe, a power pump, a refrigerant source and a packaging box, wherein the box body is filled with cooling liquid, the packaging box is arranged in the box body, the packaging box comprises a server and the phase change material, the server is surrounded in the phase change material, an evaporation end of the heat pipe is arranged in the phase change material, and a condensation end of the heat pipe extends out of the packaging box; the box body is respectively provided with a cooling liquid inlet and a cooling liquid outlet for the cooling liquid to enter and exit the box body; the cooling liquid inlet and the cooling liquid outlet are respectively connected with a refrigerant source and a power pump through pipelines to form a heat dissipation cycle of 'the refrigerant source, the power pump, the cooling liquid inlet, the box body, the cooling liquid outlet, the power pump and the refrigerant source'. The invention uses the heat pipe to transport the generated heat, utilizes the liquid phase change heat transfer, has higher heat dissipation response speed and higher heat dissipation efficiency compared with the conventional convection heat transfer, and can well solve the heat dissipation problem of high heat flow density.)

1. A heat pipe, a phase change material and immersed liquid cooling combined heat dissipation system comprises a box body, a cooling liquid inlet, a cooling liquid outlet, a heat pipe, a power pump, a refrigerant source and a packaging box, and is characterized in that the box body is filled with cooling liquid, the packaging box is arranged in the box body, the packaging box comprises a server and the phase change material, the server is surrounded inside the phase change material, an evaporation end of the heat pipe is arranged in the phase change material, and a condensation end of the heat pipe extends out of the packaging box; the box body is respectively provided with a cooling liquid inlet and a cooling liquid outlet for the cooling liquid to enter and exit the box body; the cooling liquid inlet and the cooling liquid outlet are respectively connected with a refrigerant source and a power pump through pipelines to form a heat dissipation cycle of 'the refrigerant source, the power pump, the cooling liquid inlet, the box body, the cooling liquid outlet, the power pump and the refrigerant source'.

2. The heat dissipating system of claim 1, wherein the cooling fluid is an insulating cooling fluid.

3. The heat dissipation system of claim 1, wherein the enclosure is submerged in the insulating coolant and is suspended and secured by a bracket.

4. The heat dissipating system of claim 1, wherein the cabinet is a rectangular parallelepiped container with a removable top cover.

5. the heat dissipation system of claim 3, wherein the servers are uniformly arranged in the enclosure, the phase-change material is filled in the gap between two adjacent servers and between the server and the enclosure wall of the server, and the heat pipes are inserted into the phase-change material, wherein the evaporation ends of the heat pipes are arranged in the enclosure of the server, and the condensation ends of the heat pipes are arranged outside the enclosure of the server.

6. A heat pipe comprises a packaging box, wherein a heat source and a phase-change material are arranged in the packaging box, the heat source is surrounded in the phase-change material, an evaporation end of the heat pipe is arranged in the phase-change material, and a condensation end of the heat pipe extends out of the packaging box.

Technical Field

The invention relates to the field of shell-and-tube heat exchangers, in particular to a heat dissipation system combining a heat pipe, a phase-change material and immersed liquid cooling.

background

With the rapid development of the internet and the internet of things, the world is turning from the internet technology era to the data technology era. The construction of a data center is tightened for dealing with the large outbreak of data storage amount and data calculation amount brought by cloud computing, Internet of things and 5G network development, and the huge heads of the Internet such as Google, Ali, Baidu and the like. It is expected that with the rapid development of industries such as big data, cloud computing, internet +, etc., the demand of the data center will be larger and larger, and thus the problem of huge energy consumption of the data center needs to be solved urgently.

Data centers are energy intensive households. According to the speculation of internet data centers, the power consumption of the data centers accounts for more than 5% of the power consumption of the whole world by 2024, wherein heat dissipation accounts for a very large proportion of the power consumption of the data centers, and even more than half of the power consumption. Data centers typically include computing devices, storage devices, network devices, security devices, etc., where heat dissipation is most desirable, and is most desirable to improve the manner in which heat is dissipated from the computing devices, i.e., from the servers and their internal processors. The traditional natural cooling and heat dissipation scheme can not meet the heat dissipation requirement of the server more and more, and the current heat dissipation scheme of the server mainly comprises air cooling, liquid cooling and heat pipe heat dissipation and cooling. Air cooling is to cool the servers by forced convection of air, and generally, cooling requirements can be met by adding cooling fins, increasing the heat dissipation area of the servers, adding forced cooling fans and the like. However, this method requires improvement of the heat dissipation surface of the machining server, and the fan is noisy and is not suitable for some occasions. In addition, air cooling is not suitable for cooling the heat dissipation surface of the server with high heat flux due to the limitation of the nature of the cooling medium air. The liquid cooling drives the liquid to circularly flow through the water pump, and the heat generated by the liquid is taken away through the heat dissipation surface of the server. Because liquid is adopted as a cooling medium, the heat dissipation capacity of the liquid cooling mode is tens of times of that of the air cooling mode, and the noise reduction effect is obvious. In recent years, in order to meet the requirement of high heat flux density heat dissipation of a server, a scheme of immersion type liquid cooling of the server is widely researched. The server-immersed liquid cooling scheme completely immerses the high heat flux servers, the storage system, and other system accessories in the insulating cooling liquid, thereby providing a complete cluster computing hardware platform. Meanwhile, the server immersion type liquid cooling does not need to be provided with a fan and an air conditioner, and energy consumption is greatly reduced. In addition, as the server equipment is highly integrated, the land use cost of the data center is greatly reduced. And because the server is completely soaked in a closed liquid environment, the computing components such as the CPU, the GPU and the like can stably work in a high-performance frequency state for a long time, so that the computing efficiency of the server is greatly improved, the influence of dust and the like is avoided, the operating environment of the server is greatly optimized, and the computing performance and the service life of the server are improved. The heat pipe heat dissipation utilizes the phase change latent heat capacity of a medium, the medium realizes the coupling of the evaporation and condensation processes in a closed space, the heat transfer is realized, and the heat conduction capacity of the heat pipe heat dissipation is more than one hundred times of that of pure copper. The heat pipe comprises an evaporation end, a condensation end and the like. The heat pipe heat dissipation scheme is also widely applied due to the characteristics of low noise, small size, high heat conduction capability and the like.

research and engineering applications show that the immersed liquid cooling and the heat pipe respectively have excellent heat dissipation performance. In addition, the phase-change material has stable temperature in the heat absorption and heat release process, so that the whole system can achieve the temperature equalization effect, and the phase-change material is widely applied to the cooling field of high-power electronic devices. The three are combined and applied to a server heat dissipation system, the overall heat dissipation of the server is optimized through immersion type liquid cooling, meanwhile, the local heat dissipation of the server is optimized through the heat pipe and the phase-change material, and an excellent solution can be provided for the heat dissipation problem of the server.

Disclosure of Invention

In order to solve the problem of server heat dissipation, the invention provides a server heat dissipation scheme combining a heat pipe, a phase change material and immersion type liquid cooling, the scheme can meet the server heat dissipation requirement of high heat flux density, and the server heat dissipation scheme is particularly suitable for working conditions with high requirements on performance, energy conservation, silence and the like of a server. The immersed liquid cooling, the heat pipe and the phase change material are combined and applied to a server heat dissipation system, and the optimization of server heat dissipation from the whole to the local is realized.

In order to achieve the purpose, the invention adopts the following technical scheme:

A heat pipe, a phase change material and immersed liquid cooling combined heat dissipation system comprises a box body, a liquid separation inlet plate, a liquid collection outlet plate, a heat pipe, a power pump, a refrigerant source and a packaging box, wherein the box body is filled with cooling liquid, the packaging box is arranged in the box body and comprises a server and the phase change material, the server is surrounded inside the phase change material, an evaporation end of the heat pipe is arranged in the phase change material, and a condensation end of the heat pipe extends out of the packaging box; the box body is respectively provided with a cooling liquid inlet and a cooling liquid outlet for the cooling liquid to enter and exit the box body; the cooling liquid inlet and the cooling liquid outlet are respectively connected with a refrigerant source and a power pump through pipelines to form a heat dissipation cycle of 'the refrigerant source, the power pump, the cooling liquid inlet, the box body, the cooling liquid outlet, the power pump and the refrigerant source'.

Preferably, the cooling fluid is an insulating cooling fluid.

preferably, the packaging box is immersed in the insulating cooling liquid and is suspended and fixed by a bracket.

Preferably, the appearance of the box body is a cuboid container which is provided with a detachable upper cover with a corresponding size.

Preferably, the liquid separation inlet plate is arranged at one end of the immersion box body, a large hole is formed in the center of one side of the liquid separation inlet plate and used for being connected with a pipeline outside the immersion box body, and a plurality of small holes are uniformly formed in the other side of the liquid separation inlet plate. The interior of the liquid separation inlet plate is completely communicated, so that insulating cooling liquid can enter from a large hole on one side and then flow out from a plurality of small holes on the other side under the driving of the power pump to enter the immersion box body.

Preferably, the manifold outlet plate is arranged on the opposite side to the fraction inlet plate. And the center of one side of the collecting outlet plate is provided with a large hole for connecting with an external pipeline of the immersion tank body. And a plurality of small holes are uniformly formed in the other side of the collecting outlet plate. The inner part of the collecting outlet plate is completely communicated, so that the insulating cooling liquid can be driven by the power pump to be collected by the plurality of small holes and then flows out of the immersion tank body from the large hole on the other side.

Preferably, the servers are uniformly arranged in the packaging box at equal intervals, phase-change materials are filled in gaps between every two adjacent servers and between the servers and the packaging box wall of the servers, and the heat pipes are inserted into the phase-change materials. The evaporation end of the heat pipe is arranged in the server packaging box, and the condensation end of the heat pipe is arranged outside the server packaging box.

Preferably, the inner surface of the heat pipe is designed into a porous structure or is provided with a plurality of channels, so that the power of the heat pipe working medium flowing back from the condensation end to the evaporation end is provided.

Preferably, the heat pipes may be arranged in an in-line or fork arrangement.

The invention has the following advantages:

1) The heat pipe is used for transporting heat generated by the server, liquid phase change heat transfer is utilized, and compared with conventional convection heat transfer, the heat pipe has higher heat dissipation response speed and higher heat dissipation efficiency, and can well solve the heat dissipation problem of the server with high heat flow density.

2) According to the invention, the server is packaged in the server packaging box filled with the phase-change material, so that the problem of unequal heat flux density generated by each part of the server can be solved, and the whole system has good temperature uniformity. Meanwhile, as the server packaging box is immersed in the insulating cooling liquid, the influence of dust and the like on the server is avoided, the operating environment of the server is greatly optimized, and the calculation performance and the service life of the server can be improved.

3) The scheme is free of fans, and meanwhile, the server is immersed in the insulating cooling liquid, so that noise can be effectively reduced.

4) This scheme combines together the cooling and the submergence formula liquid cooling of heat pipe condensation end, can cool off the condensation end of heat pipe fast high-efficiently, improves the radiating efficiency of whole server, guarantees that the server operates steadily high-efficiently for a long time.

5) The invention determines the length change of the condensation end of the heat pipe along the height direction according to a great deal of research, and determines an optimized design formula, so that the heat dissipation is more uniform, and the service life of the server is prolonged.

Description of the drawings:

FIG. 1 is a schematic structural diagram of the present embodiment;

FIG. 2 is a schematic diagram of a server enclosure box;

FIG. 3 is a schematic structural diagram of a section A of a server enclosure;

FIG. 4 is a schematic diagram showing the variation of the length of the condensation end of the heat pipe along the height direction

In the figure: 1. immersing the box body; 2. a liquid separating inlet plate; 3. a heat pipe; 4. a server packaging box; 5. a manifold outlet plate; 6. a server; 7. a condensing end; 8. an evaporation end; 9. a phase change material.

Detailed Description

FIG. 1 illustrates a heat pipe, phase change material, and immersed liquid cooling combined heat dissipation system. As shown in fig. 1, the system includes a box 1, a cooling liquid inlet, a cooling liquid outlet, a heat pipe 3, a power pump, a refrigerant source, and a packaging box 4, wherein the box 1 is filled with cooling liquid, the packaging box 4 is disposed in the box 1, the packaging box 4 includes a server 6 and a phase-change material 9, the server 6 is surrounded inside the phase-change material 9, an evaporation end 8 of the heat pipe 3 is disposed in the phase-change material 9, and a condensation end 7 of the heat pipe 3 extends out of the packaging box 4; the box body 1 is respectively provided with a cooling liquid inlet and a cooling liquid outlet for the cooling liquid to enter and exit the box body 1; the cooling liquid inlet and the cooling liquid outlet are respectively connected with a refrigerant source and a power pump through pipelines to form a heat dissipation cycle of 'the refrigerant source, the power pump, the cooling liquid inlet, the box body, the cooling liquid outlet, the power pump and the refrigerant source'.

The heat pipe, the phase change material and the immersion liquid cooling are combined to dissipate heat of the server, so that heat generated by the server is firstly transferred to the phase change material, the phase change material is subjected to phase change, then the heat is transferred to the condensation end through the evaporation end of the heat pipe, the evaporation end is transferred outwards from the condensation end, and then the evaporation end is transferred to the cooling liquid, so that the rapid heat dissipation of the server is realized.

According to the invention, the phase-change material is arranged to surround the server, more heat is absorbed through phase-change heat supply of the phase-change material and phase-change latent heat, and the temperature of the heat storage material is ensured to be constant, so that the temperature of the server can be ensured to be constant.

According to the invention, through the phase-change material, the temperature difference between different positions of the outer wall surface of the server and the phase-change material is kept basically the same, the integral heat dissipation is ensured to be uniform, and the local damage caused by nonuniform heat dissipation due to overlarge and overlong local temperature difference is avoided.

On one hand, the heat pipe is used for transporting heat generated by the server, liquid phase change heat transfer is utilized, the heat dissipation response speed is higher compared with that of conventional convection heat transfer, the heat dissipation efficiency is higher, and the heat dissipation problem of the server with high heat flow density can be well solved.

according to the invention, the server is packaged in the server packaging box filled with the phase-change material, so that the problem of unequal heat flux density generated by each part of the server can be solved, and the whole system has good temperature uniformity.

The invention has wide application range and can be used in extremely cold extreme environment. If set up in extremely cold extreme environment, because phase change material can play the heat accumulation effect simultaneously, through stopping the circulation of cooling liquid, perhaps through adding the hot-fluid, can also play certain heat preservation effect, avoid the server to stop the operation under extreme environment.

Preferably, the cooling fluid is an insulating cooling fluid. More preferably, the insulating coolant may be selected from FC-72, NOVEC insulating coolant, and the like. Through setting up insulating coolant liquid, can further guarantee the safety of system, avoid electric leakage.

Preferably, the outer wall surface of the packaging box is a heat conductor, and through the arrangement of the heat conductor on the outer wall surface and the insulating cooling liquid, the cooling liquid can directly contact with the outer wall surface of the packaging box to directly dissipate heat, so that the heat dissipation problem is better solved, and the heat dissipation effect is improved.

Preferably, the enclosure box 4 is immersed in the insulating cooling liquid and suspended and fixed by a bracket. Because the server packaging box 4 is immersed in the insulating cooling liquid, the influence of dust and the like on the server is avoided, the operating environment of the server is greatly optimized, and the computing performance and the service life of the server can be improved. And the lower part of the packaging box is also immersed in the cooling liquid through the suspension fixation of the bracket, so that the omnibearing heat dissipation is ensured.

Preferably, the appearance of the box body 1 is a cuboid container which is provided with a detachable upper cover with a corresponding size, so that the operations of installation, maintenance and the like of the immersed liquid cooling server can be facilitated. The whole immersed box body is completely installed in internal equipment, and strict sealing treatment is carried out before a server is put into use so as to ensure that the insulating cooling liquid is not leaked.

Further, the liquid separation inlet plate 2 is arranged at one end of the immersion tank body. And the center of one side of the liquid separation inlet plate is provided with a large hole for connecting with an external pipeline of the immersion box body. And a plurality of small holes are uniformly formed in the other side of the liquid separation inlet plate. The interior of the liquid separation inlet plate is completely communicated, so that insulating cooling liquid can enter from a large hole on one side and then flow out from a plurality of small holes on the other side under the driving of the power pump to enter the immersion box body. The liquid inlet flow can be more uniform by matching the big holes and the small holes.

further, said collecting outlet plate 5 is arranged on the opposite side to the separating inlet plate. And the center of one side of the collecting outlet plate is provided with a large hole for connecting with an external pipeline of the immersion tank body. And a plurality of small holes are uniformly formed in the other side of the collecting outlet plate. The inner part of the collecting outlet plate is completely communicated, so that the insulating cooling liquid can be driven by the power pump to be collected by the plurality of small holes and then flows out of the immersion tank body from the large hole on the other side. The liquid collection efficiency can be improved by matching the big holes and the small holes.

Further, the heat pipe comprises an evaporation end and a condensation end. Further, the server packaging box 4 contains a server, a heat pipe, a phase change material and the like. And a plurality of servers 6 are arranged in the server packaging box at equal intervals. The gaps between two adjacent servers 6 and the space between the servers and the server packaging box walls are filled with phase change materials, and a plurality of heat pipes 3 are inserted into the phase change materials 9. The evaporation end 8 of the heat pipe is arranged in the server packaging box 4, the condensation end 7 of the heat pipe is arranged outside the server packaging box 4, and the contact part of the heat pipe and the server packaging box is strictly sealed so as to realize the isolation between the inside and the outside of the server packaging box. The phase change material arranged in the server packaging box can be used for enabling the inside of the server packaging box to have good temperature uniformity.

The heat pipe is made of high-quality heat conducting material such as copper. And the evaporation end of the heat pipe is inserted into the phase change material filled in the server packaging box. And the condensation end of the heat pipe is positioned outside the server packaging box. The inner surface of the heat pipe is designed into a porous structure or is provided with a plurality of channels, so that the power of the heat pipe working medium flowing back from the condensation end to the evaporation end is provided. In order to further enhance the heat dissipation effect of the condensation end, other auxiliary heat dissipation measures can be implemented on the outer surface of the condensation end, such as: additionally adding a heat sink and the like. The working medium of the heat pipe can be selected from liquid ammonia, water, propane, organic refrigerants and the like.

Furthermore, the heat pipes can be arranged in a row or in a fork manner.

Further, the insulating cooling liquid can be selected from FC-72, NOVEC insulating cooling liquid and the like.

Furthermore, the insulating cooling liquid flows out of the immersion tank body and can be cooled by an external heat dissipation system, such as an air conditioner, a heat exchanger and the like, and the cooled insulating cooling liquid is driven by the power pump to return to the refrigerant source again.

Preferably, the condensation end of the heat pipe is arranged perpendicular to the wall surface of the package box 4.

Preferably, each wall surface of the packaging box is provided with a heat pipe condensation end.

Preferably, the servers are arranged along the height direction, and the phase change materials are also arranged along the height direction. The heat pipe is arranged in plurality in the height direction.

preferably, the heat pipe is arranged in a plurality of heat pipes along the height direction, and the length of the heat pipe condensation end extending out of the packaging box is increased along the height direction. The above results are obtained by a number of numerical simulations and experiments. Can make the heat dissipation more even, extension server life. Through theoretical analysis, because the encapsulation case submergence is in cooling liquid, consequently the cooling liquid in the encapsulation case can lead to the temperature of the liquid on upper portion to be higher than the lower part because the convection current, because the difference in temperature of upper portion and heat pipe condensation end just diminishes, lead to the heat transfer effect obviously to be less than the lower part, through the length that sets up the heat pipe condensation end constantly increase, make whole increase heat transfer area, thereby increase the heat dissipation capacity on upper portion, make whole upper portion lower part heat dissipation capacity even, avoid local high temperature, cause local damage. The technical feature that the length of the condensation end of the heat pipe is increased continuously is the result obtained by a large number of experiments and numerical simulation, and is an invention point of the application, and is not common knowledge in the field.

Further preferably, the length of the condensation end of the heat pipe increases along the height direction by a larger and larger range. This technical feature is the result obtained by a large number of experiments and numerical simulations, and is in accordance with the distribution of the liquid temperature, which is also an invention point of the present application, and is not common knowledge in the art.

preferably, the height of the packaging box is H, and along the height direction, the length of the condensation end of the heat pipe at the lowest end of the packaging box is L, and then the length L rule of the condensation end of the heat pipe at the position H away from the lowest end of the packaging box is as follows: l ═ L + b ═ L ═ H/H)^aWherein a and b are coefficients, and the following requirements are met:

1.23<a<1.45,0.35<b <0.38。

Preferably, a and b are gradually increased as H/H is increased.

Preferably, 1.30< a <1.38,0.36< b < 0.37.

Preferably, the heat pipes are arranged in a plurality along the height direction, and the distribution quantity of the condensation ends of the heat pipes extending out of the packaging box is increased along the height direction. The above results are obtained by a number of numerical simulations and experiments. Can make the heat dissipation more even, extension server life. Through theoretical analysis, because the encapsulation case submergence is in cooling liquid, consequently the cooling liquid in the encapsulation case can lead to the temperature of the liquid on upper portion to be higher than the lower part because the convection current, because the difference in temperature of upper portion and heat pipe condensation end just diminishes, lead to the heat transfer effect obviously to be less than the lower part, distribution density through setting up the heat pipe condensation end constantly increases, make whole increase heat transfer area, thereby increase the heat dissipation capacity on upper portion, make whole upper portion lower part heat dissipation capacity even, avoid local high temperature, cause local damage. The technical feature that the length of the condensation end of the heat pipe is increased continuously is the result obtained by a large number of experiments and numerical simulation, and is an invention point of the application, and is not common knowledge in the field.

Further preferably, the distribution density of the condensation end of the heat pipe is increased along the height direction by a larger and larger range. This technical feature is the result obtained by a large number of experiments and numerical simulations, and is in accordance with the distribution of the liquid temperature, which is also an invention point of the present application, and is not common knowledge in the art.

Preferably, the height of the packaging box is H, and along the height direction, the distribution density of the condensation end of the heat pipe at the lowest end of the packaging box is D, and the distribution density D rule of the condensation end of the heat pipe at the position H away from the lowest end of the packaging box is as follows:

d＝D+b*D*（h/H）^aWherein a and b are coefficients, and the following requirements are met:

1.3<a<1.5,0.34<b <0.37。

Preferably, a and b are gradually increased as H/H is increased.

Preferably, 1.38< a <1.42,0.35< b < 0.36.

Preferably, the heat pipe is a cylinder, and the diameter of the outer wall of the heat pipe is 50 mm;

The size of the packaging box is 950mm multiplied by 550mm multiplied by 400mm;

the immersion tank dimensions were 1000mm x 600mm x 1500 mm.

The server 6 generates heat when working, and the phase change material 9 is filled in the server packaging box 4, so that the inside of the whole server packaging box 4 has good temperature uniformity. The working medium at the evaporation end 8 of the heat pipe 3 is heated to change phase, and the heat is transferred to the condensation end 7 of the heat pipe 3, so that the heat dissipation of the server 6 is realized. Under the drive of the power pump, insulating cooling liquid in the refrigerant source enters the immersion box body 1 through the liquid separating inlet plate 2, and flows through the condensation end 7 of the heat pipe 3, so that heat generated by the server 6 is taken away. The temperature of the insulating cooling liquid rises while the heat is taken away by the insulating cooling liquid, the insulating cooling liquid flows out of the immersion tank body 1 through the flow collecting outlet plate 5 and is cooled through an external heat dissipation system such as an air conditioner, a heat exchanger and the like, and the cooled insulating cooling liquid is driven by the power pump to return to the refrigerant source again. The whole server heat dissipation scheme forms a heat dissipation circulation of insulating cooling liquid from a refrigerant source, a power pump, a liquid separation inlet plate, an immersion box body, a liquid collection outlet plate, the power pump and the refrigerant source.

Although the present invention has been described with reference to the preferred embodiments, it is not limited thereto. Various changes and modifications may be effected therein by one skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.