CN114390852B - A heat dissipation and cooling device for a computer room, and a computer room - Google Patents

Abstract

The invention belongs to the technical field of heat dissipation and cooling of machine rooms, and particularly relates to heat dissipation and cooling equipment of a machine room and the machine room. In the equipment for cooling the heat dissipation of the machine room, a supporting plate is used for placing a cabinet, an air conditioner is placed below the supporting plate, a liquid outlet of a machine unit is communicated with a liquid inlet end of a liquid conveying main pipe, a liquid inlet of the machine unit is communicated with a liquid outlet end of a liquid returning main pipe, a cooling liquid inlet is communicated with a cooling tower outlet, a cooling liquid outlet is communicated with a cooling tower inlet, a cooling plate coil pipe is provided with a liquid inlet and a liquid outlet, a liquid inlet is replaced by a first plate and is communicated with an air conditioner liquid outlet, a liquid outlet is replaced by the first plate and is communicated with the liquid returning main pipe, a liquid outlet end of a cooling circulation pipeline is communicated with the liquid inlet, a liquid inlet end of the cooling circulation pipeline is communicated with the liquid outlet, and the air conditioner liquid inlet is communicated with the liquid conveying main pipe. By the aid of the technical scheme, the problem that in the prior art, heat in a machine room cannot be taken away timely, so that the temperature in the machine room is high, and normal and effective operation of a server is affected is solved.

Description

Cooling equipment and computer lab of computer lab heat dissipation

Technical Field

The invention belongs to the technical field of heat dissipation and cooling of machine rooms, and particularly relates to heat dissipation and cooling equipment of a machine room and the machine room.

Background

At present, information technology, particularly internet technology, is increasingly developed, and network communication and unprecedented development of big data enable people to be connected together through network data. Thus, the use of servers is indispensable for better implementation of data storage. The servers are uniformly arranged in the machine room, and in the use process of the servers, the servers can generate a large amount of heat, and as the machine room is a sealed machine room space, the heat cannot be naturally emitted, and auxiliary heat dissipation is needed by using a technical means. In the prior art, cold air is blown into a machine room by using an air conditioner, heat generated by a server is taken away through cold air circulation to realize heat dissipation and temperature reduction of the machine room, however, due to unprecedented development of big data, the data required to be stored is larger and the capacity of the server is larger and larger, so that the number of the required servers is larger and larger, the heat in the machine room cannot be taken away in time, the temperature in the machine room is higher, and the normal and effective operation of the server is influenced.

Disclosure of Invention

The invention aims to provide a machine room cooling device and a machine room, and aims to solve the problems that in the prior art, heat in the machine room cannot be taken away timely, so that the temperature in the machine room is high, and the normal and effective operation of a server is affected.

The cooling equipment comprises a supporting plate, wherein the supporting plate is used for accommodating cabinets, a plurality of cabinets form a plurality of rows which are spaced apart, a cover plate is connected to the tops of every two adjacent rows of cabinets, the supporting plate and the cover plate form channels, two sides of each row of cabinets are respectively provided with a hot channel and a cold channel, the air conditioner is arranged below the supporting plate in a one-to-one correspondence manner, the air conditioner is provided with an air inlet and an air outlet, the air inlet is used for sucking hot air of the heat channel, the air outlet is used for blowing cold air to the cold channel, the cooling equipment further comprises an external heat release device, an infusion main pipe and a liquid return main pipe, the external heat release device, a cooling tower and a water cooling unit, the infusion main pipe and the liquid return main pipe are all communicated with the external heat release device to form a circulation flow path, the infusion main pipe is used for providing a cooling fluid cooling tower inlet and a cooling tower outlet, the water cooling unit is provided with a unit liquid inlet, the unit liquid outlet, the cooling liquid inlet is communicated with the cooling tower cooling plate, the cooling liquid outlet is communicated with the cooling tower through a connecting pipeline, the unit liquid inlet is communicated with the cooling liquid inlet and the cooling tower cooling plate, the cooling liquid inlet is communicated with the cooling liquid inlet, the cooling liquid inlet is communicated with the cooling liquid outlet, and the cooling liquid outlet is communicated with the cooling liquid cooling plate through the cooling plate, and the cooling liquid inlet, and the cooling liquid outlet is communicated with the cooling liquid outlet through the cooling plate.

Optionally, the first refrigerator, first refrigerator have first board change inlet, first board change outlet and first heat transfer flow path, and the play liquid end and the inlet intercommunication of first heat transfer flow path, the inlet and the play liquid interface intercommunication of first heat transfer flow path, air conditioner liquid outlet and first board change inlet intercommunication, board change outlet and return liquid house steward intercommunication.

Optionally, a first adjusting valve is arranged on a pipeline between the liquid outlet of the air conditioner and the liquid inlet of the first plate.

Optionally, an adjusting branch pipe is connected to a pipeline between the first plate liquid inlet and the first adjusting valve, the other end of the adjusting branch pipe is communicated with the infusion main pipe, and a second adjusting valve is arranged on the adjusting branch pipe.

Optionally, the outlet of the cooling tower is communicated with the liquid inlet end of the liquid delivery main pipe, the inlet of the cooling tower is communicated with the liquid outlet end of the liquid return main pipe, a valve A is arranged between the outlet of the cooling tower and the liquid inlet end of the liquid delivery main pipe, and a valve B is arranged between the inlet of the cooling tower and the liquid outlet end of the liquid return main pipe.

Optionally, a valve C is arranged between a liquid outlet of the unit and a liquid inlet end of the liquid conveying main pipe, a valve D is arranged between a liquid inlet of the unit and a liquid outlet end of the liquid return main pipe, a valve E is arranged between a cooling tower outlet and a cooling liquid inlet, and a valve F is arranged between a cooling tower inlet and a cooling liquid outlet.

Optionally, the heat dissipation and cooling device of the machine room further comprises a control module, wherein the valve A, the valve B, the valve C, the valve D, the valve E, the valve F, the first adjusting valve and the second adjusting valve are electromagnetic control valves, the control module is electrically connected with the valve A, the valve B, the valve C, the valve D, the valve E, the valve F, the first adjusting valve and the second adjusting valve, and the control module controls the air conditioner to operate.

Optionally, a second refrigerator and a compressor are arranged in the air conditioner, the second refrigerator is provided with a second plate liquid exchange inlet, a second plate liquid exchange outlet and a second heat exchange flow path, the second plate liquid exchange inlet is communicated with the infusion main pipe, the second plate liquid exchange outlet is communicated with the liquid return main pipe, the liquid outlet end of the second heat exchange flow path is communicated with the evaporator inlet of the air conditioner, the liquid inlet end of the second heat exchange flow path is communicated with the evaporator outlet of the air conditioner, and the compressor is arranged on a connecting pipe between the liquid inlet end of the second heat exchange flow path and the evaporator outlet of the air conditioner.

According to another aspect of the invention, a machine room is provided. The machine room comprises the machine room heat dissipation and cooling equipment, the supporting plate is used as the floor of the machine room, the plurality of cabinets are placed in the machine room to form a plurality of rows, the adjacent two rows of cabinets and the ceiling of the machine room, the supporting plate form channels, the channels on two sides of each row of servers are respectively a hot channel and a cold channel, one row of air conditioner corresponds to one row of cabinets, the air conditioner is provided with an air inlet and an air outlet, the air inlet is communicated with the hot channel, and the air outlet is communicated with the cold channel.

The invention has at least the following beneficial effects:

In the invention, the heat dissipation and cooling are realized simultaneously by using the air conditioner and the first heat exchange flow path of the first refrigerator, compared with the prior art, the heat dissipation and cooling are realized more effectively, the heat remained in the machine room can be carried away more timely and rapidly, the purpose of timely and rapidly dissipating the heat and cooling the machine room is achieved, in the process of arranging the pipelines of the machine room, the air conditioner, the first refrigerator, the infusion main and the liquid return main are connected in series by adopting the pipelines, so that the air conditioner and the first refrigerator can integrally use the same refrigerating liquid for heat exchange, the integral pipeline arrangement structure of the machine room is simplified while the heat can be effectively taken away, the use amount of the refrigerating liquid is saved, and the cost is saved.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are needed in the embodiments or the description of the prior art will be briefly described below, it being obvious that the drawings in the following description are only some embodiments of the present invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic diagram of an assembly of an air conditioning system for a machine room according to an embodiment of the present invention;

fig. 2 is a schematic diagram of a piping arrangement of a first embodiment of the air conditioning system for a machine room according to the present invention;

Fig. 3 is a schematic diagram of a deformed structure of a piping arrangement of a first embodiment of the air conditioning system for a machine room according to the present invention;

Fig. 4 is a schematic view of another modified structure of the piping arrangement of the first embodiment of the air conditioning system for a machine room according to the present invention;

fig. 5 is a schematic diagram of a piping arrangement of a second embodiment of the air conditioning system for a machine room according to the present invention;

Fig. 6 is a schematic diagram of a modified structure of a piping arrangement of a second embodiment of the air conditioning system for a machine room according to the present invention;

fig. 7 is a schematic diagram of another modified structure of the piping arrangement of the second embodiment of the air conditioning system for a machine room according to the present invention;

fig. 8 is a schematic diagram of a piping arrangement of a third embodiment of the air conditioning system for a machine room according to the present invention;

fig. 9 is a schematic diagram of a modified structure of a piping arrangement of a third embodiment of the air conditioning system for a machine room according to the present invention;

fig. 10 is a schematic diagram of another modified structure of the piping arrangement of the third embodiment of the air conditioning system for a machine room according to the present invention.

Wherein, each reference sign in the figure:

10. The device comprises a cabinet, 100, a supporting plate, 101, a hot channel, 102, a cold channel, 103, a channel door, 20, an air conditioner, 21, an air inlet, 22, an air outlet, 23, an air conditioner liquid inlet, 24, an air conditioner liquid outlet, 31, a transfusion main pipe, 32, a liquid return main pipe, 310, a cooling tower, 311, a cooling tower inlet, 312, a cooling tower outlet, 320, a water cooling unit, 321, a unit liquid inlet, 322, a unit liquid outlet, 40, a cold plate coil, 41, a liquid inlet, 42, a liquid outlet, 50, a first refrigerator, 51, a first plate liquid inlet, 52, a first plate liquid outlet, 53, a heat exchange flow path, 61, a valve A, 62, a valve B, 63, a valve C, 64, a valve D, 66, a valve E, 65, a valve F, 201, a first regulating valve 202, a regulating branch pipe, 203, a second regulating valve, 301, a second refrigerator, 302 and a compressor.

Detailed Description

Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present invention and should not be construed as limiting the invention.

In the description of the present invention, it should be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present invention and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present invention.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first", "a second", etc. may explicitly or implicitly include one or more such feature. In the description of the present invention, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In the present invention, unless explicitly specified and limited otherwise, the terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally formed, mechanically connected, electrically connected, directly connected, indirectly connected via an intervening medium, or in communication between two elements or in an interaction relationship between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

As shown in fig. 1 and 2, the room air conditioning system provided by the first embodiment of the present invention includes a support plate 100, a plurality of cabinets 10, and a plurality of air conditioners 20, and further includes an external heat discharging device and a cold plate coil 40. In the assembly and arrangement process, a plurality of cabinets 10 are placed on a supporting plate 100 (the supporting plate 100 is the floor of a machine room space) to form a plurality of rows, two adjacent rows of cabinets 10 and the ceiling and floor of the machine room space form channels, and the channel openings of the channels formed between the two adjacent rows of cabinets 10 are respectively provided with a closed channel door 103, two side channels of a row of servers are respectively a hot channel 101 and a cold channel 102, that is, the hot channel 101 corresponds to the hot air side of the cabinet 10, and the cold channel 102 corresponds to the cold air side of the cabinet 10, wherein the two rows of cabinets 10 close to two side walls of the machine room space respectively form the hot channel 101 or the cold channel 102 with the walls. A plurality of air conditioners 20 are placed under the support plate 100 to form a plurality of columns, and one column of air conditioners 20 corresponds to one column of cabinets 10. In a specific configuration air path circulation process, the air conditioner 20 has an air inlet 21 and an air outlet 22, the air inlet 21 is communicated with the heat channel 101, the air outlet 22 is communicated with the cold channel 102 (i.e. the air inlet sucks hot air on a hot air side and the air outlet blows cold air to a cold air side), in this way, cold air blown out of the air outlet 22 of the air conditioner 20 enters the cold channel 102, then the cold air flows through the cabinet 10 to take away heat, air flows into the heat channel 101, and hot air in the heat channel 101 is sucked by the air conditioner 20 and circulates from the air inlet 21 into a heat exchanger of the air conditioner 20 for circulation heat exchange, so that cold air is formed again and blown out of the air outlet 22. Further, the air conditioning system for a machine room of the first embodiment further includes a fluid infusion main 31 and a liquid return main 32, the fluid infusion main 31 is used for providing a refrigerating fluid, the fluid infusion main 31 and the liquid return main 32 are both extended to the air conditioner 20, the cold plate coil 40 has a liquid inlet 41 and a liquid outlet 42, and the cold plate coil 40 is disposed on the cabinet 10, so that when the air conditioner 20 is used for blowing cold air to the cabinet 10 for cooling, the cold plate coil 40 is used for realizing secondary heat dissipation and cooling, which is more beneficial to the heat dissipation and cooling effect of the air conditioning system for the whole machine room. The air conditioner 20 further has an air conditioner liquid inlet 23 and an air conditioner liquid outlet 24, the air conditioner liquid inlet 23 is communicated with the transfusion main 31, the air conditioner liquid outlet 24 is communicated with the liquid inlet 41, and the liquid outlet 42 is communicated with the liquid return main 32, so that a series mode is formed between the air conditioner 20 and the cold plate coil 40, that is, the air conditioner 20 and the cold plate coil 40 use the same refrigerating fluid to perform heat exchange work to take away heat generated by the server, and heat dissipation and cooling are realized for the server.

In the invention, the heat dissipation and the temperature reduction are realized on the cabinet 10 by using the air conditioner 20 and the cold plate coil 40 simultaneously, compared with the prior art, the heat dissipation and the temperature reduction are realized on the cabinet 10 more effectively, the heat remained in the machine room can be carried away more timely and quickly, the purpose of timely and quickly dissipating the heat and the temperature of the machine room is achieved, in the pipeline arrangement process of the air conditioner system of the machine room, the air conditioner 20 and the cold plate coil 40 can be integrally subjected to heat exchange work by adopting the pipeline series connection between the air conditioner 20 and the cold plate coil 40, the integral pipeline arrangement structure of the air conditioner system of the machine room is simplified while the heat can be effectively taken away, the consumption of the refrigerating fluid is saved, and the cost is saved.

In the first embodiment, the machine room air conditioning system further includes a first refrigerator 50, the first refrigerator 50 is detachably hung on the housing of the air conditioner 20, and the first refrigerator 50 is located under the support plate 100 together with the air conditioner 20. Specifically, the first refrigerator 50 has a first plate change liquid inlet 51, a first plate change liquid outlet 52, and a first heat exchange flow path 53, the first plate change liquid inlet 51 communicates with the air conditioner liquid outlet 24, the first plate change liquid outlet 52 communicates with the liquid return manifold 32, the liquid outlet end of the first heat exchange flow path 53 communicates with the liquid inlet port 41, and the liquid inlet end of the first heat exchange flow path 53 communicates with the liquid outlet port 42. By arranging the first refrigerator 50, the second-stage cooling circulation independent of the air conditioner 20 is arranged between the cold plate coil 40 and the first refrigerator 50, heat exchange is performed between the cold plate coil 40 and the cabinet 10, and the refrigerating fluid conveyed by the infusion main pipe 31 exchanges heat, so that heat dissipation and temperature reduction are more effectively realized.

In the present application, the first refrigerator 50 may be a plate heat exchanger, a double pipe heat exchanger, a tank heat exchanger, or the like.

The first refrigerator 50 may be optionally installed in the system as an optional module, in order to shorten the length of the connecting pipeline in the optional process, so that the air conditioner liquid inlet 23 and the air conditioner liquid outlet 24 are all arranged at the same side position of the air conditioner 20, the first refrigerator 50 is hung on the side position of the air conditioner 20 where the air conditioner liquid inlet 23 and the air conditioner liquid outlet 24 are arranged, the first plate liquid exchange inlet 51 and the first plate liquid exchange outlet 52 of the first refrigerator 50 are all arranged at the same side of the first refrigerator 50, then the pipeline connected from the first plate liquid exchange inlet 51 is communicated with the air conditioner liquid outlet 24, and the pipeline connected from the first plate liquid exchange outlet 52 is communicated with the liquid return main 32. In this way, whether or not the first refrigerator 50 as the optional module is optionally installed to the system, the relative positions of the air conditioner 20, the infusion main 31 and the return main 32 are not affected, and the installation is convenient.

As shown in fig. 2, in the room air conditioning system of the first embodiment, the external heat discharging device specifically uses the cooling tower 310 to store the refrigerant liquid and to realize the circulation, and in the present invention, uses water as the refrigerant liquid, the cooling tower 310 supplies the circulating refrigerant water to the pipes of the room air conditioning system, and the heat exchange is realized in the air conditioner 20 and the cold plate coil 40 by the circulating water flowing. In a specific assembly process, the cooling tower 310 is placed outside the machine room space, the cooling tower 310 is provided with a cooling tower inlet 311 and a cooling tower outlet 312, the cooling tower outlet 312 is communicated with the liquid inlet end of the liquid conveying main pipe 31, and the cooling tower inlet 311 is communicated with the liquid outlet end of the liquid return main pipe 32. The water is used as the refrigerating fluid, so that the cost can be effectively saved, and the popularization and the use of the air conditioning system of the machine room are facilitated.

The cooling tower 310 may be a water cooling tower, an air cooling tower, or a cooling tower that uses other refrigerant media to exchange heat.

Further, in the air conditioning system for a machine room of the first embodiment, a valve a61 is disposed between the cooling tower outlet 312 and the liquid inlet end of the liquid delivery manifold 31, and a valve B62 is disposed between the cooling tower inlet 311 and the liquid outlet end of the liquid return manifold 32. In this way, the cooling tower 310 and the pipelines in the air conditioning system of the machine room can be switched on and off through the valve A61 and the valve B62, and when the air conditioner 20 or the cold plate coil 40 needs to be maintained and replaced, the valve A61 and the valve B62 are closed to cut off the circulating water, and then maintenance and replacement work is performed, so that the circulating water does not flow into the space of the machine room any more, and the work is convenient.

As shown in fig. 2, a water pump is provided on a connection line between the cooling tower 310 and the liquid return main pipe 32, and a water pump is provided on a connection line between the liquid outlet end of the first heat exchange flow path 53 and the liquid inlet port 41, and the circulating water flow power is supplied by the water pump.

In the first embodiment, in order to realize overall automatic monitoring and control, the control module is used to realize control of the valve a61, the valve B62 and the air conditioner 20, and intelligent automatic control of the machine room air conditioning system is realized. The control module is only required to be a control system capable of realizing intelligent internet of things control, and is popular in the prior art, so that the description is omitted here.

As shown in fig. 3, which is a schematic structural view of a variation of the piping arrangement of the first embodiment. Specifically, a first adjusting valve 201 is disposed on a pipeline between the first plate changing liquid inlet 51 and the air conditioner liquid outlet 24, so that in the working process of the heat dissipation and cooling device of the air conditioner system of the machine room, when the air conditioner 20 blows cold air into the air conditioner system of the machine room to take away heat generated by the machine cabinet 10, and simultaneously, the cold plate coil 40 is utilized to take away heat generated by the machine cabinet 10, the flow and the flow speed of the refrigerating fluid between the pipeline of the air conditioner 20 and the pipeline of the first refrigerator 50 can be adjusted through the first adjusting valve 201, when the machine cabinet 10 heats less, the small flow is controlled, and when the machine cabinet 10 heats severely, the large flow refrigerating fluid is opened to meet the heat dissipation and cooling requirement. Thus, the power consumption is saved, the energy is saved, and the cost is reduced.

Further, in the modified structure of the first embodiment, an adjustment branch pipe 202 is connected to a line between the first plate change inlet 51 and the first adjustment valve 201, the other end of the adjustment branch pipe 202 communicates with the infusion manifold 31, and a second adjustment valve 203 is provided to the adjustment branch pipe 202. In the process of radiating and cooling the cabinet 10, when the cabinet 10 generates heat violently, the second regulating valve 203 can be opened at this time to supplement the liquid to the first refrigerator 50 from the infusion main pipe 31, so that the flow and the flow rate of the refrigerating liquid entering the first refrigerator 50 are increased, the heat exchange between the first refrigerator 50 and the cold plate coil 40 is faster and more efficient, more heat of the cabinet 10 can be taken away, and the radiating and cooling effect of the cold plate coil 40 on the cabinet 10 is enhanced. Generally, the serial connection of the air conditioner 20 and the cold plate coil 40 can meet the heat dissipation and cooling requirements, so the second regulating valve 203 is normally closed (i.e. the regulating branch pipe 202 is disconnected and cannot pass the refrigerant fluid).

The modified structure is the same except that the above structure is different from the first embodiment.

As shown in fig. 4, which is a schematic structural view of another variation of the piping arrangement of the first embodiment. The air conditioner 20 is internally provided with a second refrigerator 301 and a compressor 302, the second refrigerator 301 is provided with a second plate liquid exchange inlet, a second plate liquid exchange outlet and a second heat exchange flow path, the second plate liquid exchange inlet is communicated with the transfusion main pipe 31, the second plate liquid exchange outlet is communicated with the liquid return main pipe 32, the liquid outlet end of the second heat exchange flow path is communicated with the evaporator inlet of the air conditioner 20, and the cooling liquid output by the cooling tower 310 flows through the second refrigerator 301 for heat exchange. The liquid inlet end of the second heat exchange flow path is communicated with the evaporator outlet of the air conditioner 20, the compressor 302 is arranged on a connecting pipeline between the liquid inlet end of the second heat exchange flow path and the evaporator outlet of the air conditioner 20, the compressor 302 compresses the refrigerating fluid in the second heat exchange flow path and sends the refrigerating fluid to the evaporator of the air conditioner 20 for refrigeration, and then the refrigerating fluid flows back to the second refrigerator 301 for heat exchange with the cooling liquid conveyed by the cooling tower 310, and then the cooling liquid takes away heat, so that heat dissipation and cooling are realized. Further, a flow regulating valve can be arranged on the connecting pipeline between the infusion main pipe 31 and the second plate liquid inlet, so that the energy consumption can be saved by regulating according to the refrigerating output requirement of the air conditioner 20.

In the present application, the second refrigerator 301 may be a plate heat exchanger, a double pipe heat exchanger, a tank heat exchanger, or the like.

As shown in fig. 5, a schematic diagram of a piping arrangement according to a second embodiment of the present invention is shown. Among them, the room air conditioning system of the second embodiment has the following differences from the room air conditioning system of the first embodiment.

In the machine room air conditioning system of the second embodiment, the cooling tower 310 and the water cooling unit 320 are specifically used by the external heat-releasing device at the same time, wherein the cooling tower 310 is mainly responsible for cooling the water cooling unit 320, and the water cooling unit 320 provides circulating cooling water for the pipes in the machine room air conditioning system to cool the cabinet 10. In the concrete assembly process, the cooling tower 310 is provided with a cooling tower inlet 311 and a cooling tower outlet 312, the water cooling unit 320 is provided with a unit liquid inlet 321, a unit liquid outlet 322, a cooling liquid inlet and a cooling liquid outlet, the unit liquid outlet 322 is communicated with the liquid inlet end of the infusion main pipe 31, the unit liquid inlet 321 is communicated with the liquid outlet end of the liquid return main pipe 32, the cooling liquid inlet is communicated with the cooling tower outlet 312, and the cooling liquid outlet is communicated with the cooling tower inlet 311.

Further, a valve C63 is arranged between the unit liquid outlet 322 and the liquid inlet end of the liquid conveying main pipe 31, a valve D64 is arranged between the unit liquid inlet 321 and the liquid outlet end of the liquid return main pipe 32, a valve E66 is arranged between the cooling tower outlet 312 and the cooling liquid inlet, and a valve F65 is arranged between the cooling tower inlet 311 and the cooling liquid outlet. The cooling tower 310 and the pipelines in the air conditioning system of the machine room are connected and disconnected through the valve C63 and the valve D64, and when the air conditioner 20 or the cold plate coil 40 needs to be maintained and replaced, the valve C63 and the valve D64 are closed to cut off the circulating water, and then maintenance and replacement work is carried out, so that the circulating water does not flow into the space of the machine room any more, and the work is convenient. The on/off of the pipeline between the cooling tower 310 and the water cooling unit 320 is realized through the valve E66 and the valve F65, and when the water cooling unit 320 needs to be maintained and replaced, the circulating water is cut off through closing the valve E66 and the valve F65, and then maintenance and replacement work is carried out. Correspondingly, the control module is also electrically connected with the valve C63, the valve D64, the valve E66 and the valve F65 so as to realize intelligent automatic control.

As shown in fig. 5, a pump is arranged on a connecting pipeline between the cooling tower 310 and the liquid return main pipe 32, a water pump is arranged on a connecting pipeline between the liquid outlet end of the first heat exchange flow path 53 and the liquid inlet port 41, a water pump is arranged between the water cooling unit 320 and the liquid return main pipe 32, circulating water flow power is provided by adopting the pump, and the water cooling unit 320 is provided with a pump for providing output and backflow power for circulating water.

The second embodiment is identical to the first embodiment except for the above structure, and thus will not be described herein.

As shown in fig. 6, a schematic diagram of a circuit arrangement of a second embodiment of the present invention is shown. Specifically, a first adjusting valve 201 is disposed on a pipeline between the first plate changing liquid inlet 51 and the air conditioner liquid outlet 24, so that in the working process of the heat dissipation and cooling device of the air conditioner system of the machine room, when the air conditioner 20 blows cold air into the air conditioner system of the machine room to take away heat generated by the machine cabinet 10, and simultaneously, the cold plate coil 40 is utilized to take away heat generated by the machine cabinet 10, the flow and the flow speed of the refrigerating fluid between the pipeline of the air conditioner 20 and the pipeline of the first refrigerator 50 can be adjusted through the first adjusting valve 201, when the machine cabinet 10 heats less, the small flow is controlled, and when the machine cabinet 10 heats severely, the large flow refrigerating fluid is opened to meet the heat dissipation and cooling requirement. Thus, the power consumption is saved, the energy is saved, and the cost is reduced.

Further, in the modified structure of the first embodiment, an adjustment branch pipe 202 is connected to a line between the first plate change inlet 51 and the first adjustment valve 201, the other end of the adjustment branch pipe 202 communicates with the infusion manifold 31, and a second adjustment valve 203 is provided to the adjustment branch pipe 202. In the process of radiating and cooling the cabinet 10, when the cabinet 10 generates heat violently, the second regulating valve 203 can be opened at this time to supplement the liquid to the first refrigerator 50 from the infusion main pipe 31, so that the flow and the flow rate of the refrigerating liquid entering the first refrigerator 50 are increased, the heat exchange between the first refrigerator 50 and the cold plate coil 40 is faster and more efficient, more heat of the cabinet 10 can be taken away, and the radiating and cooling effect of the cold plate coil 40 on the cabinet 10 is enhanced. Generally, the serial connection of the air conditioner 20 and the cold plate coil 40 can meet the heat dissipation and cooling requirements, so the second regulating valve 203 is normally closed (i.e. the regulating branch pipe 202 is disconnected and cannot pass the refrigerant fluid). Wherein the modified structure is the same except that the above structure is different from the third embodiment.

As shown in fig. 7, another alternative construction of the piping arrangement of the second embodiment of the present invention is shown. The air conditioner 20 is internally provided with a second refrigerator 301 and a compressor 302, the second refrigerator 301 is provided with a second plate liquid exchange inlet, a second plate liquid exchange outlet and a second heat exchange flow path, the second plate liquid exchange inlet is communicated with the transfusion main pipe 31, the second plate liquid exchange outlet is communicated with the liquid return main pipe 32, the liquid outlet end of the second heat exchange flow path is communicated with the evaporator inlet of the air conditioner 20, and the cooling liquid output by the cooling tower 310 flows through the second refrigerator 301 for heat exchange. The liquid inlet end of the second heat exchange flow path is communicated with the evaporator outlet of the air conditioner 20, the compressor 302 is arranged on a connecting pipeline between the liquid inlet end of the second heat exchange flow path and the evaporator outlet of the air conditioner 20, the compressor 302 compresses the refrigerating fluid in the second heat exchange flow path and sends the refrigerating fluid to the evaporator of the air conditioner 20 for refrigeration, and then the refrigerating fluid flows back to the second refrigerator 301 for heat exchange with the cooling liquid conveyed by the cooling tower 310, and then the cooling liquid takes away heat, so that heat dissipation and cooling are realized. Further, a flow regulating valve can be arranged on the connecting pipeline between the infusion main pipe 31 and the second plate liquid inlet, so that the energy consumption can be saved by regulating according to the refrigerating output requirement of the air conditioner 20.

As shown in fig. 8, a schematic diagram of a piping arrangement of an air conditioning system for a machine room according to a third embodiment of the present invention is shown. The room air conditioning system of the third embodiment has the following differences from the room air conditioning system of the second embodiment.

In the air conditioning system for a machine room of the third embodiment, the cooling tower outlet 312 is communicated with the liquid inlet end of the liquid delivery manifold 31, the cooling tower inlet 311 is communicated with the liquid outlet end of the liquid return manifold 32, the valve a61 is arranged between the cooling tower outlet 312 and the liquid inlet end of the liquid delivery manifold 31, and the valve B62 is arranged between the cooling tower inlet 311 and the liquid outlet end of the liquid return manifold 32, so that the cooling tower 310 and the water cooling unit 320 can be turned on or off through the valve a61 and the valve B62, and when the water cooling unit 320 needs to be maintained, the circulating water is cut off by closing the valve a61 and the valve B62. A valve E66 is arranged between the cooling tower outlet 312 and the cooling liquid inlet, a valve F65 is arranged between the cooling tower inlet 311 and the cooling liquid outlet, and through controlling the valve E66, the valve F65, the valve C63 and the valve D64, the valve E66 and the valve F65 are simultaneously opened and closed, and the valve C63 and the valve D64 are simultaneously opened and closed, so that the pipeline communication between the cooling tower 310 and the machine room air conditioning system and the pipeline communication between the water cooling unit 320 and the machine room air conditioning system can be switched.

When switching to the cooling tower 310 to communicate with the machine room air conditioning system, valve a61 and valve B62 are simultaneously opened, and valve C63, valve D64, valve E66, and valve F65 are simultaneously closed.

In order to further realize automatic control, therefore, the machine room air conditioning system of the fourth embodiment further includes a control module, where the valve a61, the valve B62, the valve C63, the valve D64, the valve E66, and the valve F65 are all electromagnetic control valves, and the control module is electrically connected to the valve a61, the valve B62, the valve C63, the valve D64, the valve E66, and the valve F65, and the control module controls the air conditioner 20 to operate.

As shown in fig. 9, which is a schematic structural view of a variation of the piping arrangement of the third embodiment. Specifically, a first adjusting valve 201 is disposed on a pipeline between the first plate changing liquid inlet 51 and the air conditioner liquid outlet 24, so that in the working process of the heat dissipation and cooling device of the air conditioner system of the machine room, when the air conditioner 20 blows cold air into the air conditioner system of the machine room to take away heat generated by the machine cabinet 10, and simultaneously, the cold plate coil 40 is utilized to take away heat generated by the machine cabinet 10, the flow and the flow speed of the refrigerating fluid between the pipeline of the air conditioner 20 and the pipeline of the first refrigerator 50 can be adjusted through the first adjusting valve 201, when the machine cabinet 10 heats less, the small flow is controlled, and when the machine cabinet 10 heats severely, the large flow refrigerating fluid is opened to meet the heat dissipation and cooling requirement. Thus, the power consumption is saved, the energy is saved, and the cost is reduced.

Further, in the modified structure of the first embodiment, an adjustment branch pipe 202 is connected to a line between the first plate change inlet 51 and the first adjustment valve 201, the other end of the adjustment branch pipe 202 communicates with the infusion manifold 31, and a second adjustment valve 203 is provided to the adjustment branch pipe 202. In the process of radiating and cooling the cabinet 10, when the cabinet 10 generates heat violently, the second regulating valve 203 can be opened at this time to supplement the liquid to the first refrigerator 50 from the infusion main pipe 31, so that the flow and the flow rate of the refrigerating liquid entering the first refrigerator 50 are increased, the heat exchange between the first refrigerator 50 and the cold plate coil 40 is faster and more efficient, more heat of the cabinet 10 can be taken away, and the radiating and cooling effect of the cold plate coil 40 on the cabinet 10 is enhanced. Generally, the serial connection of the air conditioner 20 and the cold plate coil 40 can meet the heat dissipation and cooling requirements, so the second regulating valve 203 is normally closed (i.e. the regulating branch pipe 202 is disconnected and cannot pass the refrigerant fluid). Wherein the modified structure is the same except that the above structure is different from the fourth embodiment.

As shown in fig. 10, another alternative construction of the piping arrangement of the third embodiment of the present invention is shown. The air conditioner 20 is internally provided with a second refrigerator 301 and a compressor 302, the second refrigerator 301 is provided with a second plate liquid exchange inlet, a second plate liquid exchange outlet and a second heat exchange flow path, the second plate liquid exchange inlet is communicated with the transfusion main pipe 31, the second plate liquid exchange outlet is communicated with the liquid return main pipe 32, the liquid outlet end of the second heat exchange flow path is communicated with the evaporator inlet of the air conditioner 20, and the cooling liquid output by the cooling tower 310 flows through the second refrigerator 301 for heat exchange. The liquid inlet end of the second heat exchange flow path is communicated with the evaporator outlet of the air conditioner 20, the compressor 302 is arranged on a connecting pipeline between the liquid inlet end of the second heat exchange flow path and the evaporator outlet of the air conditioner 20, the compressor 302 compresses the refrigerating fluid in the second heat exchange flow path and sends the refrigerating fluid to the evaporator of the air conditioner 20 for refrigeration, and then the refrigerating fluid flows back to the second refrigerator 301 for heat exchange with the cooling liquid conveyed by the cooling tower 310, and then the cooling liquid takes away heat, so that heat dissipation and cooling are realized. Further, a flow regulating valve can be arranged on the connecting pipeline between the infusion main pipe 31 and the second plate liquid inlet, so that the energy consumption can be saved by regulating according to the refrigerating output requirement of the air conditioner 20.

In summary, the fourth embodiment is identical to the third embodiment except for the above structure, and thus will not be described in detail herein.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the invention.

Claims (7)

1. A machine room heat dissipation and cooling device, comprising:

The support plate is used for placing a cabinet, and two opposite sides of the cabinet are respectively a hot air side and a cold air side;

The air conditioners are arranged below the supporting plates in one-to-one correspondence with the cabinets, suck hot air at hot air sides, and blow cold air to cold air sides;

The machine room cooling system is characterized by further comprising:

The cooling device comprises external heat release equipment, a liquid conveying main pipe, a liquid return main pipe, a cooling tower and a water cooling unit, wherein the liquid conveying main pipe and the liquid return main pipe extend to the air conditioner, the liquid conveying main pipe and the liquid return main pipe are communicated with the external heat release equipment to form a circulating flow path, the liquid conveying main pipe is used for providing cooling fluid, the cooling tower is provided with a cooling tower inlet and a cooling tower outlet, the water cooling unit is provided with a unit liquid inlet, a unit liquid outlet, a cooling liquid inlet and a cooling liquid outlet, the unit liquid outlet is communicated with the liquid conveying main pipe through a connecting pipeline, the unit liquid inlet is communicated with the liquid return main pipe through a connecting pipeline, the cooling liquid inlet is communicated with the cooling tower outlet, and the cooling liquid outlet is communicated with the cooling tower inlet;

The machine room heat dissipation and cooling system also comprises a cold plate coil pipe, wherein the cold plate coil pipe is provided with a liquid inlet interface and a liquid outlet interface and is used for being arranged on the machine cabinet to conduct heat dissipation and cooling on the machine cabinet;

The air conditioner is provided with an air conditioner liquid inlet and an air conditioner liquid outlet, and the air conditioner liquid inlet is communicated with the transfusion main pipe;

the machine room heat dissipation cooling system further comprises a first refrigerator, wherein the first refrigerator is provided with a first plate liquid exchange inlet, a first plate liquid exchange outlet and a first heat exchange flow path, a liquid outlet end of the first heat exchange flow path is communicated with the liquid inlet, a liquid inlet end of the first heat exchange flow path is communicated with the liquid outlet, a liquid outlet of the air conditioner is communicated with the first plate liquid exchange inlet, and the plate liquid exchange outlet is communicated with the liquid return main pipe;

And a first adjusting valve is arranged on a pipeline between the liquid outlet of the air conditioner and the liquid inlet of the first plate.

2. The heat dissipation and cooling device as recited in claim 1, wherein,

The liquid inlet is replaced by the first plate, an adjusting branch pipe is connected to a pipeline between the liquid inlet and the first adjusting valve, the other end of the adjusting branch pipe is communicated with the transfusion main pipe, and a second adjusting valve is arranged on the adjusting branch pipe.

3. The heat dissipation and cooling device for machine room according to claim 2, wherein,

The cooling tower outlet is communicated with the liquid inlet end of the liquid conveying main pipe, the cooling tower inlet is communicated with the liquid outlet end of the liquid return main pipe, a valve A is arranged between the cooling tower outlet and the liquid inlet end of the liquid conveying main pipe, and a valve B is arranged between the cooling tower inlet and the liquid outlet end of the liquid return main pipe.

4. The heat dissipation and cooling device for a machine room as claimed in claim 3, wherein,

The cooling device comprises a machine set liquid outlet, a liquid inlet of a liquid return main pipe, a liquid inlet of the machine set, a liquid inlet of the liquid return main pipe, a liquid outlet of the cooling tower, a liquid inlet of the cooling tower and a liquid outlet of the cooling main pipe.

5. The cooling apparatus for machine room according to claim 4, wherein,

The machine room heat dissipation cooling equipment further comprises a control module, wherein the valve A, the valve B, the valve C, the valve D, the valve E, the valve F, the first adjusting valve and the second adjusting valve are electromagnetic control valves, and the control module is electrically connected with the valve A, the valve B, the valve C, the valve D, the valve E, the valve F, the first adjusting valve and the second adjusting valve, and controls the air conditioner to operate.

6. The heat sink apparatus of claim 5, wherein,

The air conditioner is internally provided with a second refrigerator and a compressor, the second refrigerator is provided with a second plate liquid inlet, a second plate liquid outlet and a second heat exchange flow path, the second plate liquid inlet is communicated with the infusion main pipe, the second plate liquid outlet is communicated with the first plate liquid inlet, the liquid outlet end of the second heat exchange flow path is communicated with the evaporator inlet of the air conditioner, the liquid inlet end of the second heat exchange flow path is communicated with the evaporator outlet of the air conditioner, and the compressor is arranged on a connecting pipeline of the liquid inlet end of the second heat exchange flow path and the evaporator outlet of the air conditioner.

7. A machine room, characterized in that the machine room comprises the machine room heat dissipation and cooling device as claimed in any one of claims 1 to 6, the supporting plate is used as a floor of the machine room, a plurality of cabinets are placed in the machine room to form a plurality of rows, two adjacent rows of cabinets, a ceiling of the machine room and the supporting plate form channels, two side channels of each row of servers are respectively a hot channel and a cold channel, one row of air conditioners corresponds to one row of cabinets, each air conditioner is provided with an air inlet and an air outlet, the air inlet is communicated with the hot channel, and the air outlet is communicated with the cold channel.