CN212428212U - Heat exchange system of digital energy comprehensive service station - Google Patents

Abstract

The utility model relates to a heat exchange field of a digital energy service station, in particular to a heat exchange system of a digital energy comprehensive service station, which comprises a fire hydrant arranged on the outer wall and the inner wall of a container, a power distribution cabinet arranged inside the container, a standby power supply, a machine cabinet and a refrigeration terminal used for cooling the machine cabinet, wherein one end of the refrigeration terminal is connected with the water outlet end A of a double-purpose cold and hot main machine through a cold source conveying pipeline, the other end of the refrigeration terminal is connected with the water inlet end A of the double-purpose cold and hot main machine through a circulating pipeline, and the water inlet end A and the water outlet end A form a passage inside the double-purpose cold and hot main machine, the water inlet end B of the double-purpose cold and hot main machine is connected with the water outlet end of a water injection pipeline, thereby the waste heat on the circulating pipeline can be exchanged into the waste heat recovery pipeline, and the heating of the, and the heated water flow can be conveyed to a water using end through a waste heat recovery pipeline.

Description

Heat exchange system of digital energy comprehensive service station

Technical Field

The utility model relates to a digital energy service station heat transfer field especially relates to a digital energy integrated service station heat transfer system.

Background

The container data center is completely different from the technology of the traditional data center foundation, integrates all basic implementation of power distribution, refrigeration, IT cabinet, wiring, fire protection, monitoring and the like in a container to form a highly centralized and multipurpose data center module, has the characteristics of high reliability, safety, rapid deployment, convenient movement and the like, can greatly reduce TCO of customers and improve ROI, and can meet the application requirements of the data center of most central enterprises.

At present, in a traditional container data center, a refrigerating system adopts fluorine circulation, the air outlet temperature is low and dry, and the waste heat in a container is not effectively recycled.

SUMMERY OF THE UTILITY MODEL

To the above problem, the utility model provides a digital energy integrated service station heat transfer system for the air-out is comparatively moist, and can effectual waste heat among the recycle container.

The technical scheme of the utility model as follows:

a heat exchange system of a digital energy comprehensive service station comprises fire hydrants installed on the outer wall and the inner wall of a container, a power distribution cabinet installed inside the container, a standby power supply, a cabinet used for installing IT equipment, and a refrigeration terminal used for cooling the cabinet, wherein one end of the refrigeration terminal is connected with a water outlet end A of a cold and hot dual-purpose host installed inside the container through a cold source conveying pipeline, the other end of the refrigeration terminal is connected with a water inlet end A of the cold and hot dual-purpose host through a circulating pipeline, and the water inlet end A and the water outlet end A form a passage inside the cold and hot dual-purpose host, so that a circulating refrigeration pipeline is formed among the cold and hot dual-purpose host, the cold source conveying pipeline, the refrigeration terminal and the circulating pipeline, a water outlet end of a water injection pipeline is connected onto the water inlet end B of the cold and hot dual-purpose host, and a water outlet end B of a, thereby can be with waste heat transfer on the circulating line to waste heat recovery pipeline inside to realized heating to the inside rivers of waste heat recovery pipeline, and accessible waste heat recovery pipeline carries the rivers after the heating to the water end.

Specifically, the refrigeration terminal comprises collecting pipes arranged on two sides of the heat transfer channel, heat conduction pipe bundles connected with the collecting pipes on the two sides, and a fan which is arranged at one end, far away from the cabinet, of the heat transfer channel and is opposite to the cabinet for outputting, so that air can be blown to the heat conduction pipe bundles through the fan, air outlet refrigeration is realized, and the cooling effect on the cabinet is realized.

Preferably, a butterfly valve, a water pump, a butterfly valve and a check valve are sequentially arranged on the cold source conveying pipeline from the cold and hot dual-purpose host machine to the refrigeration end.

Furthermore, the cold source pipeline is connected with one end of a cold source branch pipeline between the check valve and the adjacent butterfly valve, the other end of the cold source branch pipeline is connected to the cold source pipeline between the water inlet end of the cold source pipeline and the butterfly valve adjacent to the water inlet end, and the butterfly valve is installed on the cold source branch pipeline, so that when the water pump on the cold source pipeline needs to be overhauled, the butterfly valve can be opened to continuously convey the cold source to the refrigeration end.

Preferably, a butterfly valve, a water pump, a butterfly valve, a check valve and an electromagnetic four-way valve are sequentially arranged from the water inlet end to the water outlet end of the waste heat recovery pipeline.

Further, the end of intaking of waste heat recovery pipeline is connected with the one end of waste heat recovery tributary pipeline between the butterfly valve adjacent with the end of intaking, and the other end of waste heat recovery tributary pipeline is connected on the waste heat recovery pipeline between check valve and the butterfly valve adjacent with the check valve to install the butterfly valve on waste heat recovery tributary pipeline, make when overhauing the water pump on the waste heat recovery pipeline, can continue to retrieve the waste heat through waste heat recovery tributary pipeline, thereby can last provide hot water to the water end.

Furthermore, water injection pipeline, cold source pipeline are divided equally and are connected with the play water end of a moisturizing pipeline respectively, water source filter, butterfly valve, water pump, butterfly valve and check valve are installed in proper order to the play water end to the end to intaking of moisturizing pipeline.

Still further, refrigeration end, cold source pipeline, circulating line, all install the temperature sensor who is used for detecting the rivers temperature on waste heat recovery pipeline and the water injection pipeline, and container internally mounted has the sensor that detects the inside temperature of container, foretell temperature sensor all installs in the inside controller of container through the data line access, make can acquire the refrigeration end through the controller, cold source pipeline, circulating line, the temperature information of the inside rivers of waste heat recovery pipeline and water injection pipeline, and with cold source pipeline through the control line, water pump access controller on waste heat recovery pipeline and the moisturizing pipeline, thereby the output of accessible temperature information automatic control water pump, thereby reach the velocity of flow of accelerating or slowing inside rivers, thereby reach and promote or reduce heat exchange efficiency.

Still further, the electromagnetic four-way valve is connected with the controller through a control line, so that the controller can control the opening and closing of the electromagnetic four-way valve.

Has the advantages that: 1. the utility model discloses a set up cold and hot double-purpose host computer inside the container to waste heat transfer to waste heat recovery pipeline on with the circulating line through cold and hot double-purpose host computer is inside, thereby has realized heating to the inside rivers of waste heat recovery pipeline, and rivers after accessible waste heat recovery pipeline will heat are carried to the water end.

2. Compared with the prior art, the method has the advantages that the operation cost is reduced, and the benefit can be generated through waste heat recovery and reuse.

3. The utility model discloses a fan blows the air to heat exchanger tube bank, cools down the air through heat exchanger tube bank to make the air-out comparatively moist for the cooling device that adopts fluorine circulation.

4. The utility model discloses a controller intelligent control heat exchange efficiency, the temperature that detects through the sensor that acquires container internally mounted controls the output of water pump through the invariable temperature of predetermined container, accelerates or slows down the velocity of flow of inside rivers to reach the purpose that promotes or reduce heat exchange efficiency, thereby make can the inside temperature of intelligent control container reach the constant temperature.

Drawings

Fig. 1 is a schematic view of the internal layout of the container of the present invention;

fig. 2 is a schematic view of a specific structure of the refrigeration terminal of the present invention;

description of reference numerals: 1. a container; 2. a standby power supply; 3. a power distribution cabinet; 4. a fire hydrant; 5. a refrigeration terminal; 6. a cold source conveying pipeline; 7. a cold and hot dual-purpose host; 8. a waste heat recovery pipeline; 9. a water replenishing pipeline; 10. a cold source branch pipeline; 11. a water injection pipeline; 12. a circulation pipe; 13. a controller; 14. a waste heat recovery branch pipeline; 501. a header; 502. a heat conduction pipe bundle; 503. a fan.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1, a heat exchange system of a digital energy integrated service station comprises fire hydrant 4 installed on the outer wall and the inner wall of a container 1, a power distribution cabinet 3 installed inside the container 1, a standby power supply 2, a cabinet for installing IT equipment, and a refrigeration terminal 5 for cooling the cabinet, wherein one end of the refrigeration terminal 5 is connected with a water outlet end a of a cold and hot dual-purpose host 7 installed inside the container 1 through a cold source conveying pipeline 6, the other end of the refrigeration terminal 5 is connected with a water inlet end a of the cold and hot dual-purpose host 7 through a circulation pipeline 12, and the water inlet end a and the water outlet end a form a passage inside the cold and hot dual-purpose host 7, so that a circulating refrigeration pipeline is formed among the cold and hot dual-purpose host 7, the cold source conveying pipeline 6, the refrigeration terminal 5 and the circulation pipeline 12, and a water outlet end of a water injection pipeline 11 is connected to a water inlet end B of the, the play water end B of cold and hot double-purpose host computer 7 is connected with waste heat recovery pipeline 8's the end of intaking to can be with waste heat transfer to waste heat recovery pipeline 8 on the circulating line 12 inside, thereby realized heating to the inside rivers of waste heat recovery pipeline 8, and rivers after accessible waste heat recovery pipeline 8 will heat are carried to the water end.

Specifically, the refrigeration terminal 5 includes a header 501, a heat conduction pipe bundle 502 connected to the header 501, and a fan 503 installed at an air inlet of the heat conduction passage, and an air outlet of the heat conduction passage is directly opposite to the cabinet, so that air can be blown to the heat conduction pipe bundle 502 by the fan 503 to achieve air-out refrigeration, thereby achieving a cooling effect on the cabinet.

And a butterfly valve, a water pump, a butterfly valve and a check valve are sequentially arranged on the cold source conveying pipeline 6 from the cold and hot dual-purpose host 7 to the refrigeration tail end 5.

The cold source conveying pipeline 6 is connected with one end of a cold source branch pipeline 10 between the check valve and the adjacent butterfly valve, the other end of the cold source branch pipeline 10 is connected to the cold source conveying pipeline 6 from the water inlet end of the cold source conveying pipeline 6 to the cold source conveying pipeline 6 between the butterfly valves adjacent to the water inlet end, and the butterfly valve is installed on the cold source branch pipeline 10, so that when the water pump on the cold source conveying pipeline 6 needs to be overhauled, the butterfly valve can be opened to continuously convey the cold source to the refrigeration terminal 5.

And a butterfly valve, a water pump, a butterfly valve, a check valve and an electromagnetic four-way valve are sequentially arranged from the water inlet end to the water outlet end of the waste heat recovery pipeline 8.

The waste heat recovery pipeline 8 intake end to with intake and be connected with waste heat recovery tributary pipeline 14's one end between the adjacent butterfly valve of end, waste heat recovery tributary pipeline 14's the other end is connected on the check valve and the waste heat recovery pipeline 8 between the adjacent butterfly valve with the check valve, and install the butterfly valve on waste heat recovery tributary pipeline 14, make when overhauing the water pump on waste heat recovery pipeline 8, can continue to retrieve the waste heat through waste heat recovery tributary pipeline 14, thereby can last provide hot water to the water end.

Water injection pipeline 11, cold source pipeline 6 are gone up and are equallyd divide the play water end that is connected with a moisturizing pipeline 9 respectively, moisturizing pipeline 9's the end of intaking is installed water source filter, butterfly valve, water pump, butterfly valve and check valve on the play water end in proper order.

The refrigeration tail end 5, the cold source conveying pipeline 6, the circulating pipeline 12, the waste heat recovery pipeline 8 and the water injection pipeline 11 are all provided with temperature sensors for detecting the temperature of water flow, and the inside of the container 1 is provided with a sensor for detecting the temperature inside the container 1, the temperature sensors are connected into a controller 13 arranged inside the container 1 through data lines, so that the temperature information of the water flow inside the refrigeration terminal 5, the cold source conveying pipeline 6, the circulating pipeline 12, the waste heat recovery pipeline 8 and the water injection pipeline 11 can be obtained through the controller 13, and the water pumps on the cold source conveying pipeline 6, the waste heat recovery pipeline 8 and the water replenishing pipeline 9 are connected into the controller 13 through control lines, therefore, the output power of the water pump can be automatically controlled through the temperature information, the flow speed of the internal water flow is accelerated or slowed, and the heat exchange efficiency is improved or reduced.

The electromagnetic four-way valve is connected with the controller 13 through a control line, so that the controller 13 can control the opening and closing of the electromagnetic four-way valve.

Set up water supply pipeline 9's aim at on water injection pipeline 11, because 1 digital energy integrated service station of container conveniently carries, probably its present workplace or next workplace waste heat's recycle of not being convenient for, so can with water injection pipeline 11 the end of intaking with the electromagnetism cross valve is connected to make water injection pipeline 11, waste heat recovery pipeline 8 and cold and hot double-purpose host computer 7 intake end B and play water end B form a circulation circuit between the pipeline of the inside intercommunication of cold and hot double-purpose host computer 7, after inside rivers are consumed, accessible water supply pipeline 9 carries out the moisturizing operation.

Referring to fig. 2, the refrigeration terminal 5 includes headers 501 respectively installed at two sides of the heat transfer channel, a plurality of heat conduction tube bundles 502 are connected between the headers 501 at two sides, and a fan 503 is installed at an air inlet of the heat transfer channel, and an air outlet of the heat transfer channel faces the cabinet, so that air is blown into the heat transfer channel by the fan 503 and contacts with the heat conduction tube bundles 502 for cooling, and then directly acts on the cabinet through the air outlet, thereby cooling the cabinet.

The utility model discloses a terminal 5 of refrigeration installs a plurality ofly or corresponds the rack number and installs, only need set up on cold source pipeline 6 a plurality of joints that are connected with collector 501 can to install the butterfly valve on every connects, thereby can close when not using single joint, prevent cold source rivers leakage, every terminal 5 of refrigeration's collector 501 both ends are equallyd divide do not set up the interface and respectively through the articulate that sets up on this interface bucket cold source pipeline 6, thereby cold source circulation has been realized.

It is obvious to a person skilled in the art that the invention is not restricted to details of the above-described exemplary embodiments, but that it can be implemented in other specific forms without departing from the spirit or essential characteristics of the invention. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (9)

1. A heat exchange system of a digital energy comprehensive service station comprises fire hydrant (4) arranged on the outer wall and the inner wall of a container (1), a power distribution cabinet (3) arranged in the container (1), a standby power supply (2), a cabinet for installing IT equipment, and a refrigeration tail end (5) for cooling the cabinet, one end of the refrigeration tail end (5) is connected with a water outlet end A of a cold and hot dual-purpose host (7) arranged in the container (1) through a cold source conveying pipeline (6), the other end of the refrigeration tail end (5) is connected with a water inlet end A of the cold and hot dual-purpose host (7) through a circulating pipeline (12), and the water inlet end A and the water outlet end A form a passage in the cold and hot dual-purpose host (7), and the water inlet end B of the cold and hot dual-purpose host (7) is connected with the water outlet end of a water injection pipeline (11), and the water outlet end B of the cold and hot dual-purpose host (7) is connected with the water inlet end of a waste heat recovery pipeline (8).

2. The heat exchange system of the digital energy integrated service station as claimed in claim 1, wherein: the refrigeration tail end (5) comprises collecting pipes (501) arranged on two sides of the heat transfer channel respectively, heat conduction pipe bundles (502) connected with the collecting pipes (501) on the two sides, and a fan (503) which is arranged at one end, far away from the cabinet, of the heat transfer channel and is opposite to the output of the cabinet.

3. The heat exchange system of the digital energy integrated service station as claimed in claim 1, wherein: and a butterfly valve, a water pump, a butterfly valve and a check valve are sequentially arranged on the cold source conveying pipeline (6) from the cold and hot dual-purpose host (7) to the refrigeration tail end (5).

4. The heat exchange system of the comprehensive service station for digital energy resources of claim 3, wherein: the cold source branch pipeline (6) is connected with one end of a cold source branch pipeline (10) and is located between the check valve and the adjacent butterfly valve, the other end of the cold source branch pipeline (10) is connected to the cold source pipeline (6) between the butterfly valve adjacent to the water inlet end and the water inlet end of the cold source pipeline (6), and the butterfly valve is installed on the cold source branch pipeline (10).

5. The heat exchange system of the digital energy integrated service station as claimed in claim 1, wherein: and a butterfly valve, a water pump, a butterfly valve, a check valve and an electromagnetic four-way valve are sequentially arranged from the water inlet end to the water outlet end of the waste heat recovery pipeline (8).

6. The heat exchange system of the comprehensive service station for digital energy resources of claim 5, wherein: the one end that is connected with waste heat recovery tributary pipeline (14) between the butterfly valve adjacent with the end of intaking is held to the intaking of waste heat recovery pipeline (8), and the other end of waste heat recovery tributary pipeline (14) is connected on waste heat recovery pipeline (8) between check valve and the butterfly valve adjacent with the check valve to install the butterfly valve on waste heat recovery tributary pipeline (14).

7. The heat exchange system of the digital energy integrated service station as claimed in claim 1, wherein: the water injection pipeline (11), the water outlet end that divide equally on cold source pipeline (6) and be connected with a moisturizing pipeline (9), the end of intaking of moisturizing pipeline (9) is held and is installed water source filter, butterfly valve, water pump, butterfly valve and check valve on the water outlet in proper order.

8. The heat exchange system of the comprehensive service station for digital energy resources of claim 5, wherein: the electromagnetic four-way valve is connected with the controller (13) through a control line, so that the controller (13) can control the opening and closing of the electromagnetic four-way valve.

9. The heat exchange system of the DSSS according to any one of claims 1 to 8, wherein: all install the temperature sensor who is used for detecting rivers temperature on refrigeration end (5), cold source pipeline (6), circulating line (12), waste heat recovery pipeline (8) and water injection pipeline (11) to container (1) internally mounted has the sensor that detects container (1) inside temperature, foretell temperature sensor all installs in container (1) inside controller (13) through the data line access, and through control line with cold source pipeline (6), water pump access controller (13) of installation on waste heat recovery pipeline (8) and the moisturizing pipeline (9).

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