CN212084081U

CN212084081U - Virtual digital currency ore machine waste heat recovery heating system and refrigerating system

Info

Publication number: CN212084081U
Application number: CN202020581107.0U
Authority: CN
Inventors: 陈云; 王绘淋
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-04-18
Filing date: 2020-04-18
Publication date: 2020-12-04
Anticipated expiration: 2030-04-18

Abstract

The utility model relates to a virtual digital currency ore deposit machine technical field refers in particular to a virtual digital currency ore deposit machine waste heat recovery heating system and refrigerating system, including waste heat recovery device, heat exchange device, heating device, refrigerating plant and controlling means, waste heat recovery device is used for absorbing the heat of virtual digital currency ore deposit machine, and waste heat recovery device carries out heat exchange through heat exchange device with heating device, and heating device absorbs the heat and provides the heat, and waste heat recovery device carries out heat exchange through heat exchange device with refrigerating plant, refrigerating plant absorbs the heat and prepares cold volume. The utility model can recycle the waste heat generated by the digital currency mining machine during calculation and directly supply heat; or the heat is transferred to the absorption refrigerating unit to prepare the cold energy, so that the energy utilization rate is improved, and the environmental pollution is reduced.

Description

Virtual digital currency ore machine waste heat recovery heating system and refrigerating system

Technical Field

The utility model relates to a virtual digital currency ore deposit machine technical field refers in particular to a virtual digital currency ore deposit machine waste heat recovery heating system and refrigerating system.

Background

In recent years, with the rapid development of the block chain industry, more and more distributed computing devices are continuously operated all over the world all the year round, and a large amount of heat can be generated while high-power electric energy is consumed.

At present, the cooling for virtual digital currency ore deposit machine through liquid cooling circulation mode exists, and the waste heat that will produce is used for building heating simultaneously, but when there is not heating demand in summer, still exists the condition that the waste heat utilization is not enough.

Therefore, there is a need for improvements in the prior art.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems, the utility model provides a waste heat recovery heating system and a refrigerating system of a virtual digital currency mining machine, which can recover and utilize the waste heat generated by the digital currency mining machine during calculation and directly supply heat; or the heat is transferred to the absorption refrigerating unit to prepare the cold energy, so that the energy utilization rate is improved, and the environmental pollution is reduced.

In order to achieve the above purpose, the utility model discloses the technical scheme who uses as follows:

the utility model provides a virtual digital currency ore deposit machine waste heat recovery heating system and refrigerating system, includes waste heat recovery device, heat exchange device, heating system, refrigerating plant and controlling means, waste heat recovery device is used for absorbing the heat of virtual digital currency ore deposit machine, and waste heat recovery device carries out heat exchange through heat exchange device with heating system, and heating system absorbs the heat and provides the heat, and waste heat recovery device carries out heat exchange through heat exchange device with refrigerating plant, refrigerating plant absorbs the heat and prepares cold volume.

According to the above scheme, waste heat recovery device includes liquid cooling case, liquid pump and first motorised valve, and on the porous plywood of liquid cooling incasement was located to virtual digital currency ore deposit machine to submerge in the coolant liquid of liquid cooling incasement, the chip contact that generates heat of coolant liquid and virtual digital currency ore deposit machine, the play liquid end of liquid cooling case passes through pipe connection in the liquid pump, and the liquid pump passes through pipe connection in heat exchange device, and heat exchange device passes through pipe connection in first motorised valve, and first motorised valve passes through the inlet liquid end of pipe connection in liquid cooling case.

According to the above scheme, heating system includes heating end, second water pump and second motorised valve, and the play liquid end of heating end passes through pipe connection in second motorised valve, and the second motorised valve passes through pipe connection in heat exchange device, and heat exchange device passes through pipe connection in second water pump, and the second water pump passes through pipe connection in the terminal feed liquor end of heating, and the heating end is including locating the fan coil of radiator and central air conditioning.

According to the above scheme, heat exchange device includes plate heat exchanger, and plate heat exchanger one side is equipped with first inlet and first liquid outlet, and first inlet passes through pipe connection in the liquid pump, and first inlet passes through pipe connection in first liquid outlet, and first liquid outlet passes through pipe connection in first motorised valve, and the plate heat exchanger opposite side is equipped with second liquid outlet and second inlet, and the second inlet passes through pipe connection in second motorised valve, and the second liquid outlet passes through pipe connection in second water pump.

According to the above scheme, the refrigerating device comprises an absorption refrigerating unit, an auxiliary heater, a cooling tower, a refrigerating tail end, a third water pump, a fourth water pump, a fifth water pump, a third electric valve, a fourth electric valve, a fifth electric valve, an electric three-way flow dividing valve and an electric three-way flow combining valve, wherein the absorption refrigerating unit is provided with a third liquid inlet, a third liquid outlet, a fourth liquid inlet, a fourth liquid outlet, a fifth liquid inlet and a fifth liquid outlet, the electric three-way flow dividing valve is arranged on a pipeline between the second water pump and a plate heat exchanger, the electric three-way flow dividing valve is connected to the auxiliary heater through a pipeline, the auxiliary heater is connected to the third water pump through a pipeline, the third water pump is connected to the third liquid inlet on the absorption refrigerating unit through a pipeline, the electric three-way flow combining valve is arranged on a pipeline between the second electric valve and the plate heat exchanger, and the electric, the third motorised valve passes through the third liquid outlet of pipe connection on absorption refrigeration unit, fourth liquid outlet on the absorption refrigeration unit passes through pipe connection in fourth water pump, the fourth water pump passes through pipe connection in the inlet end of cooling tower, the play liquid end of cooling tower passes through pipe connection in fourth motorised valve, the fourth motorised valve passes through the fourth inlet of pipe connection on the absorption refrigeration unit, fifth liquid outlet on the absorption refrigeration unit passes through pipe connection in fifth water pump, fifth water pump passes through pipe connection in the terminal inlet end of refrigeration, the terminal play liquid end of refrigeration passes through pipe connection in fifth motorised valve, fifth motorised valve passes through the fifth inlet of pipe connection on the absorption refrigeration unit.

According to the above scheme, the control device comprises a controller, a first temperature sensor, a second temperature sensor, a third temperature sensor, a fourth temperature sensor, a fifth temperature sensor and a sixth temperature sensor, wherein the first temperature sensor is arranged at the liquid inlet end of the liquid cooling tank, the second temperature sensor is arranged at the liquid outlet end of the liquid cooling tank and is used for collecting the water temperatures before and after heat exchange of the liquid cooling tank, the third temperature sensor is arranged at the liquid inlet end of the heat exchange device, the fourth temperature sensor is arranged at the liquid outlet end of the heat exchange device and is used for collecting the water temperatures before and after heat exchange of the heat exchange device, the fifth temperature sensor is arranged at the third liquid inlet end of the absorption refrigerating unit, the sixth temperature sensor is arranged at the third liquid outlet end of the absorption refrigerating unit and is used for collecting the water temperatures before and after heat exchange of the absorption refrigerating unit, the first, The second temperature sensor, the third temperature sensor, the fourth temperature sensor, the fifth temperature sensor and the sixth temperature sensor are all connected to the controller, and the controller is connected to the liquid pump, the second water pump, the third water pump, the fourth water pump, the fifth water pump, the first electric valve, the second electric valve, the third electric valve, the fourth electric valve and the fifth electric valve.

The utility model discloses beneficial effect:

1) the utility model can recycle the waste heat generated by the digital currency mining machine during calculation and directly supply heat; or the heat is transferred to the absorption refrigerating unit to prepare the cold energy, so that the energy utilization rate is improved, and the environmental pollution is reduced;

2) the data center or the virtual digital currency mine site using the waste heat recovery heating and refrigerating system can refrigerate the environment in the data center or the digital currency mine site while reducing the running noise, and can also supply heat or cool for living areas or the periphery, thereby reducing the whole electric quantity consumption.

Drawings

FIG. 1 is a schematic structural diagram of a waste heat recovery heating system and a refrigeration system of the present invention;

fig. 2 is the structural schematic diagram of the liquid cooling box of the present invention.

100. A digital currency mining machine; 101. a liquid cooling tank; 102. a liquid pump; 103. a first electrically operated valve; 1011. cooling liquid; 1012. a porous laminate; 201. a plate heat exchanger; 301. a second water pump; 302. a second electrically operated valve; 310. a heating terminal; 3101. heating radiators; 3102. a terminal fan coil; 401. an absorption chiller unit; 402. an auxiliary heater; 403. a cooling tower; 404. a refrigeration terminal; 405. a third water pump; 406. a fourth water pump; 407. a fifth water pump; 408. a third electrically operated valve; 409. a fourth electrically operated valve; 410. a fifth electrically operated valve; 411. an electric three-way flow divider; 412. an electric three-way converging valve; 500. a controller; 501. a first temperature sensor; 502. a second temperature sensor; 503. a third temperature sensor; 504. a fourth temperature sensor; 505. a fifth temperature sensor; 506.

a sixth temperature sensor; 601. a first liquid inlet; 602. a second liquid inlet; 603. a third liquid inlet; 604. a fourth liquid inlet; 605. a fifth liquid inlet; 701. a first liquid outlet; 702. a second liquid outlet; 703. a third liquid outlet; 704. a fourth liquid outlet; 705. a fifth liquid outlet.

Detailed Description

The technical solution of the present invention will be described below with reference to the accompanying drawings and examples.

As shown in fig. 1 and fig. 2, a virtual digital currency ore deposit machine waste heat recovery heating system and refrigerating system, including waste heat recovery device, heat exchange device, heating device, refrigerating plant and controlling means, waste heat recovery device is used for absorbing the heat of virtual digital currency ore deposit machine 100, and waste heat recovery device carries out heat exchange through heat exchange device with heating device, and heating device absorbs the heat and provides the heat, and waste heat recovery device carries out heat exchange through heat exchange device with refrigerating plant, and refrigerating plant absorbs the heat and prepares cold volume.

In this embodiment, the waste heat recovery device includes a liquid cooling box 101, a liquid pump 102 and a first electric valve 103, the virtual digital currency mining machine 100 is disposed on a porous layer plate 1012 in the liquid cooling box 101 and is immersed in a cooling liquid 1011 in the liquid cooling box 101, the cooling liquid 1011 contacts with a heating chip of the virtual digital currency mining machine 100, a liquid outlet end of the liquid cooling box 101 is connected to the liquid pump 102 through a pipeline, the liquid pump 102 is connected to a heat exchange device through a pipeline, the heat exchange device is connected to the first electric valve 103 through a pipeline, and the first electric valve 103 is connected to a liquid inlet end of the liquid cooling box 101 through a pipeline. The heat of the heating chip of the virtual digital currency mining machine 100 is absorbed by the liquid cooling box 101, the heat is pumped into the heat exchange device for heat exchange under the action of the liquid pump 102, the exchanged cooling water flows back to the liquid cooling box 101 under the action of the first electric valve 103, and the heat exchange is continuously carried out, namely the heat of the heating chip of the virtual digital currency mining machine 100 is continuously taken away.

In practical application, the virtual digital currency mining machine 100 is placed in the liquid cooling box 101, and the plurality of liquid cooling boxes 101 are placed on the rack to form a liquid cooling cabinet.

In this embodiment, the heating apparatus includes a heating terminal 310, a second water pump 301, and a second electric valve 302, a liquid outlet end of the heating terminal 310 is connected to the second electric valve 302 through a pipe, the second electric valve 302 is connected to a heat exchanging apparatus through a pipe, the heat exchanging apparatus is connected to the second water pump 301 through a pipe, the second water pump 301 is connected to a liquid inlet end of the heating terminal 310 through a pipe, and the heating terminal 310 includes a fan coil 3102 provided in a radiator 3101 and a central air conditioner. The hot water exchanged with the heat exchange device enters the heating terminal 310 under the action of the second water pump 301 to provide heat for the radiator 3101 and the fan coil 3102 of the central air conditioner, and the cooling water after providing heat flows back to the heat exchange device under the action of the second electric valve 302 to continuously exchange heat.

In the present embodiment, the heating terminal 310 refers to a device capable of converting hot water or heating medium into hot air, and is generally located indoors.

In this embodiment, the heat exchange device includes a plate heat exchanger 201, a first liquid inlet 601 and a first liquid outlet 701 are disposed on one side of the plate heat exchanger 201, the first liquid inlet 601 is connected to a liquid pump 102 through a pipeline, the first liquid inlet 601 is connected to a first liquid outlet 701 through a pipeline, the first liquid outlet 701 is connected to a first electric valve 103 through a pipeline, a second liquid outlet 702 and a second liquid inlet 602 are disposed on the other side of the plate heat exchanger 201, the second liquid inlet 602 is connected to a second electric valve 302 through a pipeline, and the second liquid outlet 702 is connected to a second water pump 301 through a pipeline.

In this embodiment, the refrigeration apparatus includes an absorption refrigeration unit 401, an auxiliary heater 402, a cooling tower 403, a refrigeration end 404, a third water pump 405, a fourth water pump 406, a fifth water pump 407, a third electric valve 408, a fourth electric valve 409, a fifth electric valve 410, an electric three-way diverter valve 411, and an electric three-way converging valve 412, where the absorption refrigeration unit 401 is provided with a third liquid inlet 603, a third liquid outlet 703, a fourth liquid inlet 604, a fourth liquid outlet 704, a fifth liquid inlet 605, and a fifth liquid outlet 705, the electric three-way diverter valve 411 is provided on a pipeline between the second water pump 301 and the plate heat exchanger 201, the electric three-way diverter valve 411 is connected to the auxiliary heater 402 through a pipeline, the auxiliary heater 402 is connected to the third water pump 405 through a pipeline, the third water pump 405 is connected to the third liquid inlet 603 on the absorption refrigeration unit 401 through a pipeline, the electric three-way converging valve 412 is provided on a pipeline between the second electric valve 302 and the plate heat exchanger, the electric three-way converging valve 412 is connected to the third electric valve 408 through a pipeline, the third electric valve 408 is connected to a third liquid outlet 703 on the absorption refrigerator unit 401 through a pipeline, a fourth liquid outlet 704 on the absorption refrigerator unit 401 is connected to a fourth water pump 406 through a pipeline, the fourth water pump 406 is connected to the liquid inlet end of the cooling tower 403 through a pipeline, the liquid outlet end of the cooling tower 403 is connected to a fourth electric valve 409 through a pipeline, the fourth electric valve 409 is connected to a fourth liquid inlet 604 on the absorption refrigerator unit 401 through a pipeline, a fifth liquid outlet 705 on the absorption refrigerator unit 401 is connected to a fifth water pump 407 through a pipeline, the fifth water pump 407 is connected to the liquid inlet end of the refrigeration terminal 404 through a pipeline, the liquid outlet end of the refrigeration terminal 404 is connected to a fifth electric valve 410 through a pipeline, and the fifth electric valve 410 is connected to a fifth liquid inlet 605 on. Be used for receiving the hot water that plate heat exchanger 201 sent through electronic three-way diverter valve 411, and reach preset water temperature under auxiliary heater 402 effect, and enter into absorption refrigeration unit 401 under the effect of third water pump 405, make absorption refrigeration unit 401 can acquire sufficient heat, absorption refrigeration unit 401 exchanges the heat with cooling tower 403 after with the heat, convert the cold water back, send into refrigeration end 404 through fifth water pump 407, can make the water after the cooling reflux plate heat exchanger 201 through third motorised valve 408 simultaneously, continuously carry out the heat exchange.

In practical application, the electric three-way flow dividing valve 411 and the electric three-way flow converging valve 412 are connected in parallel with the pipeline.

In practical application, the absorption refrigerating unit 401 is composed of a plurality of absorption refrigerators, and preferably, the absorption refrigerating unit 401 can select ammonia absorption refrigeration or lithium bromide absorption refrigeration, and can also select other refrigeration working mediums capable of utilizing low-temperature heat energy to refrigerate.

In the present embodiment, the cooling terminal 404 refers to a device capable of converting cold water or refrigerant into cold air, such as a terminal device of a central air conditioning system, and is usually located indoors.

The heat recovery heating system and the heat recovery cooling system described in this embodiment are usually operated in a time-sharing manner, and for example, may be set to a cooling operation mode in summer and may be set to a heating operation mode in winter. When the refrigeration is working, the electric three-way diverter valve 411 is opened when the channel flowing to the absorption refrigeration unit 401 is full, and the channel flowing to the heating end 310 is closed, so that the refrigeration working mode can be realized; in the heating mode, the channel of the three-way diverter valve 411 toward the absorption chiller 401 is closed, and the channel toward the heating end 310 is fully open, thereby implementing the heating mode.

In this embodiment, the control device includes a controller, a first temperature sensor 501, a second temperature sensor 502, a third temperature sensor 503, a fourth temperature sensor 504, a fifth temperature sensor 505, and a sixth temperature sensor 506, where the first temperature sensor 501 is disposed at a liquid inlet end of the liquid cooling tank 101, the second temperature sensor 502 is disposed at a liquid outlet end of the liquid cooling tank 101, and is used to collect water temperatures before and after heat exchange of the liquid cooling tank 101, the third temperature sensor 503 is disposed at a liquid inlet end of the heat exchange device, the fourth temperature sensor 504 is disposed at a liquid outlet end of the heat exchange device, and is used to collect water temperatures before and after heat exchange of the heat exchange device, the fifth temperature sensor 505 is disposed at a third liquid inlet 603 of the absorption refrigeration unit 401, the sixth temperature sensor 506 is disposed at a third liquid outlet 703 of the absorption refrigeration unit 401, and is used to collect water temperatures before and after heat exchange of the absorption refrigeration unit 401, the first temperature sensor 501, the second temperature sensor 502, the third temperature sensor 503, the fourth temperature sensor 504, the fifth temperature sensor 505 and the sixth temperature sensor 506 are all connected to a controller, and the controller is connected to the liquid pump 102, the second water pump 301, the third water pump 405, the fourth water pump 406, the fifth water pump 407, the first electric valve 103, the second electric valve 302, the third electric valve 408, the fourth electric valve 409 and the fifth electric valve 410. The controller controls the operations of the liquid pump 102, the second water pump 301, the third water pump 405, the fourth water pump 406, the fifth water pump 407, the first electric valve 103, the second electric valve 302, the third electric valve 408, the fourth electric valve 409, and the fifth electric valve 410 by using the values returned from the first temperature sensor 501, the second temperature sensor 502, the third temperature sensor 503, the fourth temperature sensor 504, the fifth temperature sensor 505, and the sixth temperature sensor 506.

The utility model discloses the theory of operation:

when the virtual digital currency mining machine 100 works and generates heat, the controller starts the liquid pump 102, the cooling liquid 1011 in the liquid cooling box 101 absorbs the heat from the virtual digital currency mining machine 100, the hot cooling liquid 1011 enters the plate heat exchanger 201 through the pipeline and the first liquid inlet 601 of the plate heat exchanger 201 to exchange heat and then flows out of the plate heat exchanger 201 through the first liquid outlet 701, and the hot cooling liquid enters the liquid cooling box 101 to cool the virtual digital currency mining machine 100 under the driving of the first electric valve 103. The circulation process constitutes a first circulation line.

The cooling liquid 1011 absorbing heat in the first circulation line exchanges heat with water in the plate heat exchanger 201 to transfer heat to the water. When a user has a heating demand, the controller adjusts the second electric valve 302 to control the flow of water and sends hot water to the user heating end 310 through the second water pump 301;

the heat of the hot water is transferred to the absorption refrigeration unit 401, and the absorption refrigeration unit 401 can absorb the heat of the hot water to prepare cold water, and the cold water can be output to a refrigeration system to supply cold for different scenes. When the user has cold requirement, the controller controls the flow of water by adjusting the fifth electric valve 410 and sends cold water to the refrigeration end 404 of the user by the fifth water pump 407;

in practical application, the control of the water temperature of the first liquid outlet 701 of the plate heat exchanger 201 is realized by controlling the total power of the virtual digital currency mining machine 100. Under the heating working condition, according to the heat demand of the user side, the controller lifts the total power of the virtual digital currency mining machine 100 in the liquid cooling box 101, and the heat release is increased or reduced; under the refrigeration working condition, according to the magnitude of the cold quantity requirement of the user terminal, the total power of the virtual digital currency mining machine 100 in the liquid cooling box 101 and the power of the lifting auxiliary heater 402 are lifted through the controller 400, and the heat release is increased or reduced to achieve the purpose of controlling the magnitude of the cold quantity;

in practical application, the utility model discloses waste heat recovery heating and refrigerating system can be integrated in the container, transport to heating and refrigeration place back, only need switch on, water source, network, can calculate the operation and keep warm, refrigerate the use through the pipeline with the original heating in place and the butt joint of refrigerating pipe, dispose convenient operation fast.

It should be noted that the utility model discloses waste heat recovery heating and refrigerating system can be applied to the liquid cooling mine, and including being used for the liquid cooling box and the rack for the equipment cooling of virtual digital currency ore deposit machine 100 in the liquid cooling mine, the waste heat recovery refrigerating system of virtual digital currency ore deposit machine 100 can absorb the heat that virtual digital currency ore deposit machine 100 produced when operation and prepare low temperature cold water, provides cold volume for environment and electronic equipment in the virtual digital currency ore deposit machine 100 mine; the waste heat recovery heating system of the virtual digital currency mining machine 100 may provide heat for a living area or a periphery. Therefore, the virtual digital currency mining machine 100 can be used for cooling or heating by recycling the waste heat for secondary use while meeting the requirement of heat dissipation, and the utilization rate of energy is improved.

The embodiments of the present invention have been described with reference to the accompanying drawings, but the present invention is not limited to the above-mentioned embodiments, which are only illustrative and not restrictive, and those skilled in the art can make many forms without departing from the spirit and scope of the present invention, and these forms are within the scope of the present invention.

Claims

1. The utility model provides a virtual digit currency ore deposit machine waste heat recovery heating system and refrigerating system which characterized in that: comprises a waste heat recovery device, a heat exchange device, a heating device, a refrigerating device and a control device,

the waste heat recovery device is used for absorbing the heat of the virtual digital currency mining machine (100),

the waste heat recovery device and the heating device exchange heat through the heat exchange device, the heating device absorbs the heat to provide heat,

the waste heat recovery device and the refrigerating device exchange heat through the heat exchange device, and the refrigerating device absorbs the heat to produce cold.

2. The virtual digital currency ore deposit machine waste heat recovery heating system and refrigerating system of claim 1, characterized in that: waste heat recovery device includes liquid-cooling tank (101), liquid pump (102) and first motorised valve (103), virtual digital currency ore deposit machine (100) are located on porous plywood (1012) in liquid-cooling tank (101) to submerge in coolant liquid (1011) in liquid-cooling tank (101), the chip contact that generates heat of coolant liquid (1011) and virtual digital currency ore deposit machine (100), the play liquid end of liquid-cooling tank (101) passes through pipe connection in liquid pump (102), liquid pump (102) pass through pipe connection in heat exchange device, heat exchange device passes through pipe connection in first motorised valve (103), first motorised valve (103) pass through pipe connection in the inlet end of liquid-cooling tank (101).

3. The virtual digital currency ore deposit machine waste heat recovery heating system and refrigerating system of claim 2, characterized in that: heating system includes heating end (310), second water pump (301) and second motorised valve (302), the play liquid end of heating end (310) passes through pipe connection in second motorised valve (302), second motorised valve (302) pass through pipe connection in heat exchange device, heat exchange device passes through pipe connection in second water pump (301), second water pump (301) pass through the pipe connection in the inlet end of heating end (310), heating end (310) is including locating radiator (3101) and central air conditioning's fan coil (3102).

4. The virtual digital currency ore deposit machine waste heat recovery heating system and refrigerating system of claim 2, characterized in that: the heat exchange device comprises a plate heat exchanger (201), wherein a first liquid inlet (601) and a first liquid outlet (701) are arranged on one side of the plate heat exchanger (201), the first liquid inlet (601) is connected to a liquid pump (102) through a pipeline, the first liquid inlet (601) is connected to a first liquid outlet (701) through a pipeline, the first liquid outlet (701) is connected to a first electric valve (103) through a pipeline, a second liquid outlet (702) and a second liquid inlet (602) are arranged on the other side of the plate heat exchanger (201), the second liquid inlet (602) is connected to a second electric valve (302) through a pipeline, and the second liquid outlet (702) is connected to a second water pump (301) through a pipeline.

5. The virtual digital currency ore deposit machine waste heat recovery heating system and refrigerating system of claim 1, characterized in that: the refrigerating device comprises an absorption refrigerating unit (401), an auxiliary heater (402), a cooling tower (403), a refrigerating tail end (404), a third water pump (405), a fourth water pump (406), a fifth water pump (407), a third electric valve (408), a fourth electric valve (409), a fifth electric valve (410), an electric three-way flow dividing valve (411) and an electric three-way flow converging valve (412),

a third liquid inlet (603), a third liquid outlet (703), a fourth liquid inlet (604), a fourth liquid outlet (704), a fifth liquid inlet (605) and a fifth liquid outlet (705) are arranged on the absorption refrigerating unit (401),

the electric three-way diverter valve (411) is arranged on a pipeline between the second water pump (301) and the plate heat exchanger (201), the electric three-way diverter valve (411) is connected with the auxiliary heater (402) through a pipeline, the auxiliary heater (402) is connected with the third water pump (405) through a pipeline, the third water pump (405) is connected with the third liquid inlet (603) on the absorption refrigerating unit (401) through a pipeline,

the electric three-way converging valve (412) is arranged on a pipeline between the second electric valve (302) and the plate heat exchanger (201), the electric three-way converging valve (412) is connected to a third electric valve (408) through a pipeline, the third electric valve (408) is connected to a third liquid outlet (703) on the absorption refrigeration unit (401) through a pipeline,

a fourth liquid outlet (704) on the absorption refrigeration unit (401) is connected with a fourth water pump (406) through a pipeline, the fourth water pump (406) is connected with the liquid inlet end of the cooling tower (403) through a pipeline, the liquid outlet end of the cooling tower (403) is connected with a fourth electric valve (409) through a pipeline, the fourth electric valve (409) is connected with a fourth liquid inlet (604) on the absorption refrigeration unit (401) through a pipeline, a fifth liquid outlet (705) on the absorption refrigeration unit (401) is connected with a fifth water pump (407) through a pipeline, the fifth water pump (407) is connected with the liquid inlet end of the refrigeration tail end (404) through a pipeline, the liquid outlet end of the refrigeration terminal (404) is connected with a fifth electric valve (410) through a pipeline, the fifth electric valve (410) is connected to a fifth liquid inlet (605) on the absorption refrigeration unit (401) through a pipeline.

6. The virtual digital currency ore deposit machine waste heat recovery heating system and refrigerating system of claim 1, characterized in that: the control device comprises a controller, a first temperature sensor (501), a second temperature sensor (502), a third temperature sensor (503), a fourth temperature sensor (504), a fifth temperature sensor (505) and a sixth temperature sensor (506),

the liquid inlet end position of liquid cooling case (101) is located to first temperature sensor (501), the liquid outlet end position of liquid cooling case (101) is located to second temperature sensor (502), for adopt the temperature around liquid cooling case (101) heat exchange, the liquid inlet end position of heat exchange device is located to third temperature sensor (503), heat exchange device's liquid outlet end position is located to fourth temperature sensor (504), be used for gathering the temperature around the heat exchange device heat exchange, the third liquid inlet (603) position of absorption refrigerating unit (401) is located to fifth temperature sensor (505), the third liquid outlet (703) position of absorption refrigerating unit (401) is located to sixth temperature sensor (506), be used for gathering the temperature around the absorption refrigerating unit (401) heat exchange,

the first temperature sensor (501), the second temperature sensor (502), the third temperature sensor (503), the fourth temperature sensor (504), the fifth temperature sensor (505) and the sixth temperature sensor (506) are all connected to a controller, and the controller is connected to the liquid pump (102), the second water pump (301), the third water pump (405), the fourth water pump (406), the fifth water pump (407), the first electric valve (103), the second electric valve (302), the third electric valve (408), the fourth electric valve (409) and the fifth electric valve (410).