CN108458472B - Water heater device based on heating of block chain server - Google Patents
Water heater device based on heating of block chain server Download PDFInfo
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- CN108458472B CN108458472B CN201810160029.4A CN201810160029A CN108458472B CN 108458472 B CN108458472 B CN 108458472B CN 201810160029 A CN201810160029 A CN 201810160029A CN 108458472 B CN108458472 B CN 108458472B
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24H—FLUID HEATERS, e.g. WATER OR AIR HEATERS, HAVING HEAT-GENERATING MEANS, e.g. HEAT PUMPS, IN GENERAL
- F24H1/00—Water heaters, e.g. boilers, continuous-flow heaters or water-storage heaters
- F24H1/0018—Water heaters, e.g. boilers, continuous-flow heaters or water-storage heaters using electric energy supply
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24H—FLUID HEATERS, e.g. WATER OR AIR HEATERS, HAVING HEAT-GENERATING MEANS, e.g. HEAT PUMPS, IN GENERAL
- F24H9/00—Details
- F24H9/20—Arrangement or mounting of control or safety devices
- F24H9/2007—Arrangement or mounting of control or safety devices for water heaters
- F24H9/2014—Arrangement or mounting of control or safety devices for water heaters using electrical energy supply
- F24H9/2021—Storage heaters
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Abstract
The invention relates to a water heater device based on block chain server heating, which comprises a water storage tank group, a CPU water cooling block, a GPU water cooling block, a first water pump, a controller, a temperature sensor group, a water level sensor group, a first electromagnetic valve group, a second electromagnetic valve group, a third electromagnetic valve group and a fourth electromagnetic valve group, wherein the water storage tank group is connected with the CPU water cooling block; the temperature sensor group comprises at least two temperature sensors, the temperature sensors are respectively arranged in the water storage tanks of the water storage tank group, and the temperature sensors are connected to the controller; the water level sensor group comprises at least two water level sensors, the water level sensors are respectively arranged at preset positions in the water storage tanks of the water storage tank group, and the water level sensors are connected to the controller; the heat generated by the block chain server is stored in water to generate hot water, and the hot water is stored in the water storage tank for people to use, so that the heat generated by the block chain server is effectively utilized, and the waste of heat is avoided.
Description
Technical Field
The invention relates to the technical field of water heaters, in particular to a water heater device based on block chain server heating.
Background
The block chain (Blockchain) is a novel application mode of computer technologies such as distributed data storage, point-to-point transmission, a consensus mechanism, an encryption algorithm and the like, is an important concept of the bit coin, is a decentralized database essentially, and is used as a bottom layer technology of the bit coin. The block chain is a series of data blocks which are associated by using a cryptographic method, and each data block contains information of one bitcoin network transaction, so that the validity (anti-counterfeiting) of the information is verified and the next block is generated. The blockchain server is used for node discovery, information exchange and data transmission. The block chain server needs to work continuously, a large amount of heat can be generated in the working process of the block chain server, the heat is processed to be dissipated through the heat dissipation device, the problem that the server is burnt out by the large amount of heat, waste of the heat is caused, and the heat cannot be well utilized is solved.
Disclosure of Invention
Therefore, a water heater device based on heating of the block chain server needs to be provided, and the problem of heat waste caused by heat dissipation of a large amount of heat generated by the existing block chain server through a heat dissipation device is solved.
In order to achieve the above object, the inventor provides a water heater device based on block chain server heating, comprising a water storage tank set, a CPU water cooling block, a GPU water cooling block, a first water pump, a controller, a temperature sensor set, a water level sensor set, a first electromagnetic valve set, a second electromagnetic valve set, a third electromagnetic valve set and a fourth electromagnetic valve set;
the water storage tank group comprises at least two water storage tanks, and each water storage tank comprises a first water inlet, a second water inlet, a first water outlet and a second water outlet;
the temperature sensor group comprises at least two temperature sensors, the temperature sensors are respectively arranged in the water storage tanks of the water storage tank group, and the temperature sensors are connected to the controller;
the water level sensor group comprises at least two water level sensors, the water level sensors are respectively arranged at preset positions in the water storage tanks of the water storage tank group, and the water level sensors are connected to the controller;
the first electromagnetic valve group comprises at least two electromagnetic valves, one end of each electromagnetic valve of the first electromagnetic valve group is connected to a first water outlet of a water storage tank of the water storage tank group through a water pipe, the other end of each electromagnetic valve of the first electromagnetic valve group penetrates through a CPU water cooling block and a GPU water cooling block through the water pipes to be connected to a water pumping port of a first water pump, and the electromagnetic valves of the first electromagnetic valve group are connected to a controller;
the second electromagnetic valve group comprises at least two electromagnetic valves, one end of each electromagnetic valve of the second electromagnetic valve group is connected to a second water inlet of the water storage tank group through a water pipe, the other end of each electromagnetic valve of the second electromagnetic valve group is connected to a water outlet of the first water pump through a water pipe, and the electromagnetic valves of the second electromagnetic valve group are connected to the controller;
the third electromagnetic valve group comprises at least two electromagnetic valves, one end of each electromagnetic valve of the third electromagnetic valve group is connected to a first water inlet of a water storage tank of the water storage tank group through a water pipe, the other end of each electromagnetic valve of the third electromagnetic valve group is connected to a tap water pipe through a water pipe, and the electromagnetic valves of the third electromagnetic valve group are connected to the controller;
the fourth electromagnetic valve group comprises at least two electromagnetic valves, one end of each electromagnetic valve of the fourth electromagnetic valve group is connected to a second water outlet of the water storage tank group through a water pipe, the other end of each electromagnetic valve of the fourth electromagnetic valve group is connected to a hot water outlet through a water pipe, and the electromagnetic valves of the fourth electromagnetic valve group are connected to the controller;
the CPU water-cooling block is arranged on a CPU of the block chain server, and the GPU water-cooling block is arranged on a GPU of the block chain server.
The water pump is characterized by further comprising a water storage radiator and a second water pump, wherein one end of the water storage radiator is connected to the other end of the electromagnetic valve of the third electromagnetic valve group, the other end of the water storage radiator is connected to a water outlet of the second water pump, a water pumping port of the second water pump is connected to the other end of the electromagnetic valve of the fourth electromagnetic valve group through a water pipe, and a control end of the second water pump is connected to the controller.
Further preferably, the water storage radiator is an air cooling radiator.
Further optimize, storage water tank group includes four storage water tanks, temperature sensor group includes four temperature sensor, water level sensor group includes four level sensor, first electromagnetism valves includes four solenoid valves, second electromagnetism valves includes four solenoid valves, third electromagnetism valves includes four solenoid valves, fourth electromagnetism valves includes four solenoid valves.
And further optimizing, the electromagnetic valve of the first electromagnetic valve group and the electromagnetic valve connected to the same water storage tank in the second electromagnetic valve group are linkage electromagnetic valves.
Different from the prior art, according to the technical scheme, when the block chain server works, the water temperature in the water storage tanks of the water storage tank group is respectively detected through the temperature sensor group, and when the water temperature in the water storage tanks is higher than a preset temperature, the electromagnetic valves in the corresponding first electromagnetic valve groups are closed through the controller; when the temperature of water in the water storage tank is lower than a preset temperature, the controller controls the electromagnetic valve of the corresponding first electromagnetic valve group to be opened, when the first water pump works, water is pumped from the water storage tank, the CPU and the GPU of the block chain server are cooled through the CPU water cooling block and the GPU water cooling block, meanwhile, the heated water enters the water storage tank again for storage, when the temperature in the water storage tank reaches the preset value, the electromagnetic valve in the corresponding first electromagnetic valve group is closed, the first water pump cannot pump water from the water storage tank, and water is pumped from other water storage tanks to cool the CPU and the GPU; when the temperature in the water storage tank reaches a preset value, the controller opens the electromagnetic valve of the corresponding fourth electromagnetic valve group, so that hot water in the water storage tank can enter the hot water outlet through the electromagnetic valve in the corresponding fourth electromagnetic valve group for people to use; when the water level in the water storage tank is lower than the preset value, the controller opens the electromagnetic valve in the corresponding third electromagnetic valve group to open, so that cold tap water enters the water storage tank, and when the water storage tank is full of water, the controller controls the electromagnetic valve in the corresponding second electromagnetic valve group to close, so that hot water cannot enter the second water storage tank. The heat generated by the block chain server is stored in water to generate hot water, and the hot water is stored in the water storage tank for people to use, so that the heat generated by the block chain server is effectively utilized, and the waste of heat is avoided.
Drawings
Fig. 1 is a schematic structural diagram of a water heater device based on blockchain server heating according to an embodiment.
Description of reference numerals:
110. a water storage tank set is arranged on the upper portion of the water tank,
120. a first electromagnetic valve group is arranged on the first electromagnetic valve group,
130. a second electromagnetic valve group is arranged on the upper portion of the first electromagnetic valve group,
140. a third electromagnetic valve group is arranged on the upper portion of the valve body,
150. a fourth electromagnetic valve group is arranged on the upper portion of the valve body,
160. a first water pump is arranged at the bottom of the water tank,
171. the water-cooling block of the CPU is provided with a water-cooling block,
172. the water-cooling block of the GPU is provided with a water-cooling block,
181. a second water pump is arranged on the first water pump,
182. a water storage radiator.
Detailed Description
To explain technical contents, structural features, and objects and effects of the technical solutions in detail, the following detailed description is given with reference to the accompanying drawings in conjunction with the embodiments.
Referring to fig. 1, the water heater apparatus based on heating by the block chain server according to the embodiment includes a water storage tank set 110, a CPU water cooling block 170, a GPU water cooling block 172, a first water pump 160, a controller, a temperature sensor set, a water level sensor set, a first solenoid valve set 120, a second solenoid valve set 130, and a third solenoid valve set 140;
the water storage tank set 110 comprises at least two water storage tanks, and each water storage tank comprises a first water inlet, a second water inlet, a first water outlet and a second water outlet;
the temperature sensor group comprises at least two temperature sensors, the temperature sensors are respectively arranged in the water storage tanks of the water storage tank group 110, and the temperature sensors are connected to the controller;
the water level sensor group comprises at least two water level sensors, the water level sensors are respectively arranged at preset positions in the water storage tanks of the water storage tank group 110, and the water level sensors are connected to the controller;
the first electromagnetic valve group 120 comprises at least two electromagnetic valves, one end of each electromagnetic valve of the first electromagnetic valve group 120 is connected to a first water outlet of a water storage tank of the water storage tank group 110 through a water pipe, the other end of each electromagnetic valve of the first electromagnetic valve group 120 passes through the CPU water cooling block 170 and the GPU water cooling block 172 through the water pipes to be connected to a water pumping port of the first water pump 160, and the electromagnetic valves of the first electromagnetic valve group 120 are connected to a controller;
the second electromagnetic valve group 130 comprises at least two electromagnetic valves, one end of each electromagnetic valve of the second electromagnetic valve group 130 is connected to a second water inlet of the water storage tank group 110 through a water pipe, the other end of each electromagnetic valve of the second electromagnetic valve group 130 is connected to a water outlet of the first water pump 160 through a water pipe, and the electromagnetic valves of the second electromagnetic valve group 130 are connected to the controller;
the third electromagnetic valve group 140 includes at least two electromagnetic valves, one end of each electromagnetic valve of the third electromagnetic valve group 140 is connected to the first water inlet of the water storage tank group 110 through a water pipe, the other end of each electromagnetic valve of the third electromagnetic valve group 140 is connected to a tap water pipe through a water pipe, and the electromagnetic valve of the third electromagnetic valve group 140 is connected to a controller;
the fourth electromagnetic valve group 150 comprises at least two electromagnetic valves, one end of each electromagnetic valve of the fourth electromagnetic valve group 150 is connected to the second water outlet of the water storage tank group 110 through a water pipe, the other end of each electromagnetic valve of the fourth electromagnetic valve group 150 is connected to the hot water outlet through a water pipe, and the electromagnetic valves of the fourth electromagnetic valve group 150 are connected to the controller;
the CPU water-cooling block 170 is disposed in the CPU of the blockchain server, and the GPU water-cooling block 172 is disposed in the GPU of the blockchain server.
The water storage tank set 110 comprises at least two water storage tanks, a first water storage tank and a second water storage tank; the temperature sensor group comprises at least two temperature sensors, a temperature sensor A and a temperature sensor B, wherein the temperature sensor A is arranged in the first water storage tank, and the temperature sensor B is arranged in the second water storage tank; the water level sensor group comprises at least two water level sensors, a water level sensor A and a water level sensor B, wherein the water level sensor A is arranged at a preset position in the first water storage tank, and the water level sensor B is arranged at a preset position in the second water storage tank; the first electromagnetic valve group 120 comprises at least two electromagnetic valves, an electromagnetic valve A1 and an electromagnetic valve B1, one end of the electromagnetic valve A1 is connected to a first water outlet of the first water storage tank through a water pipe, the other end of the electromagnetic valve A1 penetrates through the CPU water cooling block 170 and the GPU water cooling block 172 through the water pipe and is connected to a water pumping port of the first water pump 160, one end of the electromagnetic valve B1 is connected to a first water outlet of the second water storage tank through the water pipe, and the other end of the electromagnetic valve B1 penetrates through the CPU water cooling block 170 and the GPU water cooling block 172 through the water pipe and is connected to a water pumping port of the first water; the second electromagnetic valve set 130 comprises at least two electromagnetic valves, an electromagnetic valve a2 and an electromagnetic valve B2, one end of the electromagnetic valve a2 is connected to the second water inlet of the first water storage tank through a water pipe, the other end of the electromagnetic valve a2 is connected to the water outlet of the first water pump 160 through a water pipe, one end of the electromagnetic valve B2 is connected to the second water inlet of the second water storage tank through a water pipe, and the other end of the electromagnetic valve B2 is connected to the water outlet of the first water pump 160 through a water pipe; the third electromagnetic valve group 140 comprises at least two electromagnetic valves, an electromagnetic valve A3 and an electromagnetic valve B3, one end of the electromagnetic valve A3 is connected to the first water inlet of the first water storage tank through a water pipe, the other end of the electromagnetic valve A3 of the third electromagnetic valve group 140 is connected to a tap water pipe through a water pipe, one end of the electromagnetic valve B3 is connected to the first water inlet of the second water storage tank through a water pipe, and the other end of the electromagnetic valve A3 of the third electromagnetic valve group 140 is connected to the tap water pipe through a water pipe; the fourth electromagnetic valve group 150 comprises at least two electromagnetic valves, an electromagnetic valve a4 and an electromagnetic valve B4, one end of the electromagnetic valve a4 of the fourth electromagnetic valve group 150 is connected to the second water outlet of the first water storage tank of the water storage tank group 110 through a water pipe, the other end of the electromagnetic valve a4 of the fourth electromagnetic valve group 150 is connected to the hot water outlet through a water pipe, one end of the electromagnetic valve B4 of the fourth electromagnetic valve group 150 is connected to the second water outlet of the first water storage tank of the water storage tank group 110 through a water pipe, and the other end of the electromagnetic valve B4 of the fourth electromagnetic valve group 150 is connected to the hot water outlet through a water pipe;
when the CPU and the GPU of the blockchain server operate, the water temperatures in the first water storage tank and the second water storage tank are respectively detected by the temperature sensor a and the temperature sensor B, when the water temperature in one of the first water storage tank and the second water storage tank is higher than a preset temperature, the electromagnetic valve a1 or the electromagnetic valve B1 in the corresponding first electromagnetic valve group 120 is closed by the controller, for example, when the water temperature in the first water storage tank is higher than the preset temperature, the corresponding electromagnetic valve a1 is closed, when the water temperature in the water storage tank is lower than the preset temperature, the controller controls the electromagnetic valve B1 of the corresponding first electromagnetic valve to be opened, when the water temperature in the second water storage tank is lower than the preset temperature, the controller controls the electromagnetic valve B1 of the corresponding first electromagnetic valve to be opened, and when the first water pump 160 operates, the water is pumped from the tank, and the CPU water cooling block 170 and the GPU of the blockchain server are cooled, meanwhile, the heated water enters the water storage tank again for storage, when the temperature in the water storage tank reaches a preset value, the corresponding electromagnetic valve in the first electromagnetic valve group 120 is closed, the first water pump 160 cannot pump water from the water storage tank, and the water is pumped from other water storage tanks to cool the CPU and the GPU; when the temperature in the water storage tank reaches a preset value, the controller opens the corresponding electromagnetic valve of the fourth electromagnetic valve group 150, and if the water temperature in the first water storage tank reaches the preset value, the controller opens the corresponding electromagnetic valve A4, so that the hot water in the first water storage tank can enter the hot water outlet through the electromagnetic valve A4 for the use of personnel; when the water level in the water storage tank is lower than the preset value, the controller opens the electromagnetic valve in the third electromagnetic valve group 140 corresponding to the controller, which is beneficial to opening the electromagnetic valve a3 corresponding to the controller when the water level in the first water storage tank is lower than the preset value, so that the cold tap water enters the first water storage tank, and when the water in the water storage tank is full, the controller controls the electromagnetic valve in the second electromagnetic valve group 130 corresponding to the controller to be closed, and if the water in the second water storage tank is full, the controller controls the electromagnetic valve B2 to be closed, so that the hot water cannot enter the second water storage tank. The heat generated by the block chain server is stored in water to generate hot water, and the hot water is stored in the water storage tank for people to use, so that the heat generated by the block chain server is effectively utilized, and the waste of heat is avoided.
In this embodiment, in order to avoid that the water temperatures in all the water storage tanks reach the preset values and affect the heat dissipation of the block chain server, the system further includes a water storage radiator 182 and a second water pump 181, one end of the water storage radiator 182 is connected to the other end of the electromagnetic valve of the third electromagnetic valve group 140, the other end of the water storage radiator 182 is connected to the water outlet of the second water pump 181, the water pumping port of the second water pump 181 is connected to the other end of the electromagnetic valve of the fourth electromagnetic valve group 150 through a water pipe, and the control end of the second water pump 181 is connected to the controller. When the water temperatures in all the water storage tanks reach the preset value, the controller controls the second water pump 181 to work, hot water in all the water storage tanks is pumped out, the hot water enters the water storage tanks again through the third electromagnetic valve group 140 after being radiated by the water storage radiator 182, the water temperatures in the water storage tanks are cooled, and the problem that the water temperatures in all the water storage tanks reach the preset value and influence the heat radiation of the block chain server is avoided. The water storage radiator 182 may be an air-cooled radiator or a water-cooled radiator.
In this embodiment, in order to effectively cool down the block chain server and simultaneously more effectively use the water storage tanks, the water storage tank set 110 includes four water storage tanks, the temperature sensor set includes four temperature sensors, the water level sensor set includes four water level sensors, the first solenoid valve set 120 includes four solenoid valves, the second solenoid valve set 130 includes four solenoid valves, the third solenoid valve set 140 includes four solenoid valves, and the fourth solenoid valve set 150 includes four solenoid valves. Set up four storage water tanks, can guarantee that there is sufficient cold water in the storage water tank to cool down block chain server, also avoid too much storage water tank and cause extravagant phenomenon simultaneously.
In this embodiment, the electromagnetic valves of the first electromagnetic valve set 120 and the electromagnetic valves of the second electromagnetic valve set 130 connected to the same water storage tank are linkage electromagnetic valves. That is, the solenoid valve a1 in the first solenoid valve group 120 is linked with the solenoid valve a2 in the second solenoid valve group 130, when the solenoid valve a1 in the first solenoid valve group 120 is closed, the solenoid valve a2 is closed, and when the solenoid valve a1 is opened, the solenoid valve a2 is opened; solenoid valve B1 in the first solenoid valve group 120 is interlocked with solenoid valve B2 in the second solenoid valve group 130. Meanwhile, when one electromagnetic valve in the first electromagnetic valve group 120 is opened, the other electromagnetic valves in the first electromagnetic valve group 120 are closed, so that the utilization of cold water in the water storage tank is ensured, and the storage of hot water in the water storage tank is ensured.
It should be noted that, although the above embodiments have been described herein, the invention is not limited thereto. Therefore, based on the innovative concepts of the present invention, the technical solutions of the present invention can be directly or indirectly applied to other related technical fields by making changes and modifications to the embodiments described herein, or by using equivalent structures or equivalent processes performed in the content of the present specification and the attached drawings, which are included in the scope of the present invention.
Claims (1)
1. A water heater device based on block chain server heating is characterized by comprising a water storage tank set, a CPU water cooling block, a GPU water cooling block, a first water pump, a controller, a temperature sensor set, a water level sensor set, a first electromagnetic valve set, a second electromagnetic valve set, a third electromagnetic valve set and a fourth electromagnetic valve set; the water storage tank group comprises at least two water storage tanks, and each water storage tank comprises a first water inlet, a second water inlet, a first water outlet and a second water outlet; the temperature sensor group comprises at least two temperature sensors, the temperature sensors are respectively arranged in the water storage tanks of the water storage tank group, and the temperature sensors are connected to the controller; the water level sensor group comprises at least two water level sensors, the water level sensors are respectively arranged at preset positions in the water storage tanks of the water storage tank group, and the water level sensors are connected to the controller; the first electromagnetic valve group comprises at least two electromagnetic valves, one end of each electromagnetic valve of the first electromagnetic valve group is connected to a first water outlet of a water storage tank of the water storage tank group through a water pipe, the other end of each electromagnetic valve of the first electromagnetic valve group penetrates through a CPU water cooling block and a GPU water cooling block through the water pipes to be connected to a water pumping port of a first water pump, and the electromagnetic valves of the first electromagnetic valve group are connected to a controller; the second electromagnetic valve group comprises at least two electromagnetic valves, one end of each electromagnetic valve of the second electromagnetic valve group is connected to a second water inlet of the water storage tank group through a water pipe, the other end of each electromagnetic valve of the second electromagnetic valve group is connected to a water outlet of the first water pump through a water pipe, and the electromagnetic valves of the second electromagnetic valve group are connected to the controller; the third electromagnetic valve group comprises at least two electromagnetic valves, one end of each electromagnetic valve of the third electromagnetic valve group is connected to a first water inlet of a water storage tank of the water storage tank group through a water pipe, the other end of each electromagnetic valve of the third electromagnetic valve group is connected to a tap water pipe through a water pipe, and the electromagnetic valves of the third electromagnetic valve group are connected to the controller; the fourth electromagnetic valve group comprises at least two electromagnetic valves, one end of each electromagnetic valve of the fourth electromagnetic valve group is connected to a second water outlet of the water storage tank group through a water pipe, the other end of each electromagnetic valve of the fourth electromagnetic valve group is connected to a hot water outlet through a water pipe, and the electromagnetic valves of the fourth electromagnetic valve group are connected to the controller; the water cooling block of the CPU is arranged on the CPU of the block chain server, the water cooling block of the GPU is arranged on the GPU of the block chain server, the water storage tank group comprises four water storage tanks, the temperature sensor group comprises four temperature sensors, the water level sensor group comprises four water level sensors, the first electromagnetic valve group comprises four electromagnetic valves, the second electromagnetic valve group comprises four electromagnetic valves, the third electromagnetic valve group comprises four electromagnetic valves, the fourth electromagnetic valve group comprises four electromagnetic valves, and the electromagnetic valves of the first electromagnetic valve group and the electromagnetic valves of the second electromagnetic valve group which are connected to the same water storage tank are linkage electromagnetic valves;
when the CPU and the GPU of the block chain server work, the water temperatures in the first water storage tank and the second water storage tank are respectively detected through two temperature sensors, when the water temperature in one of the first water storage tank and the second water storage tank is higher than a preset temperature, the electromagnetic valve A1 or the electromagnetic valve B1 in the corresponding first electromagnetic valve group 120 is closed through the controller, when the water temperature in the first water storage tank is higher than the preset temperature, the corresponding electromagnetic valve A1 is closed, when the water temperature in the water storage tank is lower than the preset temperature, the controller controls the electromagnetic valve of the corresponding first electromagnetic valve group 120 to be opened, when the water temperature in the second water storage tank is lower than the preset temperature, the controller controls the electromagnetic valve B1 of the corresponding first electromagnetic valve group 120 to be opened, when the first water pump 160 works, water is pumped from the water storage tank, and is pumped through the CPU water cooling block 171 and the GPU 172 to cool the CPU and the GPU of the block chain server, meanwhile, the heated water enters the water storage tank again for storage, when the temperature in the water storage tank reaches a preset value, the corresponding electromagnetic valve in the first electromagnetic valve group 120 is closed, the first water pump 160 cannot pump water from the water storage tank, and the water is pumped from other water storage tanks to cool the CPU and the GPU; when the temperature in the water storage tank reaches a preset value, the controller opens the corresponding electromagnetic valve of the fourth electromagnetic valve group 150, and when the temperature of the water in the first water storage tank reaches the preset value, the controller opens the corresponding electromagnetic valve A4, so that the hot water in the first water storage tank can enter the hot water outlet through the electromagnetic valve A4 for the use of personnel; when the water level in the water storage tank is lower than the preset value, the controller opens the corresponding electromagnetic valve in the third electromagnetic valve group 140 and opens, when the water level in the first water storage tank is lower than the preset value, the controller opens the corresponding electromagnetic valve A3 and opens, so that cold tap water enters the first water storage tank, when the water in the water storage tank is full, the controller controls the corresponding electromagnetic valve in the second electromagnetic valve group 130 and closes, when the water in the second water storage tank is full, the controller controls the electromagnetic valve B2 and closes, so that hot water cannot enter the second water storage tank, heat generated by the block chain server is stored in water, hot water is generated and stored in the water storage tank for people to use, the heat generated by the block chain server is effectively utilized, and waste of heat is avoided;
in order to avoid that the water temperature in all the water storage tanks reaches a preset value and affects the heat dissipation of the block chain server, the block chain server further comprises a water storage radiator 182 and a second water pump 181, wherein one end of the water storage radiator 182 is connected to the other end of the electromagnetic valve of the third electromagnetic valve group 140, the other end of the water storage radiator 182 is connected to the water outlet of the second water pump 181, the water pumping port of the second water pump 181 is connected to the other end of the electromagnetic valve of the fourth electromagnetic valve group 150 through a water pipe, the control end of the second water pump 181 is connected to the controller, when the water temperature in all the water storage tanks reaches the preset value, the controller controls the second water pump 181 to work to pump out the hot water in all the water storage tanks, the hot water enters the water storage tanks again through the third electromagnetic valve group 140 after the heat dissipation through the water storage radiator 182, the water temperature in the water storage tanks is cooled, the heat dissipation of the blockchain server is affected, wherein the water storage radiator 182 is an air-cooled radiator or a water-cooled radiator.
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CN104750210A (en) * | 2013-12-31 | 2015-07-01 | 鸿富锦精密工业(深圳)有限公司 | Server system |
CN204943855U (en) * | 2015-09-08 | 2016-01-06 | 温州安信科技有限公司 | Waste heat recovering water heater of air compressor |
CN207907475U (en) * | 2018-02-26 | 2018-09-25 | 宁德市东侨经济开发区睿迅网络科技有限公司 | A kind of hot water apparatus based on the heating of block chain server |
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