KR20200024410A - Cooling water saving type crypto currency mining system - Google Patents

Abstract

The present invention relates to a cryptocurrency mining system of a liquid refrigerant saving type, which is capable of maximizing a cooling effect. The cryptocurrency mining system comprises: a calculation device; a power supply device; a liquid refrigerant bath; a liquid refrigerant; a first supply pipe; a collection pipe; a circulation pump; and a cooling heat exchanger.

Description

Cooling water saving type crypto currency mining system

The present invention is provided with a cooling system that cools by submerging the electronic equipment that generates heat when cryptocurrency mining in a bath containing a non-conductive liquid refrigerant, in particular liquid refrigerant saving cryptocurrency mining configured to reduce the consumption of liquid refrigerant It is about the system.

In general, cryptocurrency is a digital currency issued as a reward for solving a predetermined cipher and algorithm.

Among the cryptocurrencies, Bitcoin, the most popular cryptocurrency, has a structure in which no central device for issuing and managing currencies exists. Bitcoin transactions are made through a peer-to-peer-based distributed database. will be.

Bitcoin as described above is stored in the form of a wallet file, each wallet is given a unique address, and Bitcoin is a transaction based on the unique address and public key cryptography.

Cryptocurrency such as Bitcoin automatically generates a fixed amount of Bitcoin at regular intervals according to a predetermined algorithm, and the generated cryptocurrency is transferred to ownership after solving complex mathematical and cryptographic problems created by a specific algorithm. .

Solving the complicated mathematical and cryptographic problems created by the specific algorithms of Bitcoin above, the GPU mounted on the graphics card or the hashboard is superior to the CPU installed in the main mode of the computer. It relies on multiple hashboards with multiple dedicated ASICs that perform only the operations required for the card or mining.

Therefore, the cryptocurrency mining system is configured and used by connecting a plurality of graphics cards or a plurality of hashboard to one main board.

However, in the conventional cryptocurrency mining system, a lot of heat is generated by mounting a plurality of graphics boards or a plurality of hashboards equipped with a plurality of ASICs for operation, and a cooling system for cooling the heat is provided.

Conventional cooling systems are air cooled, with multiple cooling fans installed around the graphics card or hashboard to cool the heat by convection. However, the air-cooled method increases the volume of the device due to the plurality of cooling fans, and also consumes a lot of power and has a problem of generating noise.

In addition, the cooling fan has a problem in that the cooling efficiency is lowered by contact with dust, etc. during long-term use, and the maintenance and repair costs are generated, such as frequent occurrence of failure due to dust.

In order to solve this problem, recently, a cooling system has been developed in which a non-conductive liquid refrigerant (w) is filled in a water tank, and a graphic card or a hash board is immersed therein to directly contact the liquid refrigerant (w) to perform heat exchange. It became.

However, such a cooling system consumes a large amount of liquid refrigerant (w) in order to submerge both the graphics card or the hash board and the power supply in the liquid refrigerant (w), resulting in a problem that the productivity is lowered.

Republic of Korea Patent Publication No. 10-2014-0020060

The present invention is to solve the above problems, the liquid refrigerant tank 200, the first cooling unit 210 and the power supply unit 120 is accommodated in the operation unit 110 is accommodated, the upper end is the first By partitioning into the second cooling unit 220 connected to the cooling unit 210, when the liquid refrigerant (w) is supplied to the first cooling unit 210, the liquid refrigerant (w) in the first cooling unit (210) The present invention provides a liquid refrigerant saving type cryptocurrency mining system that can maximize the cooling effect while reducing the amount of liquid refrigerant (w) by cooling the power supply device 120 while flowing to the second cooling unit 220. There is this.

Liquid refrigerant saving cryptocurrency mining system of the present invention to achieve the above object, Computing apparatus for mining cryptocurrency; A power supply for supplying power to the operation unit; A liquid refrigerant tank in which the associating device is installed, and the upper cooling part is connected to the first cooling part and divided into a second cooling part in which the power supply device is installed; A nonconductive liquid refrigerant contained in the liquid refrigerant tank; A first supply pipe for supplying the liquid refrigerant to the liquid refrigerant tank; A recovery tube for recovering the liquid refrigerant from the liquid refrigerant tank; A circulation pump connected to the first supply pipe and the recovery pipe to circulate the liquid refrigerant; A cooling heat exchanger for cooling the liquid refrigerant recovered from the recovery pipe; It includes, The first supply pipe is connected to the first cooling unit supplies the liquid refrigerant to the first cooling unit, The recovery tube is connected to the second cooling unit, The first cooling unit in the first 2 The liquid refrigerant moved to the cooling unit is recovered.

Distribution means provided at an upper end of the second cooling unit and distributing the liquid refrigerant moving from the first cooling unit to the second cooling unit evenly on the upper end of the second cooling unit; It includes more.

The distribution means is composed of a plate-shaped distribution plate covering the upper portion of the power supply device, the distribution plate is formed with a plurality of distribution holes spaced apart at regular intervals, the partition wall is formed along the rim.

A hot water generating device connected to the recovery pipe and using the heated liquid refrigerant recovered from the recovery pipe to generate hot water; It includes.

The hot water raw growth value, hot water tank in which water is stored therein; A heat exchanger tube provided in the hot water tank and connected to the recovery tube to allow the liquid refrigerant heated therein to flow; A second supply pipe for supplying cold water to the hot water tank; A discharge pipe discharging hot water heated by the heat exchange pipe to the outside; It includes.

Liquid refrigerant saving cryptocurrency mining system of the present invention as described above has the following effects.

The liquid refrigerant tank is divided into the first cooling unit accommodating the computing device and the second cooling unit accommodating the power supply device and having an upper end connected to the first cooling unit, thereby filling the first cooling unit. By cooling the power supply device while the liquid refrigerant flows from the first cooling part to the second cooling part, the power supply is cooled by not filling the second cooling part with the liquid coolant. It has the effect of maximizing cooling efficiency while reducing.

In particular, the distribution plate having a plurality of distribution holes formed on the second cooling unit is provided, so that the liquid refrigerant flows evenly in the power supply device, thereby increasing the cooling efficiency of the power supply device.

In addition, by providing the hot water generating device for generating hot water by using the heated liquid refrigerant to be recovered to the recovery tube, it is possible to use hot water while increasing the cooling efficiency of the liquid refrigerant, thereby improving the productivity.

1 is a perspective view of a liquid refrigerant saving cryptocurrency mining system according to an embodiment of the present invention,
2 is a front structural diagram of a liquid refrigerant saving cryptocurrency mining system according to an embodiment of the present invention,
Figure 3 is an enlarged perspective view showing the distribution means of the liquid refrigerant saving cryptocurrency mining system according to an embodiment of the present invention,
4 is an internal structure diagram of a hot water generating device of a liquid refrigerant saving cryptocurrency mining system according to an embodiment of the present invention,
5 is a structural diagram of a liquid refrigerant saving cryptocurrency mining system equipped with a distribution means according to another embodiment of the present invention.

 2 is a front structural diagram of a liquid refrigerant saving cryptocurrency mining system according to an embodiment of the present invention, Figure 3 is an enlarged perspective view of the distribution means of the liquid refrigerant saving cryptocurrency mining system according to an embodiment of the present invention 4 is an internal structural diagram of a hot water generating device of a liquid refrigerant saving cryptocurrency mining system according to an embodiment of the present invention, Figure 5 is a liquid refrigerant saving cryptocurrency having a distribution means according to another embodiment of the present invention, The structure diagram of the mining system.

1 to 5, the liquid refrigerant saving cryptocurrency mining system according to an embodiment of the present invention, the computing device 110, the power supply device 120, the liquid refrigerant tank 200, liquid refrigerant (w), the first supply pipe 310, recovery pipe 320, the circulation pump 400, the cooling heat exchanger 500, the distribution means and the hot water generating device 700.

The computing device 110 is a device used for mining cryptocurrency, and comprises a main board and a plurality of hash boards equipped with a plurality of graphics cards mounted on the main board or a plurality of dedicated ASICs.

In this case, since a lot of heat is generated in the graphic card or the hash board, the computing device 110 is immersed in the liquid refrigerant w in the liquid refrigerant tank 200 to be described later and cooled.

The power supply device 120 supplies power required for operation to the computing device 110, and is a power supply generally used for a computer.

The power supply device 120 receives the 220V power from the outside and converts the DC power supply to the arithmetic device 110 to lower the voltage.

Since a lot of heat is also generated in the power supply device 120, it is disposed in the liquid refrigerant tank 200 like the arithmetic unit 110 and is cooled by the liquid refrigerant w.

The liquid refrigerant tank 200 has an open top in the shape of a hexahedron, and a cover for minimizing evaporation of the liquid refrigerant w is detachably mounted on the top.

In addition, the arithmetic unit and the power supply device 120 are installed in the liquid refrigerant tank 200, and the first supply pipe 310 and the recovery pipe 320 to circulate the liquid refrigerant (w). This is installed.

More specifically, the inside of the liquid refrigerant tank 200 is divided into two first cooling unit 210 and the second cooling unit 220 disposed between the first cooling unit 210.

The first cooling unit 210 is a space formed on both sides of the liquid refrigerant tank 200, respectively, and the computing device 110 is installed therein.

In addition, the first supply pipe 310 to be described later is installed below the first cooling unit 210 and the liquid refrigerant (w) is supplied from the first supply pipe (310).

The second cooling unit 220 is a space disposed between the first cooling unit 210, the power supply device 120 is installed inside.

In addition, an upper end of the second cooling unit 220 is connected to an upper end of the first cooling unit 210.

That is, the first cooling unit 210 and the second cooling unit 220 are both open so that the upper end is in communication with each other.

The liquid refrigerant tank 200 fills the liquid refrigerant w in the first cooling unit 210, and the arithmetic unit 110 is completely submerged in the liquid refrigerant w to cool.

In addition, when the first cooling unit 210 is filled with the liquid refrigerant (w), the liquid refrigerant (w) is moved to the second cooling unit (220), the liquid refrigerant (w) is the second cooling The power supply device 120 is cooled by flowing downward along the power supply device 120 installed in the unit 220.

Here, the second cooling unit 220 is not filled with the liquid refrigerant w, but is filled shallowly in the lower portion.

In addition, the recovery pipe 320 is mounted to the lower portion of the second cooling unit 220 to recover the liquid refrigerant (w) filled in the first cooling unit 210, the second cooling unit 220 At the top of the) is provided with the distribution means to be described later.

As such, the liquid cooling tank 200 includes the first cooling unit 210 in which the computing device 110 is accommodated, the power supply device 120, and an upper end of the first cooling unit 210. By dividing into the second cooling unit 220 connected to, the liquid refrigerant (w) filled in the first cooling unit 210 is transferred from the first cooling unit 210 to the second cooling unit 220 By cooling the power supply device 120 while flowing, the power supply device 120 is cooled without filling the second cooling unit 220 with the liquid refrigerant w, thereby reducing the amount of liquid refrigerant w used. It has the effect of maximizing cooling efficiency while reducing.

On the other hand, as shown in Figure 2 and 3, the upper portion of the second cooling unit 220, the support 230 is provided with a 220V power supply terminal 130 is installed in the power supply device 120. The power supply device 120 is provided on the left and right sides of the power supply terminal 130.

The wire branched from the power supply terminal 130 is connected to the power supply device 120.

In addition, the electric wire for supplying power to the power supply terminal 130 is continued through the conduit 240 provided on the outside of the liquid refrigerant tank (200).

Here, the conduit 240 has a hollow cylindrical shape and is bent to a 'b' shape.

As such, the wires 240 having the passages leading to the wires are formed in a bent form, thereby minimizing the evaporation of the liquid refrigerant contained in the liquid refrigerant tank 200 and exiting to the outside.

Meanwhile, the liquid refrigerant w supplied to the first cooling unit 210 is a non-conductive liquid, and does not damage the computing device and the power supply device 120.

The first supply pipe 310 is a tube for supplying the liquid refrigerant (w) to the first cooling unit 210, one end is connected to the first cooling unit 210, the other end of the cooling heat exchange will be described later Is connected to the device 500.

The first supply pipe 310 is a passage for supplying the liquid refrigerant w cooled by the cooling heat exchanger 500 to the first cooling unit 210.

One end of the recovery pipe 320 is connected to the second cooling unit 220, and the other end thereof is connected to the cooling heat exchanger 500 through the circulation pump 400 and the hot water generator 700, which will be described later. .

The recovery pipe 320 moves the liquid refrigerant (w) heated by the computing device 110 and the power supply device 120 in the liquid refrigerant tank 200 to the cooling heat exchanger (500). It is a passage for letting go.

On the other hand, the circulation pump 400 is a device for providing a pressure for circulating the liquid refrigerant (w) flowing along the first supply pipe 310 and the recovery pipe 320, and the recovery pipe 320 and Is connected, it is disposed between the liquid refrigerant tank 200 and the hot water generating device 700.

The cooling heat exchanger 500 is an air-cooled heat exchanger, and of course, it may be replaced with another type of heat exchanger.

The cooling heat exchanger 500 is disposed between the first supply pipe 310 and the recovery pipe 320, and cooled again with the heated liquid refrigerant w recovered from the recovery pipe 320. Supply to the first supply pipe (310).

On the other hand, the distribution means is provided on the upper end of the second cooling unit 220, the liquid coolant (w) moving from the first cooling unit 210 to the second cooling unit 220, the second To distribute evenly to the top of the cooling unit 220.

Specifically, the distribution means is the distribution means consists of a plate-shaped distribution plate 610 covering the upper portion of the power supply device (120).

The distribution plate 610 is formed with a plurality of distribution holes 611 spaced apart from each other, the partition wall 612 is formed along the edge.

The distribution plate 610 accommodates the liquid refrigerant (w) flowing from the first cooling unit 210, and flows down the upper portion of the power supply device 120 through the distribution hole 611. do.

As such, the distribution plate 610 having a plurality of distribution holes 611 formed on the second cooling unit 220 is provided, such that the liquid refrigerant w flows evenly through the power supply device 120. The effect of increasing the cooling efficiency of the power supply device 120 is generated.

In some cases, the distribution means may be composed of a distribution turbine 620 instead of the distribution plate 610.

As shown in FIG. 5, the distribution turbine 620 shown on the left side is rotatably mounted on the upper portion of the second cooling unit 220, and on the outside thereof, the distribution turbine 620 is dropped from the first cooling unit 210. A plurality of rotary blades 621 that rotate in collision with the liquid refrigerant (w) is provided.

Here, the rotary blade 621 is formed with a concave receiving portion 621a, the liquid refrigerant (w) falling from the first cooling unit 210 does not flow directly to the lower portion of the receiving portion (621a). While standing, the rotary blade 621 is rotated to flow down to the lower portion to distribute evenly to the power supply device 120.

Thus, the distribution means is made of the distribution turbine 620 is provided with a plurality of rotary blades 621, while rotating the rotary blade 621 evenly distributes the liquid refrigerant (w) to the power supply device (120). In the distribution, the plurality of the rotary blades 621 is rotated in contact with the liquid refrigerant (w) to cool the liquid refrigerant (w) has an effect of increasing the cooling efficiency.

In addition, in some cases, such as the distribution turbine 620 shown on the right side of Figure 5 may be installed in the lower portion of the distribution plate 610 to be rotated by the liquid refrigerant discharged from the distribution hole 611. .

In this case, the left and right are spaced apart from each other according to the position and the number of the distribution holes 611, the liquid refrigerant (w) can be more evenly distributed to the power supply device (120).

On the other hand, the hot water generating device 700 is connected to the recovery pipe 320 to generate hot water using the heated liquid refrigerant (w) recovered from the recovery pipe 320, specifically, a hot water tank ( 710, the heat exchange tube 720, the second supply pipe 730 and the discharge pipe 740.

The hot water tank 710 is a water tank in which water to be used as hot water is stored, and disposed between the circulation pump 400 and the cooling heat exchanger 500, the recovery pipe 320 branched from the circulation pump 400. ) Is mounted at the top, and the recovery pipe 320 is branched back to the cooling heat exchanger 500 at the bottom.

The heat exchange tube 720 is connected to the recovery pipe 320 and the heated liquid refrigerant w flows inside the hot water tank 710.

The heat exchanger tube 720 is bent in a zigzag shape so that the liquid refrigerant w stays in the hot water tank 710 for a long time.

The second supply pipe 730 is a pipe for supplying cold water to the hot water tank 710 and is connected to an external water supply facility.

The second supply pipe 730 is configured to automatically supply cold water when the hot water of the hot water tank 710 is discharged to the outside.

The discharge pipe 740 is a pipe for discharging the hot water heated by the heat exchange tube 720 to the outside, the manual valve is mounted so that the user can open the manual valve to use hot water when necessary.

Of course, in some cases, when the hot water is used for heating, the second supply pipe 730 and the discharge pipe 740 may be connected to a heating pipe to circulate the hot water through the heating pipe.

Liquid refrigerant saving type cryptocurrency mining system according to an embodiment of the present invention made of the above configuration, the liquid refrigerant tank 200, the first cooling unit 210 is accommodated in the operation unit 110, and the power source By supplying the supply device 120 and the upper part is partitioned into the second cooling unit 220 connected to the first cooling unit 210, the liquid refrigerant (w) filled in the first cooling unit 210 is filled By cooling the power supply device 120 while flowing from the first cooling unit 210 to the second cooling unit 220, the second cooling unit 220 is not filled with the liquid refrigerant w. By cooling the power supply 120 without reducing the amount of liquid refrigerant (w) has the effect of maximizing the cooling efficiency.

In particular, the distribution plate 610 having a plurality of distribution holes 611 formed on the second cooling unit 220 is provided, so that the liquid refrigerant w flows evenly through the power supply device 120. The effect of increasing the cooling efficiency of the power supply device 120 is generated.

In addition, the hot water generating device 700 for generating hot water using the heated liquid refrigerant (w) recovered by the recovery pipe 320 is provided, thereby increasing the cooling efficiency of the liquid refrigerant (w) while It can be used to produce the effect of improving productivity.

The present invention is not limited thereto, and the present invention may be modified in various forms by those skilled in the art without departing from the spirit and scope of the appended claims, and such modifications should be construed as being within the scope of the present invention. something to do.

110: arithmetic unit 120: power supply
200: liquid refrigerant tank 210: first cooling unit
220: second cooling unit w: liquid refrigerant
310: first supply pipe 320: recovery pipe
400: circulation pump 500: cooling heat exchanger
610: distribution plate 611: distribution hole
612 bulkhead 620 distribution turbine
621: rotor blade 621a: accommodating part
700: hot water generator 710: hot water tank
720: heat exchanger tube 730: second supply tube
740: discharge pipe

Claims (5)

A computing device for mining cryptocurrency;
A power supply for supplying power to the operation unit;
A liquid refrigerant tank in which the associating device is installed, and an upper end portion is connected to the first cooling part and divided into a second cooling part in which the power supply device is installed;
A nonconductive liquid refrigerant contained in the liquid refrigerant tank;
A first supply pipe for supplying the liquid refrigerant to the liquid refrigerant tank;
A recovery tube for recovering the liquid refrigerant from the liquid refrigerant tank;
A circulation pump connected to the first supply pipe and the recovery pipe to circulate the liquid refrigerant;
A cooling heat exchanger for cooling the liquid refrigerant recovered from the recovery pipe; Including but not limited to:
The first supply pipe is connected to the first cooling unit to supply the liquid refrigerant to the first cooling unit,
The recovery pipe is connected to the second cooling unit, liquid refrigerant saving cryptocurrency mining system, characterized in that for recovering the liquid refrigerant moved from the first cooling unit to the second cooling unit.
The method of claim 1,
Distribution means provided at the upper end of the second cooling unit and distributing the liquid refrigerant moving from the first cooling unit to the second cooling unit evenly on the upper end of the second cooling unit; Liquid refrigerant saving cryptocurrency mining system further comprising a.
The method of claim 2,
The distribution means is composed of a plate-shaped distribution plate covering the upper portion of the power supply device,
The distribution plate is formed with a plurality of distribution holes spaced apart at regular intervals, liquid refrigerant saving cryptocurrency mining system, characterized in that the partition is formed along the edge.
The method according to any one of claims 1 to 3,
A hot water generating device connected to the recovery pipe and using the heated liquid refrigerant recovered from the recovery pipe to generate hot water; Cryptocurrency mining system capable of producing hot water, characterized in that it comprises a.
The method of claim 4, wherein
The hot water raw growth value,
A hot water tank in which water is stored therein;
A heat exchanger tube provided in the hot water tank and connected to the recovery tube to allow the liquid refrigerant heated therein to flow;
A second supply pipe for supplying cold water to the hot water tank;
A discharge pipe discharging hot water heated by the heat exchange pipe to the outside; Cryptocurrency mining system capable of producing hot water, characterized in that it comprises a.

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