CN210181606U - Small integrated water-cooling heat exchanger system for block chain operation center - Google Patents

Abstract

The utility model discloses a small-size integrated form water-cooling heat exchanger system for block chain operation center, it includes: a box body; the block chain operation center comprises a plurality of computing devices arranged in a box body; the water-cooling heat exchange device comprises a soft water treatment module, a plate type heat exchange unit module and a plate type heat exchange unit module, wherein the soft water treatment module and the plate type heat exchange unit module are arranged in the box body; a first pipe body is arranged between the soft water treatment module and the plate type heat exchange unit module, and a first control valve module is arranged on the first pipe body; the soft water treatment module is connected with the water inlet pipeline; the plate type heat exchange unit module comprises a plate type heat exchanger, a hot side inlet and a hot side outlet which are communicated with a first heat exchange channel of the plate type heat exchanger, and a cold side inlet and a cold side outlet which are communicated with a second heat exchange channel of the plate type heat exchanger, wherein the hot side inlet is connected with a first pump body and a water return pipeline module, the hot side outlet is connected with a water supply pipeline module, and the water return pipeline module and the water supply pipeline module are both connected with computing equipment; and the cold side inlet and the cold side outlet are both connected with the cooling module.

Description

Small integrated water-cooling heat exchanger system for block chain operation center

The technical field is as follows:

the utility model relates to a block chain heat transfer technical field refers in particular to a small-size integrated form water-cooling heat exchanger system for block chain operation center.

Background art:

with the continuous development of network applications, the problems of the improvement of internet access speed, the continuity of services and the enhancement of the availability and stability of the egress link are solved. High performance blockchain technology is widely used in office and industrial production.

The block chain technology is a brand new distributed infrastructure and a computing mode which utilize a block chain type data structure to verify and store data, utilize a distributed node consensus algorithm to generate and update data, utilize a cryptography mode to ensure the safety of data transmission and access, and utilize an intelligent contract composed of automatic script codes to program and operate data, and 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. The data security level of the block chain technology is high.

With the development of the blockchain technology, more and more blockdata are required to be stored in the blockchain network, and a long-time and high-reliability secure storage is required, and the frequency of data reading and recording required by the blockchain network is also higher and higher. In the high-intensity use process, the pressure of the heat dissipation function of the computer equipment is great.

The existing machine room adopts an ordinary machine case, the machine room is internally provided with a small fan for heat dissipation, frames in the whole machine room are arranged in rows, a central air conditioner and other overall heat dissipation devices are arranged above the machine room, the narrow air inside the machine room is dry, the comfort of a user in the machine room is reduced, meanwhile, the heat dissipation effect of the machine core of the computer equipment is not ideal enough, in addition, in order to protect the machine core of the computer equipment, the requirement on the dust content of air inlet in the machine room space is higher, the power consumption of a cooling fan is larger, and the effects of environmental protection and energy saving cannot be achieved.

In view of the above, the present inventors propose the following.

The utility model has the following contents:

an object of the utility model is to overcome prior art's not enough, provide a small-size integrated form water-cooled heat exchanger system for block chain operation center.

In order to solve the technical problem, the utility model discloses a following technical scheme: this a small-size integrated form water-cooling heat exchanger system for block chain operation center includes: a box body; a blockchain operation center comprising a plurality of computing devices disposed within the enclosure; the water-cooling heat exchange device comprises a soft water treatment module arranged in the box body, a plate type heat exchange unit module connected with the soft water treatment module and a cooling module connected with the plate type heat exchange unit module, wherein the cooling module is arranged on the outer side of the box body; a first pipe body is arranged between the soft water treatment module and the plate type heat exchange unit module, and a first control valve module is arranged on the first pipe body; the soft water treatment module is connected with a water inlet pipeline; the plate type heat exchanger unit module comprises a plate type heat exchanger arranged in the box body, a hot side inlet and a hot side outlet which are communicated with a first heat exchange channel in the plate type heat exchanger, and a cold side inlet and a cold side outlet which are communicated with a second heat exchange channel in the plate type heat exchanger, wherein the hot side inlet is connected with the first pump body and then connected with a water return pipeline module, the hot side outlet is connected with a water supply pipeline module, and the water return pipeline module and the water supply pipeline module are both connected with computing equipment so as to cool and radiate the computing equipment; the cold side inlet and the cold side outlet are both connected with the cooling module.

Further, in the above technical solution, the box body is a container, and a fan is further disposed outside the container; the block chain operation center also comprises a power distribution cabinet and a central control box which are arranged in the box body.

Further, in the above technical solution, the soft water treatment module includes a precision filter, a water softener and a softened water tank, which are connected in sequence, and the precision filter is connected to the water inlet pipe after being connected to the eighth stop valve and the first proportional valve; a second pump body is arranged between the softened water tank and the first pipe body, and a high-low water level meter is arranged on the softened water tank.

Furthermore, in the above technical scheme, the first control valve module includes a first check valve and a first stop valve that are sequentially disposed on the first pipe body, the first pipe body is further connected with a second stop valve and an expansion tank, and the first pipe body is further provided with a first safety valve and a first pressure sensor.

Further, in the above technical scheme, still be provided with the second body between the hot side import and the first pump body, this second body is connected first body is provided with first manometer, first thermometer, first exhaust valve, third stop valve, second temperature sensor, fourth stop valve, second check valve on this second body, still is provided with first filter, fifth stop valve between this first pump body and the return water pipe module.

Furthermore, in the above technical solution, a third pipe and a third pump body are arranged between the cold side inlet and the cooling module, and a sixth stop valve, a second filter, a third temperature sensor, a second pressure gauge, a second temperature gauge, and a first drain valve are further arranged on the third pipe.

Furthermore, in the above technical solution, a fourth pipe is disposed between the cold side outlet and the cooling module, and a seventh stop valve, a fourth temperature sensor, a third pressure gauge, a third temperature gauge, and a second exhaust valve are further disposed on the fourth pipe.

Furthermore, in the above technical scheme, the water return pipeline module includes a water return main pipeline and a plurality of water return branch pipelines distributed in parallel, the water return branch pipeline is provided with a plurality of first pipe interfaces and a first valve body for controlling the on-off of the first pipe interfaces, and the first pipe interfaces are connected with the computing equipment through water return hoses.

Furthermore, in the above technical solution, the water supply pipeline module includes a main water supply pipeline and a plurality of water supply branch pipelines distributed in parallel, the water supply branch pipelines are located beside the return water branch pipeline and distributed in parallel, the water supply branch pipelines are provided with a plurality of second pipe interfaces and second valve bodies for controlling the second pipe interfaces to be connected and disconnected, and the second pipe interfaces are connected with the computing equipment through water supply hoses; and a fifth pipeline is connected between the main water supply pipeline and the hot side outlet, a fourth pressure gauge, a fourth temperature gauge and a ninth stop valve and a fifth temperature sensor are arranged on the fifth pipeline, and a blow-down valve is further arranged on the fifth pipeline.

Further, in the above technical solution, the cooling module is one of a cooling tower and an air cooling mechanism.

After the technical scheme is adopted, compared with the prior art, the utility model has following beneficial effect: when the utility model is used, surface water or tap water is connected through the water inlet pipeline, and after the surface water or the tap water enters the soft water treatment module, the soft water treatment module carries out water softening treatment to form soft water; soft water flows into a closed internal circulation heat exchange passage formed by a first heat exchange passage, a hot side outlet, a water supply pipeline module, computing equipment, a water return pipeline module, a first pump body, a hot side inlet and a first heat exchange passage in the plate type heat exchange unit module, and after the closed internal circulation heat exchange passage is filled with the soft water, the first control valve module controls the first pipe body to be closed, so that the closed internal circulation heat exchange passage is not filled with the soft water any more; when soft water is not enough in the closed inner loop heat transfer passageway, open through first body of first control valve module control to it fills soft water for closed inner loop heat transfer passageway again. Then, the first pump body works to enable the soft water in the closed internal circulation heat exchange passage to circularly flow, when the soft water flows through the computing equipment, the heat generated when the computing equipment operates can be quickly taken away, and the purpose of quickly dissipating heat is achieved, wherein the temperature of the soft water is increased after the soft water absorbs the heat, and the soft water flows into the first heat exchange channel in the plate heat exchanger through the water return pipeline module, the first pump body and the hot side inlet; meanwhile, the cold medium in the cooling module enters from a cold side inlet of the plate heat exchanger, flows through a second heat exchange channel in the plate heat exchanger, flows out from a cold side outlet, and flows to the cooling module again, so as to form a circulation, when the soft water with high temperature after absorbing heat passes through a first heat exchange channel in the plate heat exchanger, the soft water with high temperature can exchange heat with the cold medium flowing through the second heat exchange channel in the plate heat exchanger, so that the temperature of the soft water flowing out from a hot side outlet in the plate heat exchanger is reduced, the soft water with low temperature flows to the computing equipment through the water supply pipeline module, the heat generated when the computing equipment runs can be taken away quickly again, the purpose of quick heat dissipation is achieved, the circulation is continuous, the whole block chain operation center is quickly dissipated, the heat dissipation effect is ideal, and the air in the box body is not dried, but the potential safety hazard of prevention dry air with the fire to can solve because the core for protection computer equipment, the dust content requirement of admitting air to the computer lab space is higher, the great problem of cooling blower's consumption, the order the utility model discloses extremely strong market competition has. Furthermore, the utility model discloses each module part is all integrated in a box, its compact structure to can be according to the demand shift position of use, and be convenient for transport, it is very convenient to use.

Description of the drawings:

fig. 1 is a layout diagram of the present invention;

fig. 2 is a perspective view of the present invention;

FIG. 3 is an internal structural view of the present invention;

FIG. 4 is a schematic structural view of the present invention;

FIG. 5 is a structural diagram of the reclaimed water cooling heat exchanger of the present invention;

fig. 6 is a structural view of the reclaimed water heat exchanger of the present invention.

The specific implementation mode is as follows:

the present invention will be further described with reference to the following specific embodiments and accompanying drawings.

Referring to fig. 1-6, a small integrated water-cooled heat exchanger system for a block chain operation center is disclosed, which comprises: a box body 1; a blockchain operation center 2 including a plurality of computing devices 21 disposed within the enclosure 1; the water-cooling heat exchange device 3 comprises a soft water treatment module 31 arranged in the box body 1, a plate type heat exchange unit module 32 connected with the soft water treatment module 31 and a cooling module 33 connected with the plate type heat exchange unit module 32, wherein the cooling module 33 is arranged on the outer side of the box body 1; a first pipe 34 is arranged between the soft water treatment module 31 and the plate heat exchanger unit module 32, and a first control valve module 35 is arranged on the first pipe 34; the soft water treatment module 31 is connected with a water inlet pipeline 36; the plate heat exchanger unit module 32 comprises a plate heat exchanger 321 installed in the box body 1, a hot side inlet 322 and a hot side outlet 323 which are communicated with a first heat exchange channel inside the plate heat exchanger 321, and a cold side inlet 324 and a cold side outlet 325 which are communicated with a second heat exchange channel inside the plate heat exchanger 321, the hot side inlet 322 is connected with a first pump body 326 and then connected with a water return pipeline module 327, the hot side outlet 323 is connected with a water supply pipeline module 328, and the water return pipeline module 327 and the water supply pipeline module 328 are both connected with the computing equipment 21 so as to cool and dissipate heat of the computing equipment 21; the cold side inlet 324 and the cold side outlet 325 are both connected to the cooling module 33. The first heat exchange channel, the hot side outlet 323, the water supply pipeline module 328, the computing equipment 21, the water return pipeline module 327, the first pump body 326, the hot side inlet 322 and the first heat exchange channel inside the plate heat exchanger 321 form a closed internal circulation heat exchange path. When the utility model is used, surface water (such as river water and reservoir water) is accessed through the water inlet pipeline 36, and after the surface water enters the soft water treatment module 31, the soft water treatment module 31 carries out water softening treatment to form soft water; soft water flows into a closed internal circulation heat exchange passage formed by a first heat exchange passage inside a plate heat exchanger 321, a hot side outlet 323, a water supply pipeline module 328, the computing equipment 21, a water return pipeline module 327, a first pump body 326, a hot side inlet 322 and the first heat exchange passage in the plate heat exchanger unit module 32, and after the closed internal circulation heat exchange passage is filled with the soft water, the first pipe body 34 is controlled to be closed through the first control valve module 35, so that the closed internal circulation heat exchange passage is not filled with the soft water any more; when the soft water is not enough in the closed inner circulation heat exchange passage, the first pipe body 34 is controlled to be opened through the first control valve module 35, so that the soft water is filled in the closed inner circulation heat exchange passage again. Subsequently, the first pump 326 operates to enable the soft water in the closed internal circulation heat exchange passage to circularly flow, when the soft water flows through the computing equipment 21, the soft water can quickly take away heat generated when the computing equipment 21 operates, so as to achieve the purpose of quickly dissipating heat, and the temperature of the soft water becomes high after absorbing the heat, and the soft water flows into the first heat exchange channel inside the plate heat exchanger 321 through the water return pipeline module 327, the first pump 326 and the hot side inlet 322; meanwhile, the cold medium (e.g. cold water) in the cooling module 33 enters from the cold side inlet 324 of the plate heat exchanger 321, flows through the second heat exchange channel inside the plate heat exchanger 321, then flows out from the cold side outlet 325, and flows to the cooling module 33 again, so as to form a circulation, when the soft water with the higher temperature after absorbing heat passes through the first heat exchange channel inside the plate heat exchanger 321, the soft water exchanges heat with the cold medium flowing through the second heat exchange channel inside the plate heat exchanger 321, so that the temperature of the soft water flowing out from the hot side outlet 323 in the plate heat exchanger 321 is lowered, and the soft water with the lower temperature flows to the computing equipment 21 through the water supply pipeline module 328, so as to quickly take away the heat generated during the operation of the computing equipment 21 again, thereby achieving the purpose of quick heat dissipation, and continuous circulation, so as to quickly dissipate the heat of the whole block chain operation center, which has an ideal heat dissipation effect, and can not make the inside air drying of box, but the potential safety hazard of prevention dry air in order to catch fire to can solve because for the core of protection computer equipment, the dust content requirement of admitting air to the computer lab space is higher, the great problem of cooling blower's consumption, the order the utility model discloses extremely strong market competition has. Furthermore, the utility model discloses each module part is all integrated in a box, its compact structure to can be according to the demand shift position of use, and be convenient for transport, it is very convenient to use.

The chip, motherboard, graphics card, etc. of the computing device 21 may generate a large amount of heat during operation.

The computing device 21 may be an ore machine.

The container body 1 is a container, however, the container is an existing product, the container with a proper size is selected according to actual needs, additional die sinking manufacturing is not needed, the cost can be reduced, and the fan 11 is arranged on the outer side of the container and used for dissipating heat of the container body; the block chain operation center 2 further includes a power distribution cabinet 22 and a central control box 23 disposed in the box body 1.

The soft water treatment module 31 comprises a precision filter 311, a water softener 312 and a soft water tank 313 which are connected in sequence, when the soft water treatment module 31 works, water is firstly filtered through the precision filter 311, so that the quality of water is ensured, then the water softener 312 is adopted to soften the water, and the softened soft water is stored in the soft water tank 313. The precision filter 311 is connected to the water inlet pipe 36 after connecting the eighth stop valve 314 and the first proportional valve 315. The precision filter 311 is a bag filter.

A second pump body 316 is arranged between the softened water tank 313 and the first pipe 34, and the second pump body 316 is used for pumping the soft water in the softened water tank 313 to be injected into the closed internal circulation heat exchange passage when the soft water in the closed internal circulation heat exchange passage is insufficient, so as to fulfill the aim of water supplement. The softened water tank 313 is provided with a high-low level gauge 317, so that whether the soft water in the softened water tank 313 reaches the highest level or the lowest level can be known in real time.

The first control valve module 35 includes a first check valve 351 and a first stop valve 352 sequentially disposed on the first pipe 34, wherein the first check valve 351 is used for preventing the soft water from flowing back, and the first stop valve 352 is used for controlling the first pipe 34 to be opened or closed; a second stop valve 343 and an expansion tank 344 are connected to the first pipe body 34, and a first relief valve 341 and a first pressure sensor 342 are provided on the first pipe body 34. The expansion tank 344 is used for increasing the water pressure, so that the second pump body 316 can smoothly extract the soft water in the softened water tank 313 to inject the soft water into the closed internal circulation heat exchange passage, and the purpose of water supplement is achieved.

A second pipe 37 is further arranged between the hot-side inlet 322 and the first pump body 326, the second pipe 37 is connected to the first pipe 34, a first pressure gauge 371, a first thermometer 372, a first exhaust valve 373, a third stop valve 374, a second temperature sensor 375, a fourth stop valve 376 and a second check valve 377 are arranged on the second pipe 37, and a first filter 329 and a fifth stop valve 320 are further arranged between the first pump body 326 and the water return pipeline module 327. The first pressure gauge 371 and the first temperature gauge 372 display the pressure and the temperature of the hot side inlet 322 in real time, the second check valve 377 prevents the backflow of soft water, and the first pump body 326 enables smooth water circulation. The first exhaust valve 373 is used for exhausting and reducing pressure, and the third stop valve 374 and the fourth stop valve 376 are controlled to be on and off.

A third tube 3241 and a third pump 3242 are disposed between the cold-side inlet 324 and the cooling module 33, and a sixth stop valve 3243, a second filter 3244, a third temperature sensor 3245, a second pressure gauge 3246, a second temperature gauge 3247, and a first drain valve 3248 are further disposed on the third tube 3241. A second pressure gauge 3246, a second temperature gauge 3247 show the pressure and temperature of the cold side inlet 324 in real time, a second filter 3244 for filtration and a first waste drain valve 3248 for waste drainage. The sixth stop valve 3243 is used to control on/off.

A fourth tube 3251 is disposed between the cold-side outlet 325 and the cooling module 33, and a seventh stop valve 3252, a fourth temperature sensor 3253, a third pressure gauge 3254, a third temperature gauge 3255 and a second exhaust valve 3256 are further disposed on the fourth tube 3251. A third pressure gauge 3254 and a third temperature gauge 3255 are used for displaying the pressure and the temperature at the cold-side outlet 325 in real time, a seventh stop valve 3252 is used for controlling on-off, and a second exhaust valve 3256 is used for controlling exhaust decompression.

The water return pipeline module 327 includes a water return main pipeline 3271 and a plurality of water return branch pipelines 3272 distributed in parallel, the water return branch pipeline 3272 is provided with a plurality of first pipe interfaces 3273 and a first valve body 3274 controlling the on-off of the first pipe interfaces 3273, and the first pipe interfaces 3273 are connected with the computing device 21 through water return hoses. The water supply pipeline module 328 comprises a main water supply pipeline 3281 and a plurality of water supply branch pipelines 3282 distributed in parallel, the water supply branch pipelines 3282 are located beside the water return branch pipeline 3272 and are distributed in parallel, the water supply branch pipelines 3282 are provided with a plurality of second pipe interfaces 3283 and second valve bodies 3284 for controlling the second pipe interfaces 3283 to be switched on and off, and the second pipe interfaces 3283 are connected with the computing equipment 21 through water supply hoses; the water return pipe module 327 and the water supply pipe module 328 are arranged to save space, and the second pipe connectors 3283 of the water supply branch pipes 3282 and the first pipe connectors 3273 of the water return branch pipes 3272 are arranged in parallel in a row, so that the same computing equipment 21 can be connected at the same time, and a good heat exchange effect can be achieved.

A fifth pipeline 3280 is connected between the main water supply pipeline 3281 and the hot side outlet 323, a fourth pressure gauge 3285, a fourth thermometer 3286, a ninth stop valve 3287 and a fifth temperature sensor 3288 are arranged on the fifth pipeline 3280, and a drain valve 3289 is further arranged on the fifth pipeline 3280.

The cooling module 33 is one of a cooling tower or an air cooling mechanism, and can be matched with the cooling tower or the air cooling mechanism according to actual requirements to meet different use requirements.

To sum up, when the utility model is used, surface water is connected through the water inlet pipe 36, and after the surface water enters the soft water treatment module 31, the soft water treatment module 31 carries out water softening treatment to form soft water; soft water flows into a closed internal circulation heat exchange passage formed by a first heat exchange passage inside a plate heat exchanger 321, a hot side outlet 323, a water supply pipeline module 328, the computing equipment 21, a water return pipeline module 327, a first pump body 326, a hot side inlet 322 and the first heat exchange passage in the plate heat exchanger unit module 32, and after the closed internal circulation heat exchange passage is filled with the soft water, the first pipe body 34 is controlled to be closed through the first control valve module 35, so that the closed internal circulation heat exchange passage is not filled with the soft water any more; when the soft water is not enough in the closed inner loop heat exchange path, the first pipe body 34 is controlled to be opened through the first control valve module 35, so that the soft water is filled in the closed inner loop heat exchange path again. Subsequently, the first pump 326 operates to enable the soft water in the closed internal circulation heat exchange passage to circularly flow, when the soft water flows through the computing equipment 21, the soft water can quickly take away heat generated when the computing equipment 21 operates, so as to achieve the purpose of quickly dissipating heat, and the temperature of the soft water becomes high after absorbing the heat, and the soft water flows into the first heat exchange channel inside the plate heat exchanger 321 through the water return pipeline module 327, the first pump 326 and the hot side inlet 322; meanwhile, the cold medium in the cooling module 33 enters from the cold side inlet 324 of the plate heat exchanger 321, flows through the second heat exchange channel inside the plate heat exchanger 321, flows out from the cold side outlet 325, and flows to the cooling module 33 again, so as to form a cycle, when the soft water with the higher temperature after absorbing heat passes through the first heat exchange channel inside the plate heat exchanger 321, the soft water exchanges heat with the cold medium flowing through the second heat exchange channel inside the plate heat exchanger 321, so that the temperature of the soft water flowing out from the hot side outlet 323 in the plate heat exchanger 321 is lowered, and the soft water with the lowered temperature flows to the computing equipment 21 through the water supply pipe module 328, so that the heat generated during the operation of the computing equipment 21 can be taken away quickly again, thereby achieving the purpose of quick heat dissipation, and continuously circulating, so as to quickly dissipate the heat of the whole block chain operation center, which has an ideal heat dissipation effect, and can not make the inside air drying of box, but the potential safety hazard of prevention dry air in order to catch fire to can solve because for the core of protection computer equipment, the dust content requirement of admitting air to the computer lab space is higher, the great problem of cooling blower's consumption, the order the utility model discloses extremely strong market competition has. Furthermore, the utility model discloses each module part is all integrated in a box, its compact structure to can be according to the demand shift position of use, and be convenient for transport, it is very convenient to use.

Of course, the above description is only an exemplary embodiment of the present invention, and not intended to limit the scope of the present invention, and all equivalent changes and modifications made by the constructions, features, and principles of the present invention in accordance with the claims of the present invention are intended to be included in the scope of the present invention.

Claims (10)

1. A small-size integrated form water-cooling heat exchanger system for block chain operation center, its characterized in that: it includes:

a box body (1);

a block chain computation center (2) comprising a plurality of computing devices (21) arranged within the box (1);

the water-cooling heat exchange device (3) comprises a soft water treatment module (31) arranged in the box body (1), a plate type heat exchange unit module (32) connected with the soft water treatment module (31) and a cooling module (33) connected with the plate type heat exchange unit module (32), and the cooling module (33) is arranged on the outer side of the box body (1); a first pipe body (34) is arranged between the soft water treatment module (31) and the plate type heat exchanger unit module (32), and a first control valve module (35) is arranged on the first pipe body (34); the soft water treatment module (31) is connected with a water inlet pipeline (36);

the plate heat exchanger unit module (32) comprises a plate heat exchanger (321) arranged in the box body (1), a hot side inlet (322) and a hot side outlet (323) which are communicated with a first heat exchange channel in the plate heat exchanger (321), and a cold side inlet (324) and a cold side outlet (325) which are communicated with a second heat exchange channel in the plate heat exchanger (321), wherein the hot side inlet (322) is connected with a first pump body (326) and then connected with a water return pipeline module (327), the hot side outlet (323) is connected with a water supply pipeline module (328), and the water return pipeline module (327) and the water supply pipeline module (328) are both connected with the computing equipment (21) so as to cool and radiate the computing equipment (21); the cold-side inlet (324) and the cold-side outlet (325) are both connected to the cooling module (33).

2. A compact integrated water-cooled heat exchanger system for use in a blockchain operation center as claimed in claim 1 wherein: the box body (1) is a container, and a fan (11) is arranged on the outer side of the container; the block chain operation center (2) further comprises a power distribution cabinet (22) and a central control box (23) which are arranged in the box body (1).

3. A compact integrated water-cooled heat exchanger system for use in a blockchain operation center as claimed in claim 1 wherein: the soft water treatment module (31) comprises a precision filter (311), a water softener (312) and a softening water tank (313) which are sequentially connected, and the precision filter (311) is connected with the water inlet pipeline (36) after being connected with an eighth stop valve (314) and a first proportional valve (315); a second pump body (316) is arranged between the softened water tank (313) and the first pipe body (34), and a high-low water level meter (317) is arranged on the softened water tank (313).

4. A compact integrated water-cooled heat exchanger system for use in a blockchain operation center as claimed in claim 1 wherein: the first control valve module (35) comprises a first check valve (351) and a first stop valve (352) which are sequentially arranged on a first pipe body (34), the first pipe body (34) is further connected with a second stop valve (343) and an expansion tank (344), and the first pipe body (34) is further provided with a first safety valve (341) and a first pressure sensor (342).

5. A small integrated water-cooled heat exchanger system for block chain operation centers as claimed in any one of claims 1 to 4, wherein: still be provided with second body (37) between the hot side import (322) and the first pump body (326), this second body (37) is connected first body (34), be provided with first manometer (371), first thermometer (372), first exhaust valve (373), third stop valve (374), second temperature sensor (375), fourth stop valve (376), second check valve (377) on this second body (37), still be provided with first filter (329), fifth stop valve (320) between this first pump body (326) and return water pipe module (327).

6. A small integrated water-cooled heat exchanger system for block chain operation centers as claimed in any one of claims 1 to 4, wherein: a third pipe body (3241) and a third pump body (3242) are arranged between the cold side inlet (324) and the cooling module (33), and a sixth stop valve (3243), a second filter (3244), a third temperature sensor (3245), a second pressure gauge (3246), a second temperature gauge (3247) and a first drain valve (3248) are further arranged on the third pipe body (3241).

7. A small integrated water-cooled heat exchanger system for block chain operation centers as claimed in claim 6, wherein: a fourth pipe body (3251) is arranged between the cold side outlet (325) and the cooling module (33), and a seventh stop valve (3252), a fourth temperature sensor (3253), a third pressure gauge (3254), a third thermometer (3255) and a second exhaust valve (3256) are further arranged on the fourth pipe body (3251).

8. A small integrated water-cooled heat exchanger system for block chain operation centers as claimed in any one of claims 1 to 4, wherein: the water return pipeline module (327) comprises a water return main pipeline (3271) and a plurality of water return branch pipelines (3272) distributed in parallel, the water return branch pipelines (3272) are provided with a plurality of first pipe connectors (3273) and first valve bodies (3274) for controlling the connection and disconnection of the first pipe connectors (3273), and the first pipe connectors (3273) are connected with the computing equipment (21) through water return hoses.

9. A compact integrated water-cooled heat exchanger system for use in a blockchain operations center as claimed in claim 8 wherein: the water supply pipeline module (328) comprises a main water supply pipeline (3281) and a plurality of water supply branch pipelines (3282) distributed in parallel, the water supply branch pipelines (3282) are positioned beside the water return branch pipeline (3272) and distributed in parallel, the water supply branch pipelines (3282) are provided with a plurality of second pipe interfaces (3283) and a second valve body (3284) for controlling the second pipe interfaces (3283) to be switched on and off, and the second pipe interfaces (3283) are connected with the computing equipment (21) through water supply hoses; a fifth pipeline (3280) is connected between the main water supply pipeline (3281) and the hot side outlet (323), a fourth pressure gauge (3285), a fourth thermometer (3286), a ninth stop valve (3287) and a fifth temperature sensor (3288) are arranged on the fifth pipeline (3280), and a drain valve (3289) is further arranged on the fifth pipeline (3280).

10. A small integrated water-cooled heat exchanger system for block chain operation centers as claimed in claim 5, wherein: the cooling module (33) is one of a cooling tower or an air cooling mechanism.

Images