CN111124087A - CPU water-cooling power device - Google Patents

Abstract

The invention provides a CPU water-cooling power device, comprising: the cooling device comprises a water tank, wherein a cooling pipe arranged in a curve is arranged above the water tank; the cooling pipe is sequentially provided with three pipelines which are arranged in the vertical direction, namely a power pipe, a middle pipe and an output pipe, a guide column is arranged at one end of the cooling pipe, which is connected with the water tank, and a transmission shaft is arranged in the vertical direction of the cooling pipe; the fan is mounted on the transmission shaft in the center; the transmission shaft is provided with a transmission wheel in the power pipe, and the transmission wheel is provided with a plurality of transmission blades; the invention utilizes the principles of water fluidity and steam volatility to enable cooling water to be continuously recycled, the fan rotates to form a cooling mode combining water cooling and air cooling, the fan does not need to additionally provide electric energy, the energy consumption is effectively reduced, the heat generated by the central processing unit is fully utilized, the energy is effectively released and utilized, and the consumption of the electric energy when the host machine operates is reduced.

Description

CPU water-cooling power device

Technical Field

The invention relates to the technical field of computer hardware, in particular to a CPU water-cooling power device.

Background

The CPU is a central processing unit, which is a highly integrated core operation element, the central processing unit is the heart in the field of computers, when the computer is in an operation state, the central processing unit can operate at high speed, a large amount of heat can be generated by the operation, most computers have the temperature monitoring function of the central processing unit at present, the temperature of the central processing unit is monitored so that the computer is in a normal operation state, the operation speed of the computer is reduced when the temperature of the central processing unit is overhigh, the computer is completely stopped and shut down seriously, the service life of the central processing unit is also influenced seriously by overhigh temperature, the service life is inevitably reduced when the computer is in high-temperature load for a long time, and the material and the external cooling mode of the central processing unit are further improved all the time in order to reduce the temperature of the central processing unit in operation.

At present, in most computers which normally run, the material of a central processing unit can meet the requirement of normal running, but with the continuous progress of the technology, software which needs to be processed by the central processing unit is larger and more complex, especially facing an intelligent multi-time unlimited processing mode, the load of the central processing unit is continuously increased, the flowing of air is accelerated in a single-fan mode in a case, so that heat generated by the central processing unit is dissipated as soon as possible, and the problem of heat rising in the case is solved better by a gradual multi-fan heat dissipation mode which generates double fans in the new case, but the effect is not obvious, and the air cooling can only solve part of the problems; in order to further increase the cooling speed, there is also a central processing unit that cools down by means of circulating water, but the current circulating water treatment method has a complex structure, which increases the weight of the case, and also needs to pay attention to that water cannot overflow, and the requirement for the complex operating environment of the case becomes high, therefore, the method cannot be widely applied.

Therefore, how to improve the heat dissipation mode of the central processing unit, so that the central processing unit can rapidly transmit heat during operation and release the heat in a cooling mode, the kinetic energy released by the heat can be utilized, and the technical problem which needs to be solved by the invention is that water can be injected once and the power source generated by the heat can be effectively utilized to reduce energy consumption for a long time.

Disclosure of Invention

The present invention aims to provide a CPU water cooling power plant that overcomes or at least partially solves the above mentioned problems, to solve the problem that air cooling and water cooling cannot be effectively combined.

In order to achieve the purpose, the technical scheme of the invention is realized as follows:

the invention provides a CPU water-cooling power device, which comprises a chassis board, wherein a main board is arranged on the chassis board, the main board is fixedly arranged through a screw, a CPU is fixedly arranged on the main board, and the CPU water-cooling power device also comprises:

the water tank is provided with an inner plate with the same size as the CPU in the vertical direction, the water tank is arranged on a chassis plate through a support frame, and a cooling pipe arranged in a curve is arranged above the water tank;

the cooling pipe is sequentially provided with three pipelines which are arranged in the vertical direction, namely a power pipe, a middle pipe and an output pipe, the power pipe is connected with the top of the middle pipe through a bent pipe, the middle pipe is connected with the lower end of the output pipe through the bent pipe, a guide column is arranged at one end, connected with the water tank, of the cooling pipe, and a transmission shaft is arranged in the vertical direction of the cooling pipe;

the fan is arranged on the transmission shaft in the center and is arranged outside the cooling pipe;

the cooling device comprises a cooling pipe, a transmission shaft, a fan and a cooling fan, wherein the transmission shaft is arranged in the power pipe and is provided with a plurality of transmission blades;

the guide post, the guide post divide into slant and straight to two parts, and straight to being the cylinder structure, the slant part includes batter post and straight post, and straight post and straight to the part on same straight line, batter post slant straight post direction, the batter post is provided with the nozzle with the top of straight post, the inner wall of nozzle one side and the inner wall coincidence of straight post, the circular one side of being partial to the power tube centre of a circle of nozzle.

As a further aspect of the present invention, the inner plate is made of metal, and the port plug is made of a material that is air-permeable and water-impermeable.

As a further aspect of the invention, the diameter of the nozzle is one quarter to one tenth of the diameter of the guide post.

As a further scheme of the invention, the upper end of the inner plate is connected with an inclined plate, the inclined plate inclines outwards, the other end of the inclined plate is connected with a top platform, the top platform is horizontally arranged, and the top platform is provided with a through hole for communicating the inside of the water tank with the cooling pipe.

As a further scheme of the invention, a transmission port is formed in the power pipe and used for mounting a transmission shaft, the transmission port is used for mounting a first transmission wheel, a port plug is mounted at the end point of the output pipe, a return pipe is arranged at the bottommost end of the bent pipe between the intermediate pipe and the output pipe and connected to the inclined plate, and the intermediate pipe and the output pipe are communicated with the interior of the water tank through the return pipe.

As a further scheme of the invention, the fan ring array is provided with a plurality of fan blades, the periphery of each fan blade is provided with a fan ring, the fan rings and the fan blades are installed in a staggered mode, the fan rings are fixedly installed on the supporting frame through the fan support, and the fan rings are installed on the transmission shaft through the bearings.

As a further scheme of the invention, a rectangular frame is arranged outside the transmission port and used for mounting the first transmission wheel, and a horizontally arranged cylindrical structure is arranged inside the rectangular frame.

According to a further scheme of the invention, the transmission shaft is provided with a plurality of first transmission blades in an axial array, one side of each first transmission blade is fixedly arranged on the first transmission, the first transmission blades are connected with the transmission shaft through keys, two ends of each first transmission blade are provided with bearings, the bearings are embedded and arranged on the rectangular frame, each first transmission blade is of a plate-shaped structure, and the length and the width of each first transmission blade are smaller than the inner size of the rectangular frame.

As a further scheme of the invention, the transmission ports are two through holes arranged on the wall of the power pipe, the transmission shaft penetrates through the two transmission ports to be installed, and the two transmission ports are respectively installed in a matched manner with the two bearings.

As a further scheme of the invention, a plurality of second transmission blades are arranged on the transmission shaft in an axial array, one side of each second transmission blade is fixedly arranged on a second transmission wheel, the second transmission wheels are connected with the transmission shaft through keys, bearings are arranged at two ends of each second transmission wheel, the bearings are embedded and arranged on the wall of the power pipe, each second transmission blade is of an arc-shaped structure, the radian of each second transmission blade is smaller than the radius of the power pipe, and two ends of each second transmission wheel are of spherical arc-shaped structures matched with the inner wall of the power pipe.

The invention provides a CPU water-cooling power device, which has the beneficial effects that: the invention utilizes the principles of water fluidity and steam volatility, heat generated by a central processing unit rapidly enters a water tank to contact with water through conduction of heat conducting metal, cooling water absorbs the heat and is transferred in the water tank, the heated cooling water rises through a space below a top platform and enters a cooling pipe, the bent structure of the cooling pipe increases the flow length of the water vapor, so that more water vapor can be adsorbed on the inner wall of the cooling pipe and condensed into water beads, the water beads on one hand flow back into the water tank through the lower part of a power pipe, on the other hand flow to the bottom through an intermediate pipe and an output pipe and flow into the water tank through a return pipe, so that the cooling water is continuously recycled, a port plug arranged at a port of the output pipe can flow air, thereby guiding the flow direction of the water vapor, and when the water tank is placed down, the port plug can also prevent the cooling water from overflowing, the inside components and parts of protection machine case can not damaged, and the power that vapor produced makes it have the power when being greater than the evaporation through accelerating of nozzle to the rotation of drive transmission shaft finally makes the fan rotate, forms the cooling mode that water-cooling and forced air cooling combine, and the fan does not need extra electric energy that provides, effectual reduction energy consumption, and the heat that make full use of central processing unit produced, makes the energy obtain effectual release and utilization, reduces the consumption of host computer during operation electric energy.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings based on the drawings without creative efforts.

Fig. 1 is a schematic view of a three-dimensional structure sequentially installed inside a chassis according to an embodiment of the present invention.

Fig. 2 is a schematic side view of a sequential mounting inside a chassis according to an embodiment of the present invention.

Fig. 3 is a schematic structural diagram of an internal sequential mounting front surface according to an embodiment of the present invention.

Fig. 4 is a schematic view of an installation structure of a cooling pipe and a water tank according to an embodiment of the present invention.

Fig. 5 is a schematic internal cross-sectional structure diagram of a power tube according to an embodiment of the present invention.

Fig. 6 is a schematic view of a transmission shaft mounting structure provided in the embodiment of the present invention.

Fig. 7 is a schematic axial structure diagram of a guide post according to an embodiment of the present invention.

Fig. 8 is a schematic structural view of a second transmission wheel provided in embodiment 2 of the present invention.

In the figure: 1. a chassis board; 11. a main board; 12. a CPU; 2. a water tank; 21. a support frame; 211. a long screw; 22. an inner plate; 23. a sloping plate; 24. a top platform; 3. a cooling tube; 31. a power tube; 311. a transmission port; 32. an intermediate pipe; 33. an output pipe; 34. a port plug; 35. a return pipe; 36. a rectangular frame; 4. a fan; 41. a fan bracket; 42. a fan blade; 5. a drive shaft; 51. a first drive pulley; 52. a first drive vane; 53. a bearing; 6. a guide post; 61. an oblique column; 62. a straight column; 63. a nozzle; 7. a second transmission wheel; 71. a second driving blade.

Detailed Description

Exemplary embodiments of the present disclosure will be described in more detail below with reference to the accompanying drawings. While exemplary embodiments of the present disclosure are shown in the drawings, it should be understood that the present disclosure may be embodied in various forms and should not be limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art.

Example 1

Referring to fig. 1 to 7, a CPU water-cooling power device provided by an embodiment of the present invention includes a chassis board 1, a main board 11 is mounted on the chassis board 1, the main board 11 is fixedly mounted by screws, a CPU12 is fixedly mounted on the main board 11, a water tank 2 is mounted on an outer side of a CPU12 in an attached manner, cooling water is contained in the water tank 2, the water tank 2 is regular in shape, a side of the water tank 2 contacting with a CPU12 has a size same as that of the CPU12, another side of the water tank 2 has a size larger than that of the water tank 2 contacting with the CPU12, the water tank 2 is mounted on the chassis board 1 by a support frame 21, a cooling pipe 3 arranged in a curve manner is mounted above the water tank 2, a port plug 34 is disposed at another end of the cooling pipe 3, the port plug 34 is made of a material which is air-permeable and water-impermeable, a guide column 6 is disposed at one end of the cooling pipe 3 connected, a transmission shaft 5 is provided in the vertical direction of the cooling pipe 3, a first transmission wheel 51 is provided in the transmission shaft 5 inside the cooling pipe 3, and a fan 4 is attached to the transmission shaft 5 outside the cooling pipe 3. The heat generated by the operation of the CPU12 is transmitted to the heat-conducting inner plate 22, the inner surface of the inner plate 22 is contacted with cooling water, the evaporation of the cooling water is accelerated, the evaporation speed of the cooling water is related to the heat generation quantity of the CPU12, when the heat generation quantity of the CPU12 is continuously increased, a large amount of water vapor can be used as a power source to drive the fan 4 to rotate, the rotation of the fan 4 accelerates the air circulation inside the case, and therefore the heat dissipation efficiency inside the case is improved when the heat is large.

As shown in fig. 1-3, the water tank 2 is provided with an inner plate 22 having the same size as the CPU in the vertical direction, the inner plate 22 is made of copper, the upper end of the inner plate 22 is connected with an inclined plate 23, the inclined plate 23 inclines outwards, the other end of the inclined plate 23 is connected with a top platform 24, the top platform 24 is horizontally arranged, the top platform 24 is provided with a through opening for communicating the inside of the water tank 2 with the cooling pipe 3, and the cooling pipe 3 is connected and sealed with the water tank 2 through glue. The cooling water in the water tank 2 is higher than the CPU12 at high speed, and the upper part of the water tank is provided with a part of space for evaporating water flow of water vapor and water drops to form circulating water, and frequent water injection is not needed.

As shown in fig. 3-5, the cooling pipe 3 is sequentially provided with three vertically arranged pipes, namely a power pipe 31, an intermediate pipe 32 and an output pipe 33, the top of the power pipe 31 is connected with the top of the intermediate pipe 32 through a bent pipe, the lower end of the intermediate pipe 32 is connected with the lower end of the output pipe 33 through a bent pipe, the power pipe 31 is provided with a transmission port 311, the transmission port 311 is used for installing the transmission shaft 5, the exterior of the transmission port 311 is provided with a rectangular frame 36, the rectangular frame 36 is used for installing a first transmission wheel 51, the end point of the output pipe 33 is provided with an end plug 34, the bottom end of the bent pipe between the intermediate pipe 32 and the output pipe 33 is provided with a return pipe 35, the return pipe 35 is connected to the inclined plate 23, and the. The port plug 34 can be a treated non-woven fabric, the port plug 34 seals the output pipe 33 without water leakage, and the port plug 34 can still be air-permeable, so that when water vapor is generated, a large pressure is generated in the cooling pipe 3, and the water vapor is adsorbed on the pipe wall through the circulation of air, and finally forms water drops to flow back into the water tank 2 for recycling.

As shown in fig. 5 and 6, the fan 4 is centrally mounted on the transmission shaft 5, a plurality of fan blades 42 are arranged in an annular array on the fan 4, a fan ring is arranged on the periphery of the fan blades 42, the fan ring and the fan blades 42 are installed in a staggered manner, the fan ring is fixedly mounted on the support frame 21 through a fan support 41, and the fan ring is mounted on the transmission shaft 5 through a bearing.

As shown in fig. 6, the plurality of first driving blades 52 are arranged in an axial array on the driving shaft 5, one side of each first driving blade 52 is fixedly installed on the first driving wheel 51, the first driving wheel 51 is connected with the driving shaft 5 through a key, bearings 53 are installed at two ends of each first driving wheel 51, the bearings 53 are installed on the rectangular frame 36 in an embedded mode, each first driving blade 52 is of a plate-shaped structure, the length and the width of each first driving blade 52 are smaller than the inner size of the rectangular frame 36, a cylindrical structure is horizontally arranged inside the rectangular frame 36, and the first driving blades 52 provide rotating power through rising of water vapor so as to drive the fan 4 to rotate.

As shown in fig. 5 and 7, the guide post 6 is disposed at a middle position below the first driving blade 52, the guide post 6 is divided into an oblique portion and a straight portion, the straight portion has a cylindrical structure, the oblique portion includes an oblique post 61 and a straight post 62, the straight post 62 is collinear with the straight portion, the oblique post 61 is oblique to the direction of the straight post 62, the top ends of the oblique post 61 and the straight post 62 are provided with a nozzle 63, the diameter of the nozzle 63 is one fourth of the diameter of the guide post 6, the inner wall of one side of the nozzle 63 coincides with the inner wall of the straight post 62, and the circle of the nozzle 63 is deviated to one side of the center of the power pipe 31. The size of the nozzle 63 is such that the steam generates a pressurizing force during the rising process, and the steam sprayed from the nozzle 63 can accelerate the rotation speed of the first driving blade 52, thereby increasing the rotation speed of the driving shaft 5.

Example 2

Embodiment 2 differs from embodiment 1 in the structure of the power transmission.

Referring to fig. 1 to 8, a CPU water-cooling power device provided by an embodiment of the present invention includes a chassis board 1, a motherboard 11 is installed on the chassis board 1, the motherboard 11 is fixedly installed by screws, a CPU is fixedly installed on the motherboard 11, a water tank 2 is installed on the outer side of the CPU in an attached manner, cooling water is contained in the water tank 2, the water tank 2 is regular in shape, the size of the side of the water tank 2 contacting the CPU is the same as the size of the CPU, the size of the other side of the water tank 2 is larger than the side of the water tank 2 contacting the CPU, the water tank 2 is installed on the chassis board 1 by a support frame 21, a cooling pipe 3 arranged in a curved manner is installed above the water tank 2, a port plug 34 is installed at the other end of the cooling pipe 3, the port plug 34 is made of a material that is air-permeable and water-impermeable, a guide column 6 is installed at the end of the cooling pipe, a transmission shaft 5 is provided in the vertical direction of the cooling pipe 3, a first transmission wheel 51 is provided in the transmission shaft 5 inside the cooling pipe 3, and a fan 4 is attached to the transmission shaft 5 outside the cooling pipe 3. The heat generated by the operation of the CPU12 is transmitted to the heat-conducting inner plate 22, the inner surface of the inner plate 22 is contacted with cooling water, the evaporation of the cooling water is accelerated, the evaporation speed of the cooling water is related to the heat generation quantity of the CPU12, when the heat generation quantity of the CPU12 is continuously increased, a large amount of water vapor can be used as a power source to drive the fan 4 to rotate, the rotation of the fan 4 accelerates the air circulation inside the case, and therefore the heat dissipation efficiency inside the case is improved when the heat is large.

As shown in fig. 1-3, the water tank 2 is provided with an inner plate 22 having the same size as the CPU12 in the vertical direction, the inner plate 22 is made of aluminum, the upper end of the inner plate 22 is connected with an inclined plate 23, the inclined plate 23 inclines outwards, the other end of the inclined plate 23 is connected with the top platform 24, the top platform 24 is horizontally arranged, the top platform 24 is provided with a through opening for communicating the inside of the water tank 2 with the cooling pipe 3, and the cooling pipe 3 is connected and sealed with the water tank 2 through glue. The cooling water in the water tank 2 is higher than the CPU12 at high speed, and the upper part of the water tank is provided with a part of space for evaporating water flow of water vapor and water drops to form circulating water, and frequent water injection is not needed.

As shown in fig. 3 to 5, the cooling pipe 3 is provided with a power pipe 31 in sequence, the power pipe 31 is connected with the top of the middle pipe 32 through a bent pipe, the middle pipe 32 is connected with the lower end of the output pipe 33 through a bent pipe, the power pipe 31 is provided with a transmission port 311, the transmission port 311 is used for installing a transmission shaft 5, the transmission port 311 is two through holes formed in the pipe wall of the power pipe 31, the transmission shaft 5 penetrates through the two transmission ports 311 to be installed, the two transmission ports 311 are respectively installed in a matched mode with two bearings 53, the transmission port 311 is used for installing a second transmission wheel 7, a port plug 34 is installed at the end point of the output pipe 33, a return pipe 35 is arranged at the bottommost end of the bent pipe between the middle pipe 32 and the output pipe 33, the return pipe 35 is connected to the inclined plate 23, and the return pipe 35 is used for communicating the middle pipe 32 and the output pipe 33 with the interior. The port plug 34 can be a treated non-woven fabric, the port plug 34 seals the output pipe 33 without water leakage, and the port plug 34 can still be air-permeable, so that when water vapor is generated, a large pressure is generated in the cooling pipe 3, and the water vapor is adsorbed on the pipe wall through the circulation of air, and finally forms water drops to flow back into the water tank 2 for recycling.

As shown in fig. 5 and 6, the fan 4 is centrally mounted on the transmission shaft 5, a plurality of fan blades 42 are arranged in an annular array on the fan 4, a fan ring is arranged on the periphery of the fan blades 42, the fan ring and the fan blades 42 are installed in a staggered manner, the fan ring is fixedly mounted on the support frame 21 through a fan support 41, and the fan ring is mounted on the transmission shaft 5 through a bearing.

As shown in fig. 6 and 8, a plurality of second transmission blades 71 are arranged in an axial array on the transmission shaft 5, one side of each second transmission blade 71 is fixedly installed on a second transmission wheel 7, the second transmission wheel 7 is in key connection with the transmission shaft 5, bearings 53 are installed at two ends of each second transmission wheel 7, the bearings 53 are installed on the wall of the power pipe 31 in an embedded mode, each second transmission blade 71 is of an arc-shaped structure, the radian of each second transmission blade 71 is smaller than the radius of the power pipe 31, two ends of each second transmission wheel 7 are of spherical arc-shaped structures matched with the inner wall of the power pipe 31, and the second transmission blades 71 provide rotating power through the rising of water vapor, so that the fan 4 is driven to rotate.

As shown in fig. 5 and 7, the guide post 6 is disposed at the middle position below the second transmission blade 71, the guide post 6 is divided into an oblique portion and a straight portion, the straight portion is a cylindrical structure, the oblique portion includes an oblique post 61 and a straight post 62, the straight post 62 and the straight portion are on the same straight line, the oblique post 61 is oblique to the straight post 62, the top ends of the oblique post 61 and the straight post 62 are provided with a nozzle 63, the diameter of the nozzle 63 is one tenth of the diameter of the guide post 6, the inner wall of one side of the nozzle 63 coincides with the inner wall of the straight post 62, and the circle of the nozzle 63 deflects towards one side of the center of the power tube 31. The size of the nozzle 63 is such that the steam generates a pressurizing force during the rising process, and the steam sprayed from the nozzle 63 can accelerate the rotation speed of the first driving blade 52, thereby increasing the rotation speed of the driving shaft 5.

The working principle of the CPU water-cooling power device is as follows: the water cooling is a cooling mode superior to the air cooling, the difficulty of the water cooling lies in that uncertain factors of water and the flowing-out of the water cause equipment short circuit so as to increase the risk of burning, but the defect can be completely avoided by increasing the tightness of the water cooling, the application utilizes the characteristics of evaporation and condensation of the water to enable the water cooling to form circulation, thereby achieving the effect of once water injection and long-term cooling, a CPU is a high-heat-dissipation component in operation, the CPU can be burnt out when the temperature exceeds a certain temperature so as to cause the stop operation of calculation, the overhigh temperature of the CPU can also cause the reduction of the operation speed, the peak temperature of the CPU is close to the boiling point of the water, namely the water can bear the evaporation caused by the heat generated by the CPU and can not be always in a boiling state, the heat generated by the CPU is transferred through metals with different heat conduction coefficients, the cooling water in a water tank is evaporated, and the evaporated cooling water can also become, thereby the operation of drive fan carries out the secondary cooling to CPU, what utilize this moment is water cooling and forced air cooling's combination to the forced air cooling need not consume power, also need not design circuit and control plate in addition, effectual energy saving and to CPU cool down, the water level in the water tank should cover whole central processing unit's surface during the use.

The above are merely examples of the present application and are not intended to limit the present application. Various modifications and changes may occur to those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present application should be included in the scope of the claims of the present application.

Claims (10)

1. The utility model provides a CPU water-cooling power device, includes quick-witted boxboard (1), install mainboard (11) on quick-witted boxboard (1), mainboard (11) are through screw fixed mounting, and fixed mounting has CPU (12) on mainboard (11), and its characterized in that still includes:

the water tank (2) is provided with an inner plate (22) which has the same size as the CPU (12) in the vertical direction, the water tank (2) is arranged on the chassis plate (1) through a support frame (21), and a cooling pipe (3) which is arranged in a curve manner is arranged above the water tank (2);

the cooling device comprises a cooling pipe (3), wherein the cooling pipe (3) is sequentially provided with a power pipe (31), a middle pipe (32) and an output pipe (33) which are arranged in three vertical directions, the top of the power pipe (31) is connected with the top of the middle pipe (32) through a bent pipe, the lower end of the middle pipe (32) is connected with the lower end of the output pipe (33) through the bent pipe, a guide column (6) is arranged at one end, connected with a water tank (2), of the cooling pipe (3), and a transmission shaft (5) is arranged in the vertical direction of the cooling pipe (3);

the center of the fan (4) is arranged on the transmission shaft (5), and the fan (4) is arranged outside the cooling pipe (3);

the cooling device comprises a transmission shaft (5), wherein a transmission wheel is arranged in a power pipe (31) of the transmission shaft (5), a plurality of transmission blades are arranged on the transmission wheel, bearings (53) are arranged on two sides of the transmission wheel, the bearings (53) are fixed on a cooling pipe (3), and a fan (4) is arranged at the other end of the transmission shaft (5);

guide post (6), guide post (6) divide into slant and straight two parts, and straight is the cylinder structure, and the slant part includes batter post (61) and upright (62), and upright (62) are on same straight line with straight part, batter post (61) slant upright (62) direction, and batter post (61) and the top of upright (62) are provided with nozzle (63), the inner wall of nozzle (63) one side and the coincidence of the inner wall of upright (62), the circular one side of partial towards power pipe (31) the centre of a circle of nozzle (63).

2. The CPU water-cooling power device as recited in claim 1, wherein the inner plate (22) is made of metal, and the port plug (34) is made of air-permeable and water-impermeable material.

3. The CPU water-cooled power plant according to claim 2, characterized in that the diameter of the nozzle (63) is one quarter to one tenth of the diameter of the guide post (6).

4. The CPU water-cooling power device according to claim 3, characterized in that an inclined plate (23) is connected to the upper end of the inner plate (22), the inclined plate (23) is inclined outwards, the other end of the inclined plate (23) is connected with a top platform (24), the top platform (24) is horizontally arranged, and a through hole for communicating the inside of the water tank (2) with the cooling pipe (3) is arranged on the top platform (24).

5. The CPU water-cooling power device according to claim 4, wherein a transmission port (311) is arranged on the power pipe (31), the transmission port (311) is used for installing the transmission shaft (5), the transmission port (311) is used for installing the first transmission wheel (51), a port plug (34) is installed on the end point of the output pipe (33), a return pipe (35) is arranged at the bottom end of the elbow pipe between the middle pipe (32) and the output pipe (33), the return pipe (35) is connected to the inclined plate (23), and the return pipe (35) connects the middle pipe (32) and the output pipe (33) with the inside of the water tank (2).

6. The CPU water-cooling power device according to claim 5, characterized in that the fan (4) is provided with a plurality of fan blades (42) in an annular array, a fan ring is arranged on the periphery of each fan blade (42), the fan ring and the fan blades (42) are installed in a staggered mode, the fan ring is fixedly installed on the supporting frame (21) through a fan bracket (41), and the fan ring is installed on the transmission shaft (5) through a bearing.

7. The CPU water-cooling power device as claimed in claim 6, wherein a rectangular frame (36) is arranged outside the transmission port (311), the rectangular frame (36) is used for installing the first transmission wheel (51), and a horizontally arranged cylindrical structure is arranged inside the rectangular frame (36).

8. The CPU water-cooling power device according to claim 7, wherein a plurality of first driving blades (52) are arranged in an axial array on the driving shaft (5), one side of each first driving blade (52) is fixedly installed on a first driving wheel (51), the first driving wheel (51) is connected with the driving shaft (5) through a key, bearings (53) are installed at two ends of each first driving wheel (51), the bearings (53) are installed on the rectangular frame (36) in an embedded mode, the first driving blades (52) are of a plate-shaped structure, and the length and the width of each first driving blade (52) are smaller than the inner size of the rectangular frame (36).

9. The CPU water-cooling power device according to claim 6, wherein the transmission ports (311) are two through holes arranged on the pipe wall of the power pipe (31), the transmission shaft (5) is installed through the two transmission ports (311), and the two transmission ports (311) are respectively installed in a matching way with the two bearings (53).

10. The CPU water-cooling power device according to claim 9, wherein a plurality of second driving blades (71) are arranged in an axial array on the driving shaft (5), one side of each second driving blade (71) is fixedly installed on the second driving wheel (7), the second driving wheel (7) is in key connection with the driving shaft (5), bearings (53) are installed at two ends of the second driving wheel (7), the bearings (53) are installed on the pipe wall of the power pipe (31) in an embedded mode, the second driving blades (71) are of arc structures, the radian of each second driving blade (71) is smaller than the radius of the power pipe (31), and two ends of each second driving wheel (7) are of spherical arc structures matched with the inner wall of the power pipe (31).

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