CN118981233A - A big data server terminal - Google Patents

Abstract

The present invention discloses a big data server terminal, comprising a base, a heat dissipation shell fixedly connected to the upper end of the base, a mounting cavity provided in the heat dissipation shell, a terminal body installed inside the mounting cavity, and a thermal insulation oil filled inside the mounting cavity; a liquid circulation mechanism, the liquid circulation mechanism comprising a mounting groove provided at the bottom of the mounting cavity, a horizontal mounting frame installed in the mounting groove, a rotating shaft running through the horizontal mounting frame, the rotating shaft being rotatably connected to the horizontal mounting frame, a plurality of axial flow fan blades fixedly connected at equal intervals on the outer side of the rotating shaft, and the inner bottom space of the mounting groove being connected to the top of the mounting cavity through a drain pipe. When the server terminal is in use, the circulating flow of thermal insulation oil is used in conjunction with the heat dissipation part to dissipate heat, and on the basis of ensuring a good heat dissipation effect, external dust or humid air is prevented from entering the server.

Description

Big data server terminal

Technical Field

The invention relates to the field of servers, in particular to a big data server terminal.

Background

A server, also called a server, is a device that provides computing services. Because the server needs to respond to the service request and process, the server generally has the capability of bearing the service and guaranteeing the service, and the configuration of the server comprises a processor, a hard disk, a memory, a system bus and the like, which are similar to a general computer architecture, but because the server needs to provide highly reliable service, the requirements on the aspects of processing capability stability, reliability, safety, expandability, manageability and the like are higher, and the big data server is a server for processing big data;

In the use process of the large data server on the market, a large amount of data needs to be processed, and the large data server is almost not in stop work, so that a large amount of heat can be accumulated in the server, the existing server can dissipate the heat of the terminal in an air cooling heat dissipation mode, but in the mode, external air flow can be introduced to enter the inner wall of the server, and residual moisture and dust in the external air flow are easily accumulated in the server, so that the normal use of the subsequent server is affected, and therefore, how to solve the problem is needed to be considered.

Disclosure of Invention

The invention aims to solve the defects in the prior art, and provides a big data server terminal which adopts the circulation flow of heat-conducting insulating oil to cooperate with a heat dissipation part to dissipate heat when in use, and prevents external dust or moist air from entering the inside of the server on the basis of ensuring better heat dissipation effect.

In order to achieve the above purpose, the present invention adopts the following technical scheme:

The big data server terminal comprises a base, wherein the upper end of the base is fixedly connected with a heat dissipation shell, an installation cavity is arranged in the heat dissipation shell, a terminal body is installed in the installation cavity, and temperature-conducting insulating oil is filled in the installation cavity; the liquid circulation mechanism comprises a mounting groove which is formed in the bottom of the mounting cavity, a horizontal mounting frame is mounted in the mounting groove, a rotating shaft is arranged on the horizontal mounting frame in a penetrating mode, the rotating shaft is rotationally connected with the horizontal mounting frame, a plurality of axial flow fan blades are fixedly connected to the outer side of the rotating shaft at equal intervals, and the inner bottom space of the mounting groove is communicated with the inner top of the mounting cavity through a liquid discharge pipe; the cooling mechanism comprises a rectangular box fixedly connected to the right side of the base, two columnar grooves are symmetrically formed in the upper end of the rectangular box, piston blocks capable of sliding up and down are arranged in each columnar groove, rectangular through grooves are formed in the base in a penetrating mode, a high-pressure cylinder is installed at the inner bottom of each rectangular through groove, the inner bottom of each columnar groove located at the rear side is communicated with the outside through a second air inlet, the inner bottom of each columnar groove located at the rear side is communicated with the inside of each high-pressure cylinder through an exhaust pipe, a communicating pipe is communicated with the inner top space of each high-pressure cylinder, a vortex tube is communicated with the other end of each communicating pipe, an annular cavity is formed in the heat dissipation shell, and the cold air end of each vortex tube is communicated with the inside of the annular cavity; the driving mechanism is used for driving the liquid circulation mechanism and the cooling mechanism; and the auxiliary heat dissipation mechanism is used for improving the heat dissipation performance of the high-pressure cylinder.

Preferably, the phase change material is arranged in the annular cavity, the front side space of the annular cavity is communicated with the outside through the air outlet, and the liquid discharge pipe penetrates through the annular cavity.

Preferably, the pressure release valve is installed in the communicating pipe, the first check valve is installed in the exhaust pipe and the second air inlet, the first check valve in the exhaust pipe flows to the column groove to enter the high-pressure cylinder in a one-way, and the first check valve in the second air inlet flows to the outside to enter the bottom of the column groove in a one-way.

Preferably, the driving mechanism comprises a double-shaft motor arranged at the upper end of the base, a left output shaft of the double-shaft motor extends to the inside of the installation cavity and is provided with a second bevel gear, and the upper end of the rotating shaft is provided with a first bevel gear.

Preferably, the first bevel gear is meshed with the second bevel gear, and two sides of the upper end part of the rotating shaft are fixedly connected with L-shaped connecting rods.

Preferably, the right side output shaft of biax motor fixedly connected with rolling disc, two the upper end of piston piece is fixedly connected with U-shaped pole jointly, the eccentric department rotation of rolling disc is connected with the connecting rod, the other end of connecting rod is connected with the horizontal part rotation of U-shaped pole.

Preferably, the auxiliary heat dissipation mechanism comprises a first air inlet arranged at the inner bottom of the front side columnar groove, a water storage cavity is arranged in the base, water is filled in the water storage cavity, the inner bottom of the columnar groove located at the front side is communicated with the inner side of the water storage cavity through a liquid inlet pipe, a discharge pipe is communicated with the inner bottom of the columnar groove located at the front side, a plurality of heat dissipation fins are arranged on the outer side of the high-pressure cylinder, one sides of the heat dissipation fins extend to the inner side of the high-pressure cylinder, a hollow plate is arranged at the inner top of the rectangular through groove, a plurality of atomizing nozzles are arranged at the inner bottom of the hollow plate, and each atomizing nozzle is formed by a mounting circular ring and an atomizing nozzle, and the other end of the discharge pipe is communicated with the inner side of the hollow plate.

Preferably, the discharge pipe, the liquid inlet pipe and the first air inlet are internally provided with second one-way valves, the second one-way valve in the first air inlet flows to the front side columnar groove in a unidirectional way from the outside, the second one-way valve in the liquid inlet pipe flows to the water storage cavity in a unidirectional way to the front side columnar groove, and the second one-way valve in the discharge pipe flows to the front side columnar groove in a unidirectional way to the hollow plate.

Compared with the prior art, the invention has the beneficial effects that:

1. Be provided with axial fan blade, the start-up of biax motor can drive axial fan blade and rotate, axial fan blade's rotation can drive inside fluid flow, with the insulating conduction temperature oil suction of installation cavity bottom, then arrange the interior top in installation cavity, utilize this mode, can let insulating conduction temperature oil circulation flow, the start-up of biax motor still can produce high-pressure gas simultaneously, the use of high-pressure gas's release cooperation vortex tube can produce low temperature gas, low temperature gas is by phase change material storage, and when insulating conduction temperature oil circulation flows, can contact phase change material, heat transfer is carried out, make insulating conduction temperature oil temperature reduce fast, reach radiating purpose.

2. Because the oil body is in the flowing state, the homogeneity of cooling is better, in addition, above-mentioned pivot rotation in-process, still can drive two L form connecting rods and rotate to stir insulating heat conduction oil, further promote the homogeneity of cooling.

3. The whole heat dissipation is internal heat dissipation, external air cannot be introduced into the server, and the situation that external dust or moist air enters the server to influence the normal operation of the server is avoided.

4. After the double-shaft motor is started, an atomization water body is sprayed out firstly at the atomization nozzle, then gas is sprayed out, after the atomization water body is contacted with a plurality of radiating fins, the heat is absorbed and evaporated rapidly, the temperature of high-pressure gas in the high-pressure cylinder is reduced, the temperature of the high-pressure gas released subsequently is not too high, the temperature of low-temperature air exhausted from the vortex tube is lower finally, the refrigerating effect is better, and the gas can achieve the effects of accelerating evaporation and air cooling.

In summary, when the server terminal is used, on the basis of having a good heat dissipation effect, the heat dissipation is performed by adopting an internal heat dissipation mode, the overall heat dissipation effect is relatively uniform, and meanwhile, external air is not introduced.

Drawings

Fig. 1 is a schematic structural diagram of a big data server terminal according to the present invention;

FIG. 2 is a left side view schematic of FIG. 1;

FIG. 3 is a schematic cross-sectional view of FIG. 1;

FIG. 4 is an enlarged schematic view of a rectangular box;

FIG. 5 is a schematic view from the bottom of FIG. 4;

FIG. 6 is a schematic diagram of one of the output shafts of the dual-shaft motor mated with the rotating shaft;

Fig. 7 is a schematic structural view of the hollow slab.

In the figure: the device comprises a heat dissipation shell, a base, a rectangular through groove 3, an air outlet 4, a double-shaft motor 5, a rotary disk 6, a rectangular box 7, a columnar groove 8, a U-shaped rod 9, a connecting rod 10, an exhaust pipe 11, a liquid inlet pipe 12, a communicating pipe 13, a vortex tube 14, a high-pressure cylinder 15, a heat dissipation fin 16, a mounting cavity 17, a terminal body 18, a liquid discharge pipe 19, a mounting groove 20, a ring cavity 21, a phase change material 22, a water storage cavity 23, a piston block 24, a first air inlet 25, a second air inlet 26, a discharge pipe 27, a hollow plate 28, a horizontal mounting rack 29, a rotary shaft 30, a axial flow fan blade 31, a L-shaped connecting rod 32, a first bevel gear 33, a second bevel gear 34 and an atomization nozzle 35.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

Referring to fig. 1-7, a big data server terminal comprises a base 2, wherein the upper end of the base 2 is fixedly connected with a heat dissipation shell 1, an installation cavity 17 is arranged in the heat dissipation shell 1, a terminal body 18 is arranged in the installation cavity 17, and heat conduction insulating oil is filled in the installation cavity 17, so that the heat conduction insulating oil has good heat conduction property and insulativity, and the heat dissipation effect is better;

As an embodiment of the invention, the invention further comprises a liquid circulation mechanism, the liquid circulation mechanism comprises a mounting groove 20 arranged at the bottom of the mounting cavity 17, a horizontal mounting frame 29 is arranged in the mounting groove 20, a rotating shaft 30 is arranged on the horizontal mounting frame 29 in a penetrating way, the rotating shaft 30 is rotationally connected with the horizontal mounting frame 29, a plurality of axial flow fan blades 31 are fixedly connected at equal intervals on the outer side of the rotating shaft 30, the axial flow fan blades 31 can generate liquid flow from top to bottom after rotating, and the inner bottom space of the mounting groove 20 is communicated with the inner top of the mounting cavity 17 through a liquid discharge pipe 19;

As an embodiment of the invention, the device further comprises a cooling mechanism, the cooling mechanism comprises a rectangular box 7 fixedly connected to the right side of a base 2, two columnar grooves 8 are symmetrically arranged at the upper end of the rectangular box 7, a piston block 24 capable of sliding up and down is arranged in each columnar groove 8, a rectangular through groove 3 is arranged on the base 2 in a front-back penetrating manner, a high-pressure cylinder 15 is arranged at the inner bottom of the rectangular through groove 3, the inner bottom of the columnar groove 8 at the rear side is communicated with the outside through a second air inlet 26, the inner bottom of the columnar groove 8 at the rear side is communicated with the inside of the high-pressure cylinder 15 through an exhaust pipe 11, a communicating pipe 13 is communicated with the inner top space of the high-pressure cylinder 15, a vortex tube 14 is communicated with the other end of the communicating pipe 13, the vortex tube 14 is also called Lank-Her vortex tube, a mechanical device is used for enabling separated compressed gas to enter into a hot flow and a cold flow, the gas from the hot end can reach 200 ℃, the gas from the cold end can reach-50 ℃, no moving parts are arranged, the compressed gas is injected into a flow chamber tangentially, and finally the compressed gas is sprayed out to a high rotation speed;

As one embodiment of the present invention, the inside of the heat dissipation housing 1 is provided with the annular cavity 21, the cold air end of the vortex tube 14 is communicated with the inside of the annular cavity 21, the annular cavity 21 is provided with the phase change material 22, the phase change material 22 refers to a material which changes the state of the material and can provide latent heat under the condition of constant temperature, the process of changing physical properties is called a phase change process, at this time, the phase change material 22 absorbs or releases a large amount of latent heat, in the scheme, the phase change material is used for cold storage, the front space of the annular cavity 21 is communicated with the outside through the air outlet 4, and the liquid discharge tube 19 penetrates through the annular cavity 21;

As an implementation mode of the invention, a pressure release valve is arranged in the communicating pipe 13, first check valves are arranged in the exhaust pipe 11 and the second air inlet 26, the check valves can ensure the unidirectional flow of fluid, the backflow of the fluid is avoided, the flow direction of the first check valve in the exhaust pipe 11 is that the columnar groove 8 enters the high-pressure cylinder 15 in a unidirectional way, and the flow direction of the first check valve in the second air inlet 26 enters the bottom of the columnar groove 8 in a unidirectional way;

As one embodiment of the invention, the invention also comprises a driving mechanism, wherein the driving mechanism is used for driving the liquid circulation mechanism and the cooling mechanism, the driving mechanism comprises a double-shaft motor 5 arranged at the upper end of the base 2, the double-shaft motor 5 is a servo motor, the servo motor can control the speed, the position accuracy is very accurate, the voltage signal can be converted into the torque and the rotating speed to drive a control object, the rotating speed of a rotor of the servo motor is controlled by an input signal and can quickly react, the driving mechanism is used as an executing element in an automatic control system, and has the characteristics of small electromechanical time constant, high linearity and the like, the received electric signal can be converted into the angular displacement or the angular velocity output on a motor shaft, the left output shaft of the double-shaft motor 5 extends to the inside of the installation cavity 17 and is provided with a second bevel gear 34, the upper end of the rotating shaft 30 is provided with a first bevel gear 33, the first bevel gear 33 is meshed with the second bevel gear 34, the second bevel gear 34 can be driven to rotate through the rotation of the first bevel gear 33, the two sides of the upper end part of the rotating shaft 30 are fixedly connected with an L-shaped connecting rod 32, the right side output shaft of the double-shaft motor 5 is fixedly connected with a rotating disc 6, the two piston blocks 24 are fixedly connected with the U-shaped connecting rod 10 at the other end of the U-shaped connecting rod 10, and the other end of the U-shaped connecting rod 10 is fixedly connected with the rotating disc 10;

As an embodiment of the invention, the high-pressure water pump further comprises an auxiliary heat dissipation mechanism, wherein the auxiliary heat dissipation mechanism is used for improving the heat dissipation performance of the high-pressure cylinder 15, the auxiliary heat dissipation mechanism comprises a first air inlet 25 formed at the inner bottom of the front-side columnar groove 8, a water storage cavity 23 is formed in the base 2, water is filled in the water storage cavity 23, the inner bottom of the columnar groove 8 positioned at the front side is communicated with the inner side of the water storage cavity 23 through a liquid inlet pipe 12, a discharge pipe 27 is communicated with the inner bottom of the columnar groove 8 positioned at the front side, a plurality of heat dissipation fins 16 are arranged on the outer side of the high-pressure cylinder 15, one side of each heat dissipation fin 16 extends into the high-pressure cylinder 15, a hollow plate 28 is arranged at the inner top of the rectangular through groove 3, a plurality of atomizing nozzles 35 are arranged at the inner bottom of the hollow plate 28, the atomizing nozzles 35 are formed by arranging circular rings and atomizing nozzles, the atomizing nozzles are devices for spraying water with mist scattering to the air through the nozzles, and the other end of the discharge pipe 27 is communicated with the inner side of the hollow plate 28;

As an embodiment of the present invention, the discharge pipe 27, the liquid inlet pipe 12 and the first air inlet 25 are all provided with second check valves, the second check valve flow direction in the first air inlet 25 is that the outside enters the front side columnar groove 8 in a unidirectional way, the second check valve flow direction in the liquid inlet pipe 12 is that the water storage cavity 23 enters the front side columnar groove 8 in a unidirectional way, and the second check valve flow direction in the discharge pipe 27 is that the front side columnar groove 8 enters the hollow plate 28 in a unidirectional way.

In the invention, when the double-shaft motor 5 is started in use, after the double-shaft motor 5 is started, the rotating shaft 30 is rotated through the meshing action of the first bevel gear 33 and the second bevel gear 34, the rotation of the rotating shaft 30 drives the axial flow fan blades 31 to rotate, the rotation of the axial flow fan blades 31 drives internal fluid to flow, insulating heat-conducting oil at the bottom of the mounting cavity 17 is pumped in and then discharged to the inner top of the mounting cavity 17, and the insulating heat-conducting oil can flow circularly in the mode;

In the process, the dual-shaft motor 5 is started to drive the rotating disc 6 to rotate, the rotating disc 6 rotates to be matched with the connecting rod 10, the U-shaped rod 9 can reciprocate up and down, the two piston blocks 24 can reciprocate up and down, when the piston block 24 at the rear side moves up, gas is supplemented from the outside through the second air inlet 26, when the piston block 24 at the rear side moves down, the gas is pressed into the high-pressure cylinder 15, high-pressure air can be accumulated in the high-pressure cylinder 15 in a manner that the pressure release valve is opened when the air pressure in the high-pressure cylinder 15 reaches the threshold value of the pressure release valve, a part of the high-pressure air in the high-pressure cylinder 15 can be released, the released high-pressure air can enter the vortex tube 14 from the communicating tube 13, then enters the annular cavity 21 through the cold end of the vortex tube 14, the low-temperature air generated by the vortex tube 14 can be contacted with the phase change material 22, the phase change material 22 can store the low temperature, and when the insulating thermal conduction oil circularly flows, the insulating thermal conduction oil can be contacted with the material 22 to perform heat exchange, so that the insulating thermal conduction oil can rapidly flow, the thermal conduction oil can be cooled down, and the thermal insulation thermal conduction oil can be cooled down uniformly, and the insulating oil can be cooled down uniformly, and the temperature can be cooled down, and the insulating thermal insulation oil can be cooled down uniformly, and the terminal is in a state is more rapidly, and the state is in a state that the state is cooled down, and the state is cooled down by the rotating shaft is further due to the rotation of the insulating oil, and the insulating medium, and the thermal conduction oil is cooled;

It should be noted that in the above process, since the pressure release valve is closed after being opened for a period of time and then opened for a period of time, the phase change material 22 can always store more cold energy, so as to ensure the heat dissipation effect thereof;

In addition, when the piston block 24 at the front side moves upwards, gas is supplemented through the first air inlet 25, and meanwhile, water is supplemented through the liquid inlet pipe 12, the pipe diameter setting position of the liquid inlet pipe 12 is smaller, so that the ratio of the pumped gas to the water is 5:1, the gas is positioned at the top of the water, when the piston block 24 at the front side moves downwards, the water is extruded out of the hollow plate 28 firstly, and is sprayed out of the atomizing nozzle 35, the atomized water is in an atomized state, and after contacting with the plurality of radiating fins 16, the gas absorbs heat rapidly and evaporates, the temperature of the high-pressure gas in the high-pressure cylinder 15 is reduced (more heat is generated when the gas is compressed), so that the temperature of the subsequently released high-pressure gas is not too high, and the temperature of the low-temperature air finally discharged from the vortex pipe 14 is lower, the refrigerating effect is better, and after the water is sprayed out, the gas can promote the evaporation of the atomized water on the radiating fins 16, the radiating effect of the air cooling effect of the radiating fins 16 is improved, and meanwhile, the actual radiating effect of the air cooling of the radiating fins 16 can be further improved, namely, the radiating effect of the air is further improved by moving the movable terminal 18 on the piston block 24 at the front side is further improved;

The heat dissipation is internal heat dissipation, external air cannot be introduced into the server, and the condition that external dust or moist air enters the server to influence the normal operation of the server is avoided.

The present invention is not limited to the above-mentioned embodiments, and any person skilled in the art, based on the technical solution of the present invention and the inventive concept thereof, can be replaced or changed within the scope of the present invention.

Claims (8)

1. A big data server terminal, comprising:

The heat dissipation device comprises a base (2), wherein the upper end of the base (2) is fixedly connected with a heat dissipation shell (1), an installation cavity (17) is formed in the heat dissipation shell (1), a terminal body (18) is installed in the installation cavity (17), and heat conduction insulating oil is filled in the installation cavity (17);

The liquid circulation mechanism comprises a mounting groove (20) formed in the inner bottom of the mounting cavity (17), a horizontal mounting frame (29) is mounted in the mounting groove (20), a rotating shaft (30) is arranged on the horizontal mounting frame (29) in a penetrating mode, the rotating shaft (30) is rotationally connected with the horizontal mounting frame (29), a plurality of axial flow fan blades (31) are fixedly connected to the outer side of the rotating shaft (30) at equal intervals, and the inner bottom space of the mounting groove (20) is communicated with the inner top of the mounting cavity (17) through a liquid discharge pipe (19);

The cooling mechanism comprises a rectangular box (7) fixedly connected to the right side of a base (2), two columnar grooves (8) are symmetrically formed in the upper end of the rectangular box (7), piston blocks (24) capable of sliding up and down are arranged in each columnar groove (8), rectangular through grooves (3) are formed in the base (2) in a front-back penetrating mode, a high-pressure cylinder (15) is arranged at the inner bottom of each rectangular through groove (3), the inner bottom of each columnar groove (8) at the rear side is communicated with the outside through a second air inlet (26), the inner bottom of each columnar groove (8) at the rear side is communicated with the inside of each high-pressure cylinder (15) through an exhaust pipe (11), a communicating pipe (13) is communicated with the inner top space of each high-pressure cylinder (15), a vortex tube (14) is communicated with the other end of each communicating pipe (13), an annular cavity (21) is formed in the inside of each heat dissipation shell (1), and the cold air end of each vortex tube (14) is communicated with the inside of the annular cavity (21);

The driving mechanism is used for driving the liquid circulation mechanism and the cooling mechanism;

And the auxiliary heat dissipation mechanism is used for improving the heat dissipation performance of the high-pressure cylinder (15).

2. A big data server terminal according to claim 1, characterized in that the annular cavity (21) is provided with a phase change material (22), the front space of the annular cavity (21) is communicated with the outside through the air outlet (4), and the liquid discharge pipe (19) penetrates through the annular cavity (21).

3. A big data server terminal according to claim 1, characterized in that a pressure release valve is installed in the communicating pipe (13), a first one-way valve is installed in each of the exhaust pipe (11) and the second air inlet (26), the first one-way valve in the exhaust pipe (11) flows to the column-shaped groove (8) to enter the high-pressure cylinder (15) in a one-way manner, and the first one-way valve in the second air inlet (26) flows to the outside to enter the bottom in the column-shaped groove (8) in a one-way manner.

4. A big data server terminal according to claim 1, characterized in that the driving mechanism comprises a double-shaft motor (5) mounted at the upper end of the base (2), the left output shaft of the double-shaft motor (5) extends into the mounting cavity (17) and is provided with a second bevel gear (34), and the upper end of the rotating shaft (30) is provided with a first bevel gear (33).

5. A big data server terminal according to claim 4, characterized in that the first bevel gear (33) is engaged with the second bevel gear (34), and the two sides of the upper end portion of the rotating shaft (30) are fixedly connected with L-shaped connecting rods (32).

6. The big data server terminal according to claim 4, wherein the right output shaft of the double-shaft motor (5) is fixedly connected with a rotating disc (6), the upper ends of the two piston blocks (24) are fixedly connected with a U-shaped rod (9) together, the eccentric part of the rotating disc (6) is rotatably connected with a connecting rod (10), and the other end of the connecting rod (10) is rotatably connected with the horizontal part of the U-shaped rod (9).

7. The big data server terminal according to claim 1, wherein the auxiliary heat dissipation mechanism comprises a first air inlet (25) formed in the inner bottom of the front side columnar groove (8), a water storage cavity (23) is formed in the base (2), water is filled in the water storage cavity (23), the inner bottom of the columnar groove (8) located at the front side is communicated with the inner side of the water storage cavity (23) through a liquid inlet pipe (12), a discharge pipe (27) is communicated with the inner bottom of the columnar groove (8) located at the front side, a plurality of heat dissipation fins (16) are arranged on the outer side of the high pressure cylinder (15), one sides of the heat dissipation fins (16) extend to the inner side of the high pressure cylinder (15), a hollow plate (28) is arranged at the inner top of the rectangular through groove (3), a plurality of atomizing nozzles (35) are arranged at the inner bottom of the hollow plate (28), and the other end of the discharge pipe (27) is communicated with the inner side of the hollow plate (28).

8. A big data server terminal according to claim 7, characterized in that the discharge pipe (27), the liquid inlet pipe (12) and the first air inlet (25) are provided with second one-way valves, the second one-way valve flow direction in the first air inlet (25) is that the outside world enters the front side column-shaped groove (8) in a one-way mode, the second one-way valve flow direction in the liquid inlet pipe (12) is that the water storage cavity (23) enters the front side column-shaped groove (8) in a one-way mode, and the second one-way valve flow direction in the discharge pipe (27) is that the front side column-shaped groove (8) enters the hollow plate (28) in a one-way mode.