CN114201008A - Heat dissipation device of big data internet server - Google Patents

Abstract

The invention relates to a heat dissipation device of a big data internet server, which comprises a cabinet body, a turbine, an air guide assembly, an air-cooled heat exchanger and an air compressor, wherein the air guide assembly is arranged on the cabinet body; cold air generated by the air-cooled heat exchanger is pressurized by the air compressor and then enters the first driving chamber to drive the turbine to rotate, the turbine drives the air guide assembly to work in the rotating process, the cold air enters the circulation heat dissipation chamber to perform heat dissipation and cooling on a server inside the circulation heat dissipation chamber under the action of the air guide assembly, and hot air generated in the process enters the air-cooled heat exchanger under the action of the air compressor to perform heat exchange and cooling and then is reused; compared with the prior art, this device can directly dispel the heat to the server, and not only the radiating effect is good, adopts high-pressure gas drive turbine to drive air guide component work moreover and drives the gas flow, the effectual energy consumption that has reduced.

Description

Heat dissipation device of big data internet server

Technical Field

The invention relates to the technical field of heat dissipation equipment, in particular to a heat dissipation device of a big data internet server.

Background

China's data centers develop rapidly, the total amount is over 40 thousands, annual power consumption is over 1.5% of the power consumption of the whole society, the data center energy consumption is expected to be equivalent to one year of power generation of three gorges power stations every year, the PUE of most of the data centers is still generally more than 2.2, and the difference is larger than the international advanced level. Data center IT equipment needs to be cooled all weather, and a precise air conditioner is adopted in a machine room for refrigeration generally, so that the environmental control requirement of the data center is met. The energy consumption of the air conditioning unit of the data center accounts for 35% -45% of the total energy consumption of the machine room, which is second to the energy consumption of IT equipment of the data center, so that the PUE value of the data center is high, and the energy efficiency utilization rate is low.

The existing cooling mode of the data center is to cool the environment firstly and then cool the equipment, the heat dissipation can not be directly carried out on the server, the energy consumption is high, and the heat dissipation effect is poor.

Therefore, there is a need to provide a new technical solution to overcome the above-mentioned drawbacks.

Disclosure of Invention

The invention aims to provide a heat dissipation device of a big data internet server, which can effectively solve the technical problems.

In order to achieve the purpose of the invention, the following technical scheme is adopted:

the utility model provides a heat abstractor of big data internet server which characterized in that: the method comprises the following steps:

the cabinet body: the interior of the heat exchanger is sequentially divided into a first driving chamber, a circulation heat dissipation chamber and a second driving chamber from right to left; the first driving chamber is communicated with the circulation heat dissipation chamber, and cold air enters the circulation heat dissipation chamber through the first driving chamber to dissipate heat of a server installed in the circulation heat dissipation chamber;

a turbine: the first driving chamber is rotatably connected with the first driving chamber;

the air guide component: the circulating heat dissipation chamber is positioned in the circulating heat dissipation chamber, is in driving connection with the turbine, is driven by the turbine to rotate to send cold air into the circulating heat dissipation chamber, and sends hot air generated in the heat dissipation process out of the circulating heat dissipation chamber;

air-cooled heat exchanger: the heat source inlet is fixedly arranged at the bottom of the cabinet body and communicated with the circulation heat dissipation chamber through a hot air conveying pipeline, and the heat source inlet is used for carrying out heat exchange and cooling on hot air flowing out of the circulation heat dissipation chamber;

and, an air compressor: and the air outlet is communicated with the first driving chamber and used for driving air to circularly flow and pressurizing the cold air before the cold air enters the first driving chamber so that the cold air can drive the turbine to rotate.

Preferably, the circulation heat dissipation chamber is sequentially divided into a first air supply cavity, a flow guide cavity and a second air supply cavity from top to bottom; the right ends of the first air supply cavity and the second air supply cavity are uniformly provided with first air vents communicated with the first driving chamber, the first air supply cavity and the second air supply cavity are communicated with the flow guide cavity, and the flow guide cavity is communicated with the cold air heat exchanger through a hot air conveying pipeline.

Preferably, the flow guide cavity is internally and fixedly provided with a first installation chamber and a second installation chamber which are vertically and symmetrically distributed and used for fixing the server, and the first installation chamber and the second installation chamber are respectively provided with a plurality of installation chambers at equal intervals along the length direction of the flow guide cavity.

Preferably, the bottom of the first installation chamber is fixedly provided with a supporting seat for fixing a server, airflow channels are respectively arranged between the supporting seat and the server heat dissipation plate and between the bottom plate of the first installation chamber and the bottom plate of the first installation chamber, an air inlet is formed in the middle of the top plate of the first installation chamber, and second ventilation holes communicated with the flow guide cavity are uniformly distributed at the lower end of the right side wall of the first installation chamber, so that air in the first installation chamber can be conveniently circulated.

Preferably, the supporting seat used for fixing the server is fixedly arranged on the inner side wall of the top plate of the second installation chamber, airflow channels are respectively arranged between the supporting seat and the top plate of the first installation chamber and between the server heat dissipation plate and the top plate of the first installation chamber, an air inlet is formed in the middle of the bottom plate of the second installation chamber, and second ventilation holes communicated with the flow guide cavity are uniformly distributed in the upper end of the right side wall of the second installation chamber, so that air in the second installation chamber can be conveniently circulated.

Preferably, the air inlet of first installation room and the air inlet department of second installation room all install the door that opens and shuts, just all set firmly temperature sensor in first installation room and the second installation room for real-time detection the indoor temperature of first installation room and second installation to the open degree of controlling the door that opens and shuts realizes cold air rational distribution.

Preferably, the air guide assembly includes:

first air guide roll: the rotating shaft of the turbine is fixedly connected with the rotating shaft of the turbine and driven to rotate by the turbine;

a second air guide roller: the two air supply chambers are respectively and rotatably connected into the first air supply chamber and the second air supply chamber and are in driving connection with the first air guide roller through a belt pulley group, and the belt pulley group is positioned in the second driving chamber; the second air guide roller is driven by the first air guide roller to rotate so as to drive cold air to enter the first air supply cavity and the second air supply cavity;

a third air guide roller: the air guide device is rotationally connected between two adjacent first installation chambers or two adjacent second installation chambers, one end of the air guide device is rotationally connected with the top wall or the bottom plate of the air guide cavity, and the other end of the air guide device is in driving connection with the first air guide roller through a first conical gear set; the third air guide roller and the first air guide roller act together to drive hot air to be discharged out of the first installation chamber or the second installation chamber, and the hot air is guided to the air inlet of the hot air conveying pipeline;

and, a fourth wind guide roller: the first installation chamber and the second installation chamber are connected in a rotating mode, one end of the first installation chamber is connected with the left side wall of the first installation chamber or the second installation chamber in a rotating mode, the other end of the first installation chamber is connected with the third air guide roller in a driving mode through a second bevel gear set, and therefore the third air guide roller is driven to rotate to guide cold air into the first installation chamber and/or the second installation chamber.

Preferably, the first air guide roller and the left side wall and the right side wall of the circulation heat dissipation chamber, and the second air guide roller and the circulation heat dissipation chamber are rotatably connected through sealed bearings.

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

according to the invention, cold air generated by an air-cooled heat exchanger is pressurized by an air compressor and then enters a first driving chamber to drive a turbine to rotate, the turbine drives an air guide assembly to work in the rotating process, the cold air enters a circulation heat dissipation chamber to perform heat dissipation and cooling on a server inside the circulation heat dissipation chamber under the action of the air guide assembly, and hot air generated in the process enters the air-cooled heat exchanger under the action of the air compressor to perform heat exchange and cooling and then is reused; compared with the prior art, the technical scheme has the advantages that the server is directly cooled, the cooling effect is good, the high-pressure gas drives the turbine to drive the air guide assembly to work to drive the air to flow, and the energy consumption is effectively reduced.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the description of the embodiments will be briefly introduced below.

Fig. 1 is a front view of a heat dissipation device of a big data internet server according to the present invention;

FIG. 2 is a schematic diagram of an internal structure of a heat dissipation device of a big data Internet server according to the present invention

Fig. 3 is a flowchart of a heat dissipation apparatus of a big data internet server according to the present invention.

Numerical description in the figures:

1. a cabinet body; 101. a first drive chamber; 102. a second drive chamber; 103. a first air supply cavity; 104. a flow guide cavity; 105. a second air supply cavity; 106. a first installation chamber; 107. a second installation chamber; 108. opening and closing the door;

a turbine;

an air guide assembly; 301. a first air guide roller; 302. a second air guide roller; 303. a third air guide roller; 304. a fourth air guide roller;

4. an air-cooled heat exchanger; 5. an air compressor; 6. a hot air delivery duct; 7. a supporting seat; 8. a support plate; 9. a server; 10. a PLC control system; 11. a temperature sensor; 12. a thermal energy generator; 13. and (4) a storage battery.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the following will clearly and completely describe the technical solutions in the embodiments of the present invention, and it is obvious that the described embodiments are some embodiments of the present invention, but not all embodiments.

In the description of the present invention, it is to be understood that the terms "central," "lateral," "longitudinal," "front," "rear," "left," "right," "upper," "lower," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like are used in the orientation or positional relationship indicated in the drawings for convenience in describing the invention and for simplicity in description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are therefore not to be considered limiting of the scope of the invention. When an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When a component is referred to as being "connected" to another component, it can be directly connected to the other component or intervening components may also be present. When a component is referred to as being "disposed on" another component, it can be directly on the other component or intervening components may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only.

The heat dissipation device of a big data internet server according to the present invention will be described in detail with reference to the accompanying drawings.

As shown in fig. 1 to 3, the heat dissipation apparatus for a big data internet server 9 provided by the present invention includes a cabinet 1, a turbine, an air guide assembly 3, an air-cooled heat exchanger 4 and an air compressor 5.

The cabinet body 1 is internally divided into a first driving chamber 101, a circulation heat dissipation chamber and a second driving chamber 102 from right to left; the first driving chamber 101 is communicated with the circulation heat dissipation chamber, and cold air enters the circulation heat dissipation chamber through the first driving chamber 101 to perform heat dissipation and cooling on the servers 9 installed inside the circulation heat dissipation chamber.

The turbine is rotatably connected in the first driving chamber 101; the air guide assembly 3 is positioned in the circulation heat dissipation chamber, is in driving connection with the turbine, is driven by the turbine to rotate to send cold air into the circulation heat dissipation chamber, and sends hot air generated in the heat dissipation process out of the circulation heat dissipation chamber to form heat dissipation circulation.

The air-cooled heat exchanger 4 is arranged at the bottom of the cabinet body 1, and a heat source inlet of the air-cooled heat exchanger is communicated with the circulation heat dissipation chamber through a hot air conveying pipeline 6 and is used for carrying out heat exchange and cooling on hot air flowing out of the circulation heat dissipation chamber. The air compressor 5 is installed on the outer side of the right side wall of the cabinet body 1 and located below the second driving chamber 102, an air inlet of the air compressor is communicated with a cold source outlet of the circulation heat dissipation chamber, and an air outlet of the air compressor is communicated with the first driving chamber 101 and used for driving air to flow in a circulation mode and pressurizing the cold air before the cold air enters the first driving chamber 101 so that the cold air can drive the turbine to rotate.

In the invention, cold air generated by an air-cooled heat exchanger 4 is pressurized by an air compressor 5 and then enters a first driving chamber 101 to drive a turbine to rotate, the turbine drives the air guide assembly 3 to work in the rotating process, the cold air enters the circulation heat dissipation chamber to perform heat dissipation and cooling on a server 9 inside the circulation heat dissipation chamber under the action of the air guide assembly 3, and hot air generated in the process enters the air-cooled heat exchanger 4 under the action of the air compressor 5 to perform heat exchange and cooling and then is reused; compared with the prior art, the technical scheme has the advantages that the server 9 is directly cooled, the cooling effect is good, the high-pressure gas is adopted to drive the turbine to drive the air guide component 3 to work, so that the air flows, and the energy consumption is effectively reduced.

Specifically, in this embodiment, the circulation heat dissipation chamber is sequentially divided into a first air supply cavity 103, a diversion cavity 104, and a second air supply cavity 105 from top to bottom; the right ends of the first air supply cavity 103 and the second air supply cavity 105 are uniformly provided with first vent holes communicated with the first driving chamber 101, the first air supply cavity 103 and the second air supply cavity 105 are communicated with the flow guide cavity 104, and the flow guide cavity 104 is communicated with the cold air heat exchanger through a hot air conveying pipeline 6.

The flow guide cavity 104 is internally provided with a first installation chamber 106 and a second installation chamber 107 which are distributed up and down symmetrically and used for fixing the server 9, and the first installation chamber 106 and the second installation chamber 107 are respectively provided with a plurality of chambers at equal intervals along the length direction of the flow guide cavity 104. Specifically, in the present embodiment, each cabinet 1 is provided with 3 corresponding first mounting chambers 106 and 3 corresponding second mounting chambers 107.

An air inlet is formed in the middle of the top plate of the first mounting chamber 106, and second vent holes communicated with the flow guide cavity 104 are uniformly distributed at the lower end of the right side wall of the first mounting chamber; meanwhile, a support seat 7 for fixing the server 9 is also installed at the bottom of the first installation room 106; the right end of the support seat 7 is fixedly connected with the right side wall of the first mounting chamber 106, and an airflow channel is arranged between the left end of the support seat and the left side wall of the first mounting chamber 106; in addition, a waist-shaped hole is formed in the surface of the support base 7 at a position corresponding to the heat dissipation plate of the server 9, and the bottom of the support base 7 is fixedly connected with the bottom plate of the first installation chamber 106 through support legs distributed in a matrix; thereby forming a circulation passage in the first mounting chamber 106 to facilitate air circulation.

An air inlet is formed in the middle of the bottom plate of the second mounting chamber 107, and second ventilation holes communicated with the flow guide cavity 104 are uniformly distributed in the upper end of the right side wall of the second mounting chamber; meanwhile, the supporting seat 7 is further installed on the inner side wall of the top plate of the second installation chamber 107, a supporting plate 8 which is horizontally placed is installed below the supporting seat 7 in the second installation chamber 107, and the server 9 is fixed between the supporting seat 7 and the supporting plate 8; the right end of the support seat 7 is fixedly connected with the right side wall of the second mounting chamber 107, and an airflow channel is arranged between the left end of the support seat and the left side wall of the second mounting chamber 107; in addition, a waist-shaped hole is formed in the surface of the support seat 7 at a position corresponding to the heat dissipation plate of the server 9, and the top of the support seat 7 is fixedly connected with the top plate of the second installation chamber 107 through support legs distributed in a matrix; the left end of the supporting plate 8 is provided with a third ventilation hole; so that a circulation passage is formed in the second mounting chamber 107 to facilitate air circulation.

Through setting up independent first installation room 106 and second installation room 107, can realize dispelling the heat cooling to single server 9, improved the flexibility of use of this device, further improved the radiating effect simultaneously.

Specifically, in the present embodiment, the air guide assembly 3 includes the air guide assembly 3 including a first air guide roller 301, a second air guide roller 302, a third air guide roller 303, and a fourth air guide roller 304.

The first wind guide roller 301 is rotatably connected in the guide cavity 104 and located between the first installation chamber 106 and the second installation chamber 107, and a rotating shaft thereof is fixedly connected with a rotating shaft of the turbine and is driven by the turbine to rotate.

Two second air guide rollers 302 are respectively and rotatably connected in the first air supply cavity 103 and the second air supply cavity 105, and are in driving connection with the first air guide roller 301 through a pulley set, and the pulley set is located in the second driving chamber 102; the second air guide roller 302 is driven by the first air guide roller 301 to rotate to drive cold air to enter the first air supply cavity 103 and the second air supply cavity 105 through the first vent hole.

The third air guide roller 303 is rotatably connected between two adjacent first installation chambers 106 or two adjacent second installation chambers 107, one end of the third air guide roller is rotatably connected with the top wall or the bottom plate of the air guide cavity 104, and the other end of the third air guide roller is in driving connection with the first air guide roller 301 through a first conical gear set; the third air guide roller 303 and the first air guide roller 301 work together to drive hot air to be discharged out of the first installation chamber 106 or the second installation chamber 107, and guide the hot air to the air inlet of the hot air delivery pipe 6.

The fourth air guide roll 304 is rotatably connected in the first installation chamber 106 or the second installation chamber 107, one end of the fourth air guide roll is rotatably connected with the left side wall of the first installation chamber 106 or the second installation chamber 107, and the other end of the fourth air guide roll is in driving connection with the third air guide roll 303 through a second bevel gear set; so that the cold air is guided into the first installation chamber 106 and/or the second installation chamber 107 by being rotated by the third air guide roller 303.

It should be noted that the first air guide roller 301 and the left and right side walls of the circulation heat dissipation chamber, and the second air guide roller 302 and the circulation heat dissipation chamber are rotatably connected by a seal bearing.

Through the air guide assembly 3 with the structure, not only the whole set has high operation stability, but also the components of the air guide assembly have high uniformity, and the air guide assembly is convenient to maintain or replace.

In addition, in the present embodiment, a PLC control system 10 is further provided, and the server 9, the air-cooled heat exchanger 4 and the air compressor 5 are all in control connection with the PLC control system 10 so as to control the operation thereof.

Meanwhile, in this embodiment, the air inlet of the first installation chamber 106 and the air inlet of the second installation chamber 107 are both provided with an opening and closing door 108, the first installation chamber 106 and the second installation chamber 107 are both fixedly provided with a temperature sensor 11, and the opening and closing door 108 and the temperature sensor 11 are both in control connection with the PLC control system 10; the temperature sensor 11 is used for detecting the temperature in the first installation chamber 106 and the second installation chamber 107 in real time, and controlling the opening degree of the opening and closing door 108 through the PLC control system 10, so that the reasonable distribution of the cold air is realized, the heat dissipation effect of each server 9 is ensured, and the cold air is fully utilized.

Specifically, in this embodiment, a thermal energy generator 12 and a storage battery 13 are further provided, the thermal energy generator 12 and the storage battery 13 are both in control connection with the PLC control system 10, and a heat source inlet of the thermal energy generator 12 is communicated with a heat source outlet of the air-cooled heat exchanger 4; the heat energy generated by the air-cooled heat exchanger 4 is collected into the heat energy generator 12 to be utilized, and the generated electric energy is stored in the storage battery 13 to supply power to the server 9, the air compressor 5 and the air-cooled heat exchanger 4 during power failure, so that the effective utilization of the heat energy is realized.

The working principle of the invention is as follows:

when the air cooling device is used, cold air generated by the air cooling heat exchanger 4 is pressurized by the air compressor 5 and then enters the first driving chamber 101 to push the turbine to rotate, the turbine drives the first air guide roller 301 to rotate in the rotating process, so that the second air guide roller 302, the third air guide roller 303 and the fourth air guide roller 304 are driven to synchronously rotate, the cold air firstly enters the first air supply cavity 103 and the second air supply cavity 105 under the drive of the first air guide roller 301, then is shunted under the drive of the fourth air guide roller and enters the first installation chamber 106 and the second installation chamber 107 to cool the server 9 in a heat dissipation manner, and finally, hot air flows out through the second air vent under the drive of the first air guide roller and the second air guide roller and enters the air cooling heat exchanger for cooling under the drive of the air compressor 5 to be reused; the heat energy generated in the heat exchange process enters the heat energy generator 12 to be utilized, and the generated electric energy is stored in the storage battery 13 to supply power to the server 9, the air compressor 5 and the air-cooled heat exchanger 4 during power failure.

In addition, through separating cabinet body 1 for a plurality of independent spaces in this embodiment to all install sealing door in the outside in every space, conveniently maintain or change different spare parts.

The standard parts used in the invention can be purchased from the market, the special-shaped parts can be customized according to the description of the specification and the accompanying drawings, the specific connection mode of each part adopts conventional means such as bolts, rivets, welding and the like mature in the prior art, the machinery, parts and equipment adopt conventional models in the prior art, and the circuit connection adopts the conventional connection mode in the prior art, and the details are not described, and the content not described in detail in the specification belongs to the prior art known by persons skilled in the art.

Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention.

Claims (8)

1. The utility model provides a heat abstractor of big data internet server which characterized in that: the method comprises the following steps:

the cabinet body: the interior of the heat exchanger is sequentially divided into a first driving chamber, a circulation heat dissipation chamber and a second driving chamber from right to left; the first driving chamber is communicated with the circulation heat dissipation chamber, and cold air enters the circulation heat dissipation chamber through the first driving chamber to dissipate heat of a server installed in the circulation heat dissipation chamber;

a turbine: the first driving chamber is rotatably connected with the first driving chamber;

the air guide component: the circulating heat dissipation chamber is positioned in the circulating heat dissipation chamber, is in driving connection with the turbine, is driven by the turbine to rotate to send cold air into the circulating heat dissipation chamber, and sends hot air generated in the heat dissipation process out of the circulating heat dissipation chamber;

air-cooled heat exchanger: the heat source inlet is fixedly arranged at the bottom of the cabinet body and communicated with the circulation heat dissipation chamber through a hot air conveying pipeline, and the heat source inlet is used for carrying out heat exchange and cooling on hot air flowing out of the circulation heat dissipation chamber;

and, an air compressor: and the air outlet is communicated with the first driving chamber and used for driving air to circularly flow and pressurizing the cold air before the cold air enters the first driving chamber so that the cold air can drive the turbine to rotate.

2. The heat dissipation device of a big data internet server as claimed in claim 1, wherein: the circulation heat dissipation chamber is sequentially divided into a first air supply cavity, a flow guide cavity and a second air supply cavity from top to bottom; the right ends of the first air supply cavity and the second air supply cavity are uniformly provided with first air vents communicated with the first driving chamber, the first air supply cavity and the second air supply cavity are communicated with the flow guide cavity, and the flow guide cavity is communicated with the cold air heat exchanger through a hot air conveying pipeline.

3. The heat dissipation device of a big data internet server as claimed in claim 2, wherein: the water conservancy diversion intracavity sets firmly first installation room and the second installation room that is upper and lower symmetric distribution, and it is used for fixed server, just first installation room and second installation room all follow the equidistant a plurality of length direction in water conservancy diversion chamber.

4. The heat dissipation device of a big data internet server as claimed in claim 3, wherein: the bottom of the first installation chamber is fixedly provided with a supporting seat used for fixing a server, airflow channels are arranged between the supporting seat and the server heat dissipation plate and between the bottom plate of the first installation chamber, an air inlet is formed in the middle of the top plate of the first installation chamber, and second ventilation holes communicated with the flow guide cavity are uniformly distributed in the lower end of the right side wall of the first installation chamber, so that air in the first installation chamber can circulate.

5. The heat dissipation device of a big data internet server as claimed in claim 3, wherein: the supporting seat is fixedly arranged on the inner side wall of the top plate of the second installation chamber, a supporting plate is fixedly arranged in the second installation chamber below the supporting seat, and the server is fixed between the supporting seat and the supporting plate; airflow channels are arranged among the supporting seat, the server heat dissipation plate and the top plate of the first installation chamber, and a third ventilation hole is formed in the left end of the supporting plate; an air inlet is formed in the middle of the bottom plate of the second mounting chamber, and second ventilation holes communicated with the flow guide cavity are uniformly distributed in the upper end of the right side wall of the second mounting chamber, so that air in the second mounting chamber can be conveniently circulated.

6. The heat dissipation device of a big data internet server as claimed in claim 4 or 5, wherein: the air inlet of first installation room and the air inlet department of second installation room all install the door that opens and shuts, just all set firmly temperature sensor in first installation room and the second installation room for real-time detection the indoor temperature of first installation room and second installation to the open degree of controlling the door that opens and shuts realizes cold air rational distribution.

7. The heat dissipation device of a big data internet server as claimed in claim 6, wherein: the wind guide assembly includes:

first air guide roll: the rotating shaft of the turbine is fixedly connected with the rotating shaft of the turbine and driven to rotate by the turbine;

a second air guide roller: the two air supply chambers are respectively and rotatably connected into the first air supply chamber and the second air supply chamber and are in driving connection with the first air guide roller through a belt pulley group, and the belt pulley group is positioned in the second driving chamber; the second air guide roller is driven by the first air guide roller to rotate so as to drive cold air to enter the first air supply cavity and the second air supply cavity;

a third air guide roller: the air guide device is rotationally connected between two adjacent first installation chambers or two adjacent second installation chambers, one end of the air guide device is rotationally connected with the top wall or the bottom plate of the air guide cavity, and the other end of the air guide device is in driving connection with the first air guide roller through a first conical gear set; the third air guide roller and the first air guide roller act together to drive hot air to be discharged out of the first installation chamber or the second installation chamber, and the hot air is guided to the air inlet of the hot air conveying pipeline;

and, a fourth wind guide roller: the first installation chamber and the second installation chamber are connected in a rotating mode, one end of the first installation chamber is connected with the left side wall of the first installation chamber or the second installation chamber in a rotating mode, the other end of the first installation chamber is connected with the third air guide roller in a driving mode through a second bevel gear set, and therefore the third air guide roller is driven to rotate to guide cold air into the first installation chamber and/or the second installation chamber.

8. The heat dissipation device of a big data internet server as claimed in claim 7, wherein: and the first air guide roller is rotatably connected with the left side wall and the right side wall of the circulation heat dissipation chamber, and the second air guide roller is rotatably connected with the circulation heat dissipation chamber through sealing bearings.

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