CN113630999B

CN113630999B - High-efficiency big data processing device

Info

Publication number: CN113630999B
Application number: CN202110933309.6A
Authority: CN
Inventors: 肖池国
Original assignee: Shanghai Shenwei Technology Co ltd
Current assignee: Shanghai Shenwei Technology Co ltd
Priority date: 2021-08-14
Filing date: 2021-08-14
Publication date: 2023-11-17
Anticipated expiration: 2041-08-14
Also published as: CN113630999A

Abstract

The invention relates to a high-efficiency big data processing device, which comprises a shell, wherein a placing cavity and a heat exchange cavity which are communicated are arranged in the shell, a heat conducting piece extending into the placing cavity is arranged in the heat exchange cavity, an air guide flow passage communicated with the heat exchange cavity is arranged on the outer side of the shell, and an air guide piece is rotationally arranged at a heat dissipation hole of the shell; the invention improves the heat radiation mode of the traditional big data processing device, is matched with the use of the heat conducting piece and the air guide channel, realizes the preliminary heat radiation by the contact heat conduction of the processing device, enables the heat to be contacted with the heat conducting liquid, enables the generated air flow to circulate in the air guide channel, is matched with the use of the air guide piece and the transmission piece, enables the air flow circulated in the air guide channel to be used as a power source to drive the transmission piece to rotate, synchronously drives the air guide piece to rotate, enables the air guide piece to guide the air of the heat radiation hole of the shell, and accelerates the air flow velocity in the shell, thereby realizing the further heat radiation effect of the processing device.

Description

High-efficiency big data processing device

Technical Field

The present invention relates to a high-efficiency big data processing device.

Background

Big data is a data set which cannot be captured, managed and processed by a conventional software tool within a certain time range, is a massive, high-growth-rate and diversified information asset which needs a new processing mode to have stronger decision-making ability, insight discovery ability and flow optimization ability, can be processed by a manual or automatic device, becomes information after the data is interpreted and endowed with a certain meaning, is a basic link of system engineering and automatic control, and greatly influences the progress of human social development through the development of data processing technology and the breadth and depth of application thereof in various fields of social production and social life.

The existing big data processing device can rapidly analyze and process a large amount of big data information, but in the processing process, a large amount of heat is easy to generate due to the fact that the energy consumption is large, in addition, the existing big data processing device is usually matched with an integrated shell for use, the heat is usually discharged through a radiating hole, the heat discharging effect is poor, if the heat in the device cannot be timely discharged, the temperature of the device can be gradually increased, elements in the device are easily damaged, the performance of the device is affected, and the service life of the device is reduced.

In order to solve the above problems, the present invention proposes a high-efficiency big data processing apparatus.

Disclosure of Invention

(1) Technical problem to be solved

The invention aims to overcome the defects of the prior art, adapt to the actual needs, and provide a high-efficiency big data processing device so as to solve the technical problems.

(2) Technical proposal

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

the utility model provides a high-efficient big data processing device, includes the casing, be equipped with placing chamber and the heat transfer chamber that is linked together in the casing, the heat transfer intracavity is equipped with and extends to placing the heat conduction piece in the intracavity, the outside of casing is equipped with the air guide runner with the heat transfer chamber intercommunication, the louvre department of casing is equipped with the air guide piece rotationally, the intercommunication has one end to link to each other with the rotation end of air guide piece on the air guide runner and is used for driving the air guide piece along circumference pivoted driving medium.

Further, the heat conduction piece is including locating the heat absorption platform of placing the intracavity, one side of heat absorption platform is equipped with a plurality of heat conduction rods that extend to the heat transfer intracavity, the heat transfer intracavity is filled with the heat conduction liquid that the liquid level is located heat conduction rod extension top.

Further, the wind guide piece comprises a rotating rod rotatably arranged on the shell, and a wind guide fan is arranged on the rotating rod.

Further, the transmission piece comprises a mounting shell communicated with the air guide channel, a guide wheel with one side extending to the outer side of the mounting shell is rotationally arranged in the mounting shell, and an annular transmission belt is arranged between the extending end of the guide wheel and the outer side of the rotating rod.

Further, the air inlet shell is communicated with the shell placing cavity, one end of the air guide channel is communicated with the liquid guide shell, an arc-shaped liquid guide plate is arranged at the communication position of the liquid guide shell and the air guide channel, a liquid guide pipe is communicated with the liquid guide shell, and the air inlet shell is communicated with the liquid guide pipe.

Further, the liquid guide shell comprises an inclined block connected with the air guide channel, a plurality of air guide holes are formed in the connection position of the inclined edge of the inclined block and the air guide channel, the arc-shaped liquid guide plate is arranged on the inner side of the inclined block and located above the air guide holes, a water condensation plate is arranged on the inner side, away from the air guide holes, of the inclined block, and a plurality of heat conduction columns with one ends extending to the outer side of the inclined block are arranged on one side of the water condensation plate.

Further, the bevel edge of the bevel block is communicated with the liquid guide pipe, and the position of the liquid guide pipe, which is communicated with the bevel edge of the bevel block, is positioned below the position of the air guide hole.

Further, an inclined tube is communicated between the air inlet shell and the liquid guide tube, and a moisture absorption body with one end extending to the outer side of the inclined tube is arranged in the inclined tube.

Further, still including locating on the casing and with the heat transfer chamber intercommunication receive the water tank, it is the inlet that sets up relatively to receive water tank to be equipped with on the water tank with catheter one end, be equipped with the fixed slot on the casing, be equipped with in the fixed slot and be used for sheltering from to receive the shutoff piece of water tank and heat transfer chamber intercommunication department, be equipped with the buoyancy piece that one end extends to receiving in the water tank on the shutoff piece.

Further, the blocking piece is including locating the montant in the fixed slot, the one end of montant is equipped with and is used for sheltering from the shielding plate that receives water tank and heat transfer chamber intercommunication department, the buoyancy piece is including locating on the montant and one end extends to the kickboard that receives in the water tank.

(3) The beneficial effects are that:

A. the invention improves the heat radiation mode of the traditional big data processing device, is matched with the use of the heat conducting piece and the air guide channel, realizes the preliminary heat radiation by the contact heat conduction of the processing device, enables the heat to be contacted with the heat conducting liquid, enables the generated air flow to circulate in the air guide channel, is matched with the use of the air guide piece and the transmission piece, enables the air flow circulated in the air guide channel to be used as a power source to drive the transmission piece to rotate, synchronously drives the air guide piece to rotate, enables the air guide piece to guide the air of the heat radiation hole of the shell, and accelerates the air flow velocity in the shell, thereby realizing the further heat radiation effect of the processing device.

B. Then cooperate the use of drain casing, arc drain board and catheter, the air current in the air guide runner is got into in the drain casing by the air vent and is condensed into water with the contact of congeal the water board, the arc drain board prevents that the water of condensation from getting into the discharge that the air vent influences the air current to guide the water by the catheter, and cooperate to receive water tank, shutoff piece and buoyancy piece's use, make water store gradually in receiving the water tank, make the closure and opening of buoyancy piece control shutoff piece to receiving water tank and heat transfer chamber intercommunication department by the transform of liquid level, realize the recycle to water.

Drawings

FIG. 1 is a schematic diagram of the overall three-dimensional structure of a high-efficiency big data processing device of the present invention;

FIG. 2 is a three-dimensional view of the connection of the oblique block and the arc-shaped liquid guide plate of the high-efficiency big data processing device;

FIG. 3 is a front cross-sectional view of the high efficiency big data processing apparatus of the present invention;

FIG. 4 is a side view of the high efficiency big data processing apparatus of the present invention;

FIG. 5 is a front view of the high efficiency big data processing apparatus of the present invention;

FIG. 6 is an enlarged view of the high efficiency big data processing device A of the present invention;

fig. 7 is an enlarged view of the high-efficiency big data processing apparatus B of the present invention.

The reference numerals are as follows:

the heat-conducting device comprises a shell 1, a heat-conducting piece 2, a heat-absorbing table 21, a heat-conducting rod 22, a heat-conducting liquid 23, a heat-conducting flow channel 3, a wind-conducting piece 4, a rotating rod 41, a fan 42, a transmission piece 5, a mounting shell 51, a guide wheel 52, an annular transmission belt 53, an air inlet shell 6, a liquid-conducting shell 7, an inclined block 71, a condensation plate 72, a heat-conducting column 73, an arc-shaped liquid-conducting plate 8, a liquid-conducting tube 9, an inclined tube 10, a moisture-absorbing body 11, a water-receiving tank 12, a plugging piece 13, a vertical rod 131, a shielding plate 132, a buoyancy piece 14 and a floating plate 141.

Detailed Description

The invention is further illustrated by the following examples in connection with figures 1-7:

as shown in fig. 1, fig. 3, fig. 4 and fig. 5, a high-efficiency big data processing device comprises a shell 1, wherein a placing cavity and a heat exchange cavity which are communicated are arranged in the shell 1, a storage door which is matched with the placing cavity is arranged on the shell 1, an operator is used for placing the data processing device in the placing cavity, a wiring hole is arranged on the shell 1, a heat conducting piece 2 which extends into the placing cavity is arranged in the heat exchange cavity, an air guide channel 3 which is communicated with the heat exchange cavity is arranged on the outer side of the shell 1, the communication end of the air guide channel 3 and the heat exchange cavity is obliquely arranged towards the heat exchange cavity, an air guide piece 4 is rotationally arranged at a radiating hole of the shell 1, and a transmission piece 5 which is connected with the rotating end of the air guide piece 4 and is used for driving the air guide piece 4 to rotate along the circumferential direction is arranged on the air guide channel 3;

further, the heat conducting member 2 includes a heat absorbing stage 21 disposed in the placement cavity, a plurality of heat conducting rods 22 extending into the heat exchanging cavity are disposed on one side of the heat absorbing stage 21, the heat absorbing stage 21 and the heat conducting rods 22 are made of iron or other heat conducting materials, the heat exchanging cavity is filled with a heat conducting liquid 23 with a liquid level above an extending end of the heat conducting rods 22, and the heat conducting liquid 23 can be water;

the wind guide 4 comprises a rotating rod 41 rotatably arranged on the shell 1, and a wind guide fan 42 is arranged on the rotating rod 41;

the transmission piece 5 comprises a mounting shell 51 communicated with the air guide channel 3, a guide wheel 52 with one side extending to the outer side of the mounting shell 51 is rotationally arranged in the mounting shell 51, an annular transmission belt 53 is arranged between the extending end of the guide wheel 52 and the outer side of the rotating rod 41, winding wheels are arranged at the extending end of the guide wheel 52 and the outer side of the rotating rod 41, and the annular transmission belt 53 is in transmission connection through the two winding wheels;

the steam formed by the heat conducting liquid 23 is led into the air guide channel 3 to form air flow, the air flow passes through the guide wheel 52 and drives the guide wheel 52 to rotate, and the annular transmission belt 53 links the rotating rod 41 to rotate along the circumferential direction, so that the air guide fan 42 is driven to rotate to guide air outwards to the heat dissipation holes of the shell 1, and the heat dissipation operation of the treatment device can be completed; for example, one end of the guide wheel 52 is provided with a sector wheel, which is located in the guide air duct 3.

It is also preferable that the air guide channel 3 and the driving unit 5 on one side of the casing 1 are provided with two winding wheels, the rotating rod 41 is provided with two winding wheels, the winding wheels are respectively connected with two guide wheels 52 on one side, the two guide wheels 52 are symmetrically arranged on two sides of the rotating rod 41, so that the two guide wheels 52 synchronously drive the rotating rod 41 to rotate, and the rotating effect of the rotating rod 41 is improved.

In this embodiment, as shown in fig. 1, 2, 3 and 7, the air inlet shell 6 is further included and communicated with the placing cavity of the shell 1, one end of the air guide channel 3 is communicated with a liquid guide shell 7, an arc-shaped liquid guide plate 8 is arranged at the communication position of the liquid guide shell 7 and the air guide channel 3, a liquid guide pipe 9 is communicated with the liquid guide shell 7, and the air inlet shell 6 is communicated with the liquid guide pipe 9;

further, the liquid guiding shell 7 comprises an inclined block 71 connected with the air guiding channel 3, a plurality of air guiding holes are arranged at the connection part of the inclined edge of the inclined block 71 and the air guiding channel 3, an arc-shaped liquid guiding plate 8 is arranged at the inner side of the inclined block 71 and positioned above the air guiding holes, a water condensation plate 72 is arranged at the inner side of the inclined block 71 far away from the air guiding holes, a plurality of heat conducting columns 73 with one ends extending to the outer side of the inclined block 71 are arranged at one side of the water condensation plate 72, and the water condensation plate 72 and the heat conducting columns 73 are made of iron or other heat conducting materials;

the air flow in the air guide channel 3 enters the liquid guide shell 7 through the air guide hole, the air flow rises to be in contact with the condensation plate 72, and heat exchange is carried out between the heat conduction column 73 and the outside air, so that water vapor in the air flow is condensed on the condensation plate 72 to form water drops, the water drops on the condensation plate 72 fall down, the condensed water is prevented from entering the air guide hole by the arc-shaped liquid guide plate 8 to influence the discharge of the air flow, the water drops flow into the liquid guide tube 9 along the inclined edge of the inclined block 71, and then fall into the water receiving tank 12 along the lower end outlet of the liquid guide tube 9, so that the condensation recovery of the water vapor is realized, and the water vapor is prevented from being directly discharged to the outside;

the oblique edge of the oblique block 71 is communicated with the liquid guide pipe 9, and the position of the liquid guide pipe 9 communicated with the oblique edge of the oblique block 71 is lower than the position of the air guide hole, so that water drops falling on the condensation plate 72 can not fall into the air guide hole and can fall into the liquid guide pipe 9;

an inclined tube 10 is communicated between the air inlet shell 6 and the liquid guide tube 9, and a moisture absorber 11 with one end extending to the outer side of the inclined tube 10 is arranged in the inclined tube 10;

the rotation of the air guide fan 42 drives the airflow inside the shell 1 to flow, so that external air enters the shell 1 from the liquid guide pipe 9 and flows into the shell 1 along the paths of the inclined pipe 10 and the air inlet shell 6, and the moisture absorbing body 11 in the inclined pipe 10 absorbs residual moisture in the air and then enters the shell 1, so that the backflow airflow and the residual moisture in the outside air can be prevented from entering the shell, the inclined pipe 10 is obliquely arranged, and when water is accumulated inside, the water can flow into the liquid guide pipe 9 along the oblique direction of the inclined pipe 10, and a good water blocking effect is realized.

In this embodiment, as shown in fig. 1, 3, 4 and 6, the heat-conducting device further comprises a water accommodating tank 12 which is arranged on the housing 1 and is communicated with the heat exchange cavity, a liquid inlet which is opposite to one end of the liquid guiding pipe 9 is arranged on the water accommodating tank 12, a fixed groove is arranged on the housing 1, a blocking piece 13 for blocking the communication part of the water accommodating tank 12 and the heat exchange cavity is arranged in the fixed groove, a buoyancy piece 14 with one end extending into the water accommodating tank 10 is arranged on the blocking piece 13, and the liquid level of the heat-conducting liquid 32 is positioned below the communication part of the water accommodating tank 12 and the heat exchange cavity and also below the communication part of the air guiding channel 3 and the heat exchange cavity;

the plugging piece 13 comprises a vertical rod 131 arranged in the fixed groove, one end of the vertical rod 131 is provided with a shielding plate 132 for shielding the communication part between the water accommodating tank 12 and the heat exchange cavity, the buoyancy piece 14 comprises a floating plate 141 arranged on the vertical rod 131 and one end of which extends into the water accommodating tank 12, and the floating plate 141 can drive the shielding plate 132 to move upwards along the water level as the water level in the water accommodating tank 12 is continuously increased, so that the communication part between the water accommodating tank 12 and the heat exchange cavity is opened, and water flows back into the heat exchange cavity again to perform the action.

The invention has the beneficial effects that:

the invention improves the heat dissipation mode of the traditional big data processing device, is matched with the use of the heat conducting piece 2 and the air conducting runner 3, realizes the primary heat dissipation of the processing device by the contact heat conduction, enables the heat to be contacted with the heat conducting liquid 23, enables the generated air flow to circulate in the air conducting runner 3, is matched with the use of the air conducting piece 4 and the transmission piece 5, enables the air flow circulated in the air conducting runner 3 to serve as a power source to drive the transmission piece 5 to rotate, synchronously drives the air conducting piece 4 to rotate, enables the air conducting piece 4 to conduct air to the heat dissipation holes of the shell 1, accelerates the air flow velocity in the shell 1, and further realizes the heat dissipation effect of the processing device.

Then the use of liquid guide shell 7, arc drain board 8 and catheter 9 is cooperated, the air current in the air guide runner 3 is got into in the liquid guide shell 7 by the gas vent and is condensed into water with congeal the contact of water board 72, arc drain board 8 prevents that the water of condensation from getting into the gas vent and influencing the discharge of air current, and lead the comdenstion water by catheter 9, and cooperate the use of receiving water tank 12, shutoff piece 13 and buoyancy piece 14, make water store gradually in receiving water tank 12, make the closure and the opening of the shutoff piece 13 to receiving water tank 12 and heat transfer chamber intercommunication department by the transform of liquid level messenger buoyancy piece 14, realize the recycle to water.

Working principle: firstly, the heat absorption table 21 is contacted with a data processing device positioned in a placing cavity to conduct heat, heat is led into the heat conduction liquid 23 by the heat conduction rod 22, the heat is continuously led into the heat conduction liquid 23 to rise in temperature and generate steam, the steam is led into the air conduction flow channel 3 to form air flow, the air flow passes through the guide wheel 52 and drives the guide wheel 52 to rotate, and the annular transmission belt 53 links the rotating rod 41 to rotate along the circumferential direction, so that the fan 42 is driven to rotate to conduct air outwards to the heat dissipation hole of the shell 1, and the heat dissipation operation of the processing device can be completed;

then, the air flow enters the inclined block 71 through the air guide hole communicated with the air guide channel 3 by the inclined block 71, the air flow rises to contact with the condensation plate 72, and the heat conduction column 73 exchanges heat with the outside air, so that water vapor in the air flow is condensed on the condensation plate 72 to form water drops, the water drops on the condensation plate 72 flow into the liquid guide pipe 9 along the inclined edge of the inclined block 71, and fall into the water accommodating tank 12 along the lower end outlet of the liquid guide pipe 9;

wherein, the rotation of the fan 42 drives the airflow in the shell 1 to flow, so that the external air enters the shell 1 through the liquid guide pipe 9 and along the path of the inclined pipe 10 and the air inlet shell 6, and the moisture absorbing body 11 in the inclined pipe 10 absorbs the residual moisture in the air and then enters the shell 1;

finally, as the water drops continuously fall into the water accommodating tank 12, the liquid level in the water accommodating tank 12 gradually rises, the floating plate 141 is driven to rise by the rising of the liquid level, and the floating plate 141 is linked with the vertical rod 131 and the shielding plate 132 to move upwards, so that the communicating position between the water accommodating tank 12 and the heat exchange cavity is opened, and the water in the water accommodating tank 12 flows into the heat exchange cavity again, thereby completing the recovery operation of the liquid.

The embodiments of the present invention are disclosed as preferred embodiments, but not limited thereto, and those skilled in the art will readily appreciate from the foregoing description that various extensions and modifications can be made without departing from the spirit of the present invention.

Claims

1. The utility model provides a high-efficient big data processing apparatus, includes casing (1), its characterized in that, be equipped with in casing (1) and be linked together place chamber and heat transfer chamber, be equipped with in the heat transfer chamber and extend to place heat conduction spare (2) in the intracavity, the outside of casing (1) is equipped with air guide runner (3) with heat transfer chamber intercommunication, the louvre department of casing (1) rotationally is equipped with air guide spare (4), be provided with driving medium (5) in air guide runner (3), the one end of driving medium (5) links to each other and is used for driving air guide spare (4) along circumference rotation with the rotation end of air guide spare (4);

the heat conducting piece (2) comprises a heat absorbing table (21) arranged in the placing cavity, one side of the heat absorbing table (21) is provided with a plurality of heat conducting rods (22) extending into the heat exchanging cavity, and the heat exchanging cavity is filled with heat conducting liquid (23) with liquid level above the extending end of the heat conducting rods (22)

The air inlet shell (6) is communicated with the placing cavity of the shell (1), one end of the air guide channel (3) is communicated with the liquid guide shell (7), an arc-shaped liquid guide plate (8) is arranged at the communication part of the liquid guide shell (7) and the air guide channel (3), a liquid guide pipe (9) is communicated with the liquid guide shell (7), and the air inlet shell (6) is communicated with the liquid guide pipe (9);

the water tank is characterized by further comprising a water containing tank (12) which is arranged on the shell (1) and communicated with the heat exchange cavity, a liquid inlet which is arranged opposite to one end of the liquid guide tube (9) is formed in the water containing tank (12), a fixing groove is formed in the shell (1), a blocking piece (13) used for blocking the position where the water containing tank (12) is communicated with the heat exchange cavity is arranged in the fixing groove, and a buoyancy piece (14) with one end extending into the water containing tank (12) is arranged on the blocking piece (13).

2. A high efficiency big data processing apparatus as defined in claim 1, wherein: the wind guide piece (4) comprises a rotating rod (41) rotatably arranged on the shell (1), and a wind guide fan (42) is arranged on the rotating rod (41).

3. A high efficiency big data processing apparatus as defined in claim 2, wherein: the transmission piece (5) comprises a mounting shell (51) communicated with the air guide channel (3), a guide wheel (52) with one side extending to the outer side of the mounting shell (51) is rotationally arranged in the mounting shell (51), and an annular transmission belt (53) is arranged between the extending end of the guide wheel (52) and the outer side of the rotating rod (41).

4. A high efficiency big data processing apparatus as defined in claim 1, wherein: the utility model discloses a solar cell module, including air guide channel (3), air guide shell (7), including oblique piece (71) that links to each other with air guide channel (3), the hypotenuse of oblique piece (71) links to each other and the intercommunication department is equipped with a plurality of air guide holes with air guide channel (3), arc liquid guide plate (8) are located oblique piece (71) inboard and are located the air guide hole top, an inboard that air guide hole was kept away from to oblique piece (71) is equipped with congeals water board (72), one side of congeals water board (72) is equipped with heat conduction post (73) that a plurality of one ends extend to oblique piece (71) outside.

5. A high efficiency big data processing apparatus according to claim 4, wherein: the bevel edge of the bevel block (71) is communicated with the liquid guide tube (9), and the position of the liquid guide tube (9) communicated with the bevel edge of the bevel block (71) is positioned below the position of the air guide hole.

6. A high efficiency big data processing apparatus according to claim 5, wherein: an inclined tube (10) is communicated between the air inlet shell (6) and the liquid guide tube (9), and a moisture absorption body (11) with one end extending to the outer side of the inclined tube (10) is arranged in the inclined tube (10).

7. A high efficiency big data processing apparatus according to claim 6, wherein: the blocking piece (13) comprises a vertical rod (131) arranged in the fixing groove, one end of the vertical rod (131) is provided with a shielding plate (132) used for shielding the communication part of the water accommodating tank (12) and the heat exchange cavity, and the buoyancy piece (14) comprises a floating plate (141) arranged on the vertical rod (131) and one end of which extends into the water accommodating tank (12).