CN214764293U - Heat dissipation system - Google Patents

Abstract

The utility model discloses a rapid heat dissipation system, which comprises a dust removal box which sucks external air and discharges the air into a closed space, wherein a cathode hairiness net and an anode filter screen are arranged in the dust removal box; after being sucked into the dust removal box, the outside air is discharged from an air outlet of the dust removal box after passing through the cathode hairiness net and the anode filter screen in sequence; and a dust absorption component is also arranged in the dust removal box to absorb dust adsorbed on the anode filter screen. The utility model discloses set up the dust removal case, thereby the air gets into dust removal case back earlier through negative pole hair feather net make the dust in the air electrified, and the air passes through negative pole hair feather net back rethread positive pole filter screen, and electrified dust is adsorbed by the positive pole filter screen this moment to filter out the dust, guarantee to discharge the air in the airtight space and do not contain the dust, improved the reliability of equipment operation in cooling down in to the airtight space.

Description

Heat dissipation system

Technical Field

The utility model relates to a heat dissipation field specifically is a cooling system.

Background

High-accuracy instrument usually moves in airtight space, but often can produce a large amount of heats in the operation process, absorbs external cold air through conventional cooling system and comes to the airtight space heat dissipation, often can bring the dust in the outside air into, and the dust gets into can seriously influence the life of instrument in the high-accuracy instrument, therefore await a urgent need to solve.

Disclosure of Invention

In order to avoid and overcome the technical problem that exists among the prior art, the utility model provides a cooling system. The utility model discloses set up the dust removal case, thereby the air gets into dust removal case back earlier through negative pole hair feather net make the dust in the air electrified, and the air passes through negative pole hair feather net back rethread positive pole filter screen, and electrified dust is adsorbed by the positive pole filter screen this moment to filter out the dust, guarantee to discharge the air in the airtight space and do not contain the dust, improved the reliability of equipment operation in cooling down in to the airtight space.

In order to achieve the above object, the utility model provides a following technical scheme:

a heat dissipation system comprises a dust removal box which sucks external air and discharges the air into a closed space, wherein a cathode hairiness net and an anode filter screen are arranged in the dust removal box; after being sucked into the dust removal box, the outside air is discharged from an air outlet of the dust removal box after passing through the cathode hairiness net and the anode filter screen in sequence; a dust collection assembly is arranged in the dust removal box to absorb dust adsorbed on the anode filter screen;

the dust removal box is also internally provided with a slow flow pipe for reducing the air flow rate, one end of a pipe orifice of the slow flow pipe is connected with an air inlet of the box body, a pipe orifice at the other end of the slow flow pipe is positioned at the front end of the cathode hairiness net and shunted, the shunted pipe orifices are opposite, and the outside air shunted by the slow flow pipe passes through the cathode hairiness net after colliding;

the dust collection assembly discharges dust into a dust storage pipeline after dust collection, a dust collection plate for adsorbing dust is arranged on the inner wall of the dust storage pipeline, and the outlet end of the dust storage pipeline is positioned outside the closed space; the dust collecting device is characterized in that a ventilating net is arranged in the dust storage pipeline, an opening is formed in the pipe wall of the dust storage pipeline, and the dust collecting plate is inserted into the dust storage pipeline from the opening so as to be clamped and fixed by the ventilating net and the pipe wall of the dust storage pipeline.

As a further aspect of the present invention: an anode filter barrel is fixed in the dust removal box, the barrel wall of the anode filter barrel is an anode filter screen, and the anode filter barrel divides the inner cavity of the dust removal box into a cavity to be dedusted and a dust-free cavity.

As a further aspect of the present invention: the dust absorption subassembly includes the dust absorption mouth with anode filters butt, the dust absorption mouth is through its motion of hugging closely anode filters of drive structure drive in order to absorb the absorptive dust on the anode filters net, the dust absorption mouth is linked together through dust absorption pipe and dust exhaust pipe, the gas outlet and the storage dirt pipeline of dust exhaust pipe are linked together.

As a further aspect of the present invention: and a negative pressure structure is fixed in the dust suction nozzle to extract dust adsorbed on the anode filter screen.

As a further aspect of the present invention: the driving structure is a screw rod arranged along the axial direction of the anode filter barrel body, the bracket is fixed on a nut seat of the screw rod, and the dust suction nozzle is arranged on the bracket; an elastic part is arranged on the bracket along the radial direction of the anode filter barrel, one end of the elastic part is fixed on the bracket, and the other end of the elastic part is connected and fixed with the dust suction nozzle; the dust exhaust pipe is rotatably connected with the dust suction pipe.

As a further aspect of the present invention: the dust removal box is fixed in the closed space, and an air inlet of the dust removal box is communicated with the outside through an air inlet pipe; a one-way air outlet used for exhausting air outwards is arranged in the closed space.

As a further aspect of the present invention: the unhurried current pipe includes the air duct, air duct one end is linked together with the air inlet of dust removal case, the other end reposition of redundant personnel of air duct forms two shunt tubes, two the shunt tubes mouth of pipe is relative and lie in same axis, two the orificial axis of shunt tubes all is parallel with negative pole hairiness net screen surface.

As a further aspect of the present invention: the dust storage pipeline is fixed outside the closed space, the pipe body is V-shaped, and the dust collection plate is an activated carbon plate.

As a further aspect of the present invention: the dust storage pipeline is internally provided with the flow buffering plates in a staggered mode, so that gas in the pipeline body forms an S-shaped flow track.

As a further aspect of the present invention: one end of the slow flow plate is fixed on the net wall of the breathable net, and the other end of the slow flow plate is bent towards the outflow direction of air to form a flow guide section parallel to the pipe wall.

Compared with the prior art, the beneficial effects of the utility model are that:

1. the utility model discloses set up the dust removal case in airtight space, thereby the air gets into dust removal case back earlier through negative pole hair feather net make the dust in the air electrified, the air passes through negative pole hair feather net back rethread positive pole filter screen, and electrified dust is adsorbed by the positive pole filter screen this moment to filter out the dust, guarantee to discharge the air in the airtight space and do not contain the dust, improved the reliability of equipment operation when cooling down in to airtight space.

2. The utility model discloses a set up the positive pole lauter tub and separate the dust removal incasement chamber for treating dust removal chamber and dustless chamber, the air is behind the negative pole hairiness net through treating the dust removal intracavity, and the dust in the air is adsorbed with the electron and is taken on the negative electricity together, can adsorb the dust after the positive electricity is led to the positive pole lauter tub. Through set up the dust absorption mouth in the dust removal case, make the positive pole filter screen butt of dust absorption mouth and positive pole lauter tub bucket wall, can inhale the absorptive dust on the positive pole filter screen when drive dust absorption mouth motion, can discharge outside the airtight space through the dust exhaust pipe after the absorption is accomplished.

3. The utility model arranges the screw rod in the dust removing box, fixes the dust suction nozzle on the bracket, drives the bracket and the dust suction nozzle to spirally lift while the screw rod rotates, thereby absorbing the dust on the wall of the anode filter barrel, and the dust absorbing rate is high; the elastic piece on the bracket is arranged, so that the dust suction nozzle can be always abutted against the anode filter screen, and the maximization of the suction force of the dust suction nozzle is ensured; the closed space exhausts air outwards through the one-way air outlet, and the balance of pressure intensity in the closed space can be guaranteed while heat is dissipated.

4. The utility model discloses set up the unhurried current pipe between the air inlet of dust removal case and negative pole hairiness net, the air duct of unhurried current pipe is linked together with the air inlet of dust removal case, and the air duct mouth of pipe reposition of redundant personnel forms the shunt tubes, the shunt tubes mouth of pipe sets up relatively, make the air that gets into the dust removal incasement pass through behind the shunt tubes, the reposition of redundant personnel collides, thereby the velocity of flow of air has been reduced, make the air can slowly pass through the electron fog region that negative pole hairiness net produced, make the dust can fully combine with the electron, improve the adsorption efficiency of follow-up positive pole lauter tub to the dust.

5. The utility model arranges a dust storage pipeline outside the closed space to be communicated with the dust discharge pipe, and after the air mixed with dust enters the dust storage pipeline, the dust suction plate in the dust storage pipeline adsorbs the dust to prevent the dust from directly discharging polluted air outwards; the dust collection plate is clamped and fixed through the ventilation net and the pipe wall of the dust storage pipeline, and the dust collection plate is inserted into the dust storage pipeline through the opening on the dust storage pipeline, so that the dust collection plate is convenient to assemble and disassemble, and after the heat dissipation process is finished, the dust collection plate can be drawn out of the dust storage pipeline in time and replaced; the baffles in the dust storage pipeline are arranged in a staggered manner, so that gas passing through the dust storage pipeline forms an S-shaped flow track, the side length of the contact time between dust and a dust collection plate is long, and the adsorption rate of the dust is improved; meanwhile, the plate end of the flow buffering plate is bent towards the air outflow direction to form a flow guide section parallel to the pipe wall, when air passes through the flow guide section, the air is in full contact with the dust collection plate due to the narrow flow guide section and the narrow pipe wall, so that the dust adsorption rate is improved, the flow guide section also has a flow equalizing effect, and the noise generated when the air in the dust storage pipeline flows is reduced; the V-shaped design of the pipe body also increases the flow path of air in a limited installation space.

Drawings

Fig. 1 is a schematic structural diagram of the present invention.

Fig. 2 is a schematic structural view of the slow flow tube of the present invention.

Fig. 3 is a top view of the dust suction assembly of the present invention.

Fig. 4 is a schematic structural view of the dust suction assembly of the present invention.

Fig. 5 is a schematic structural view of the middle dust storage pipeline of the present invention.

Fig. 6 is an enlarged view of a portion a in fig. 5.

Fig. 7 is a front view of the pipe orifice of the dust storage pipe.

In the figure: 1. an air inlet pipe; 2. a dust removal box; 3. a cathode hairiness net; 4. an anode filter barrel; 5. a dust collection assembly; 6. a dust exhaust pipe; 7. a slow flow pipe; 8. a dust storage pipeline; 51. a support; 52. a screw rod; 53. a dust collection pipe; 54. a dust suction nozzle; 71. an air duct; 72. a shunt tube; 81. a breathable net; 82. an activated carbon plate; 83. a flow buffering plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-7, in an embodiment of the present invention, a heat dissipation system includes a dust removal box 2 fixed in an enclosed space, the dust removal box 2 sucks air outside the enclosed space, and discharges the air into the enclosed space to thereby play a cooling effect on the enclosed space. Usually, an air inlet pipe 1 is fixed at an air inlet of the dust removal box 2, the air inlet pipe 1 is communicated with the outside, and an air suction pump is additionally arranged in the air inlet pipe 1 to play a role in air suction. The dust removal box 2 is fixed outside the closed space, a pipeline is additionally arranged at an air outlet of the dust removal box 2, and the pipeline is communicated with the inside of the closed space, so that the heat dissipation function can be realized.

A cathode filter screen 3 and an anode filter barrel 4 are arranged in the dust removing box 2, the anode filter barrel 4 divides the inner cavity of the dust removing box 2 into a cavity to be removed with dust and a dust-free cavity, and the cathode filter screen 3 is fixed in the cavity to be removed with dust. The cathode filter 3 is preferably fixed at the air inlet of the dust box 2.

After entering the dust removing box 2, the outside air firstly passes through the cathode filter screen 3. The cathode filter screen 3 forms hairiness by spinning conductive fibers, the hairiness is used as an emitter after being woven into a net, and cold-emitted electrons form electron mist. After the outside air passes through the electron fog generated by the cathode filter screen 3, dust in the air and electrons are adsorbed together and are negatively charged. The wall of the anode filter barrel 4 is an anode filter screen which is positively charged, and when the outside air is mixed with negatively charged dust and passes through the anode filter barrel 4, the dust is adsorbed on the anode filter screen. The outside air becomes dustless after passing through the anode filter screen, and is discharged into the closed space from the air outlet of the dust removal box 2, so that the temperature of the closed space is reduced.

In order to prevent the anode filter barrel 4 from being excessively dusty, a dust suction assembly 5 is usually arranged in the barrel to suck dust on the barrel wall. The dust suction assembly 5 is preferably a dust suction nozzle 54, and the dust suction nozzle 54 can be spirally lifted along with the bracket 51 by arranging the screw rod 52 in the anode filter barrel 4 along the axial direction of the barrel body, fixing the bracket 51 on the nut of the screw rod 52, and starting the screw rod 52 after the dust suction nozzle 54 is fixed on the bracket 51, so that dust adsorbed in the anode filter barrel 4 can be sucked completely.

The anode filter screen on the wall of the anode filter barrel 4 is of a double-layer structure, the inner layer of the anode filter screen is a metal power grid, the outer layer of the anode filter screen is a breathable filter screen, and the two layers of structures are tightly attached together. In order to improve the adsorption effect of the dust suction nozzle 54, an elastic member is arranged on the bracket 51 along the radial direction of the anode filter barrel 4, one end of the elastic member is fixed on the bracket 51, and the other end of the elastic member is connected and fixed with the dust suction nozzle 54. Under the elastic action of the elastic piece, the dust suction nozzle 54 is always abutted against the anode filter screen, and after a negative pressure structure is arranged in the dust suction nozzle 54, the maximum suction force can be ensured during dust suction. The resilient member is preferably a compression spring here. The negative pressure mechanism can be any negative pressure fan, such as a TWYX full wind negative pressure fan.

A dust exhaust pipe 6 is arranged in the dust box 2, a dust suction pipe 53 is arranged on the dust suction nozzle 54, and the dust suction pipe 53 is rotatably connected with the dust exhaust pipe 6. After the dust is sucked by the dust suction nozzle 54, the dust passes through the dust suction pipe 53 and the dust exhaust pipe 6 in order and is discharged to the outside of the closed space. In order to ensure the normal relative rotation between the dust suction pipe 53 and the dust exhaust pipe 6, a bearing bracket is usually fixed in the dust box 2, and a bearing is fixed on the bearing bracket, so that the dust suction pipe 53 and the dust exhaust pipe 6 are connected through the bearing, and the dust exhaust pipe 6 is ensured to be stationary and the dust suction pipe 53 rotates together with the dust suction nozzle 54 in the working process.

The arrangement of the anode filter barrel 4 is only a preferred embodiment, and the anode filter screen with any shape is arranged in the dust removing box 2 for the external air to pass through, and the dust suction assembly 5 with any working mode is arranged for performing dust suction treatment on the anode filter screen. For example, an anode filter screen is fixed at the air outlet of the dust removing box 2, and a strip-shaped dust collector which rotates around the center of the screen surface is arranged on the anode filter screen, so that the function of filtering dust can be realized.

The space between the anode filter barrel 4 and the dust removal box 2 is a dust-free cavity, and after air passing through the anode filter barrel 4 enters the dust-free cavity, the air enters the closed space from the air outlet of the dust removal box 2. In order to balance the pressure intensity in the closed air, a one-way air outlet is arranged in the closed space to discharge air outwards.

The temperature sensor is arranged in the closed space, and transmits a signal to the heat dissipation system after sensing that the temperature in the closed space reaches a set temperature, and the heat dissipation system is started to extract outside air and convey the outside air into the closed space. And closing the heat dissipation system until the temperature in the closed space is reduced to be below the set temperature or the heat dissipation system is started for a specified time.

After air is pumped into the dust removal box 2, the air flow rate is too high, so that when the air passes through the cathode hairiness net 3, part of dust particles in the air pass through an electron fog area generated by the cathode hairiness net 3 without being combined with electrons due to the too high speed, and the part of dust particles cannot be effectively adsorbed by the anode filter barrel 4, so that the adsorption efficiency of the anode filter barrel is reduced. Therefore, a draft tube 7 is additionally arranged between the air inlet of the dust removing box 2 and the cathode hairiness net 3.

The slow flow pipe 7 comprises an air duct 71 communicated with an air inlet of the dust removal box 2, the other end of the orifice of the slow flow pipe 7 is divided into two flow dividing pipes 72, the orifices of the two flow dividing pipes 72 are opposite, the orifices have the same size and are positioned on the same axis, and the axes of the orifices of the two flow dividing pipes 72 are parallel to the screen surface of the cathode hairiness screen 3. After the outside air enters the air duct 71 from the dust removing box 2, the outside air is divided into two flow dividing pipes 72, when the outside air flows out of the two flow dividing pipes 72, the air flow rate is reduced to the maximum extent by the collision of two air flows, and the decelerated air slowly passes through an electron fog area, so that the proportion of combining dust and electrons is improved. The number of the shunt tubes 72 is not limited, and the deceleration function can also be realized by arranging a plurality of shunt tubes to enable a plurality of air strands to collide. The shunt tubes are not arranged right opposite to each other, but an included angle is formed between the shunt tubes, so that air is collided to achieve the effect of speed reduction.

In order to prevent the air directly discharged from the dust exhaust pipe 6 from being mixed with a large amount of dust to pollute the outside air, a dust storage pipeline 8 is additionally arranged at the air outlet of the dust exhaust pipe. The inner wall of the dust storage line 8 is provided with a suction plate for sucking dust, which is preferably an activated carbon plate 82. In order to facilitate the detachment and fixation of the dust collection plate, the inner wall of the dust storage pipeline 8 is fixed with the air permeable net 81, the pipe wall of the dust storage pipeline 8 is provided with an opening, and the dust collection plate is inserted into the dust storage pipeline 8 from the opening and can be clamped and fixed by the air permeable net 81 and the pipe wall of the dust storage pipeline 8. The air outlet of the dust storage pipeline 8 is positioned outside the closed space, and when air with dust passes through the dust storage pipeline 8, the dust passes through the breathable net 81 and is adsorbed by the dust collection plate, so that the dust content in the air discharged outside the closed space is greatly reduced. After the heat dissipation process is finished, the dust suction plate can be drawn out from the dust storage pipeline 8 in time and replaced.

The inner wall of the dust storage pipeline 8 is also provided with baffle plates 83 in a staggered manner, and the baffle plates 83 are arranged in a staggered manner, so that the gas passing through the dust storage pipeline 8 forms an S-shaped flow track. Due to the increased flow trajectory, the dust adsorption rate is simultaneously increased. One end of the flow buffering plate 83 is fixed on the net wall of the breathable net 81, the other end of the flow buffering plate is bent towards the air outflow direction to form a flow guide section parallel to the pipe wall, when the air passes through the flow guide section, the contact proportion of the air and the dust collection plate is increased, the dust collection effect is improved, meanwhile, the flow guide section also has the flow equalizing effect, and the noise generated when the air flows in the dust storage pipeline 8 is reduced. By designing the pipe body of the dust removal pipeline 8 into a V shape, the flow path length of air is increased in a limited installation space.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (10)

1. A heat dissipation system is characterized by comprising a dust removal box (2) which sucks outside air and discharges the outside air into a closed space, wherein a cathode hairiness net (3) and an anode filter screen are arranged in the dust removal box (2); after being sucked into the dust removal box (2), the outside air is discharged from an air outlet of the dust removal box (2) after passing through the cathode hairiness net (3) and the anode filter screen in sequence; a dust collection assembly (5) is also arranged in the dust removal box (2) to absorb dust adsorbed on the anode filter screen;

a slow flow pipe (7) used for reducing the air flow rate is further arranged in the dust removal box (2), one end of a pipe orifice of the slow flow pipe (7) is connected with an air inlet of the box body, a pipe orifice at the other end of the slow flow pipe (7) is positioned at the front end of the cathode hairiness net (3) and shunted, the shunted pipe orifices are opposite, and outside air shunted by the slow flow pipe (7) collides and then passes through the cathode hairiness net (3);

the dust collection assembly (5) discharges dust into a dust storage pipeline (8) after dust collection, a dust collection plate for adsorbing dust is arranged on the inner wall of the dust storage pipeline (8), and the outlet end of the dust storage pipeline (8) is positioned outside the closed space; the dust collecting device is characterized in that a ventilating net (81) is arranged in the dust storage pipeline (8), an opening is formed in the pipe wall of the dust storage pipeline (8), and the dust collecting plate is inserted into the dust storage pipeline (8) from the opening so as to be clamped and fixed by the ventilating net (81) and the pipe wall of the dust storage pipeline (8).

2. The heat dissipation system according to claim 1, wherein an anode filter barrel (4) is fixed in the dust removal box (2), a barrel wall of the anode filter barrel (4) is an anode filter screen, and the anode filter barrel (4) divides an inner cavity of the dust removal box (2) into a cavity to be cleaned and a dust-free cavity.

3. The heat dissipation system according to claim 2, wherein the dust collection assembly (5) comprises a dust collection nozzle (54) abutted against the anode filter screen, the dust collection nozzle (54) is driven by a driving structure to move close to the anode filter screen so as to collect dust adsorbed on the anode filter screen, the dust collection nozzle (54) is communicated with the dust discharge pipe (6) through a dust collection pipe (53), and an air outlet of the dust discharge pipe (6) is communicated with the dust storage pipeline (8).

4. A heat removal system according to claim 3, characterised in that a negative pressure structure is fixed in the suction nozzle (54) for extracting dust adsorbed on the anode filter mesh.

5. A heat-dissipating system according to claim 3, wherein the driving structure is a screw rod (52) arranged along the axial direction of the body of the anode filter barrel (4), the bracket (51) is fixed on a nut seat of the screw rod (52), and the dust suction nozzle (54) is installed on the bracket (51); an elastic part is arranged on the support (51) along the radial direction of the anode filter barrel (4), one end of the elastic part is fixed on the support (51), and the other end of the elastic part is connected and fixed with a dust suction nozzle (54); the dust exhaust pipe (6) is rotatably connected with the dust suction pipe (53).

6. The heat dissipation system according to claim 5, wherein the dust removal box (2) is fixed in the closed space, and an air inlet of the dust removal box (2) is communicated with the outside through an air inlet pipe (1); a one-way air outlet used for exhausting air outwards is arranged in the closed space.

7. The heat dissipation system according to any one of claims 1 to 6, wherein the slow flow pipe (7) comprises an air duct (71), one end of the air duct (71) is communicated with an air inlet of the dust removal box (2), the other end of the air duct (71) is divided into two flow dividing pipes (72), pipe openings of the two flow dividing pipes (72) are opposite and located on the same axis, and axes of the pipe openings of the two flow dividing pipes (72) are parallel to the net surface of the cathode hairiness net (3).

8. The heat dissipation system of any one of claims 1 to 6, wherein the dust storage pipeline (8) is fixed outside the enclosed space and has a V-shaped pipe body, and the dust collection plate is an activated carbon plate (82).

9. A heat dissipation system according to any one of claims 1-6, wherein the dust storage pipeline (8) is provided with baffles (83) in a staggered manner, so that the gas in the pipeline forms an S-shaped flow track.

10. A heat-dissipating system according to claim 9, wherein the flow-slowing plate (83) is fixed at one end to the wall of the air-permeable net (81) and at the other end bent in the air outflow direction to form a flow-guiding section parallel to the wall of the pipe.

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