CN114355708A - Image acquisition instrument with efficient heat dissipation function for epidemic prevention and control - Google Patents

Abstract

The invention relates to an image acquisition instrument with high-efficiency heat dissipation function for epidemic prevention and control, which comprises a main body, a bracket, a heat dissipation mechanism and a cooling mechanism, wherein the main body is arranged on the bracket, the heat dissipation mechanism is arranged on the main body, the cooling mechanism is arranged on the heat dissipation mechanism, the heat dissipation mechanism comprises a heat dissipation component and a water cooling component, the cooling mechanism comprises a cooling box and a condensation needle, the cooling box is provided with a cooling unit, the cooling unit is provided with a rotating unit, the cooling box is internally provided with a circulating unit, the image acquisition instrument with high-efficiency heat dissipation function for epidemic prevention and control is monitored by the main body, the image acquisition instrument performs multiple heat dissipation on the main body through air cooling, water cooling and heat dissipation fins, realizes better heat dissipation effect, cools and recycles water vapor through the cooling mechanism, saves water resources, and the cooling mechanism performs double cooling on the water vapor through the condensation needle and flowing cooling liquid, and a better cooling effect is realized, so that a better water cooling effect is realized.

Description

Image acquisition instrument with efficient heat dissipation function for epidemic prevention and control

Technical Field

The invention relates to an image acquisition instrument with a high-efficiency heat dissipation function for epidemic prevention and control.

Background

Current image acquisition instrument is when using, can produce a large amount of heats, and current image acquisition instrument generally does not set up better heat abstractor, when the high temperature, will cause image acquisition instrument life to reduce, current image acquisition instrument that has the heat dissipation function simultaneously, it is generally comparatively simple that its heat dissipation mechanism set up, the radiating effect is not good, current heat dissipation mechanism generally adopts water-cooling or forced air cooling to dispel the heat simultaneously, adopt water-cooling radiating's mode, its water does not generally have better recovery and cyclic utilization, cause the waste of water resource.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: in order to overcome the defects of the prior art, the image acquisition instrument with the efficient heat dissipation function for epidemic prevention and control is provided.

The technical scheme adopted by the invention for solving the technical problems is as follows: an image acquisition instrument with a high-efficiency heat dissipation function for epidemic situation prevention and control comprises a main body, a support, a heat dissipation mechanism and a cooling mechanism, wherein the main body is arranged on the support;

the heat dissipation mechanism comprises a heat dissipation assembly and a water cooling assembly, the heat dissipation assembly comprises a plurality of heat dissipation fins, each heat dissipation fin is uniformly arranged along the axis direction of the main body, the water cooling assembly comprises a shell, a water tank, an atomizing spray head, a driving unit, a moving unit and a pushing unit, the shell is arranged on the main body, the heat dissipation fins extend into the shell, the driving unit comprises a motor and a driving shaft, the motor is horizontally arranged in the shell, the driving shaft is mounted on the motor, the moving unit comprises a rotating rod, a moving rod and a moving wheel, the rotating rod is arranged on the driving shaft, one end of the rotating rod is connected with the driving shaft, the moving wheel is arranged at one end of the moving rod far away from the driving shaft, the moving rod is arranged in the shell, a sliding groove is arranged in the shell, the end part of the moving rod is positioned in the sliding groove, and the moving rod is connected with the sliding groove in a sliding manner, the movable rod is provided with a strip-shaped groove, the movable wheel is positioned in the strip-shaped groove, the movable wheel is in rolling connection with the strip-shaped groove, the number of the pushing units is two, the two pushing units are respectively arranged at two sides of the movable rod, each pushing unit comprises a sleeve, a piston rod, a first spring, a first connecting pipe and a second connecting pipe, the sleeves are arranged in the shell, one end of each piston rod is positioned in the corresponding sleeve, the other end of each piston rod extends out of the corresponding sleeve and is abutted against the movable rod, a piston of each piston rod is in sealing connection with the corresponding sleeve, the first spring is arranged in the corresponding sleeve, one end of the first spring is connected with the piston of the corresponding piston rod, the other end of the first spring is connected with the corresponding sleeve, the first connecting pipe and the second connecting pipe are both arranged at the tops of the sleeves, the first connecting pipe and the second connecting pipe are both communicated with the insides of the sleeves, and the water tank is arranged on the shell, one of the sleeves is communicated with the inside of the water tank through a first connecting pipe connected with the sleeve, the other sleeve is communicated with the inside of the shell through another first connecting pipe, the atomizing nozzle is arranged on a second connecting pipe on the sleeve communicated with the water tank, and the atomizing nozzle is communicated with the inside of the sleeve through the second connecting pipe;

the cooling mechanism comprises a cooling box and a condensation needle, the cooling box is arranged on the shell, a sleeve communicated with the inside of the shell is communicated with the inside of the cooling box through a second connecting pipe connected with the sleeve, and the condensation needle is arranged at the top of the cooling box.

In order to realize better cooling effect, be equipped with the cooling unit on the cooler bin, the cooling unit includes box, fixed pipe, seal block, second spring, inlet tube and cooling tube, the cooling tube sets up in the cooler bin, the cooling tube spirals the setting, box and fixed pipe all set up on the cooler bin, seal block sets up in the fixed pipe, seal block and fixed pipe sealing connection, the second spring sets up in the fixed pipe, the one end and the seal block of second spring are connected, the other end and the fixed union coupling of second spring, inlet tube and cooling tube all set up at fixed tub of top, fixed pipe passes through inlet tube and the inside intercommunication of box, the box passes through the cooling tube and the inside intercommunication of fixed pipe.

In order to drive the operation of cooling unit, be equipped with the rotation unit on the cooling unit, the rotation unit includes fan, pivot, semi-gear and rack, the pivot sets up on the cooler bin, the fan cover is established in the pivot, fan and pivot key-type connection, the fan is located the second connecting pipe under, the semi-gear cover is established in the pivot, semi-gear and pivot key-type connection, the rack sets up on sealed piece, rack and semi-gear meshing.

In order to save the water resource, be equipped with the circulation unit in the cooler bin, the circulation unit includes water pump, drain pipe and level sensor, the water pump sets up in the cooler bin, the drain pipe sets up on the water tank, the water tank passes through drain pipe and water pump and the inside intercommunication of cooler bin, level sensor sets up in the cooler bin.

In order to support the device, the support comprises a base and a supporting rod, the supporting rod is arranged on the base, and the main body is arranged on the supporting rod.

In order to enable air or water to enter the sleeve only through the first connecting pipe and then to be discharged through the second connecting pipe, a one-way valve is arranged at the joint of the first connecting pipe and the sleeve, and a one-way valve is arranged at the joint of the second connecting pipe and the sleeve.

In order to enable the cooling liquid to enter the fixed pipe only through the liquid inlet pipe and then to be discharged through the liquid outlet pipe, a one-way valve is arranged at the joint of the liquid inlet pipe and the fixed pipe, and a one-way valve is arranged at the joint of the cooling pipe and the fixed pipe.

The atomizer has a plurality of, and each atomizer corresponds the setting with each radiating fin respectively.

In order to achieve a better heat dissipation effect, a fan is arranged on the driving shaft, and the fan and the heat dissipation fins are arranged just opposite to each other.

The image acquisition instrument with the efficient heat dissipation function for epidemic situation prevention and control has the advantages that the monitoring is realized through the main body, the heat generated during the operation of the main body is dissipated through the heat dissipation mechanism, and the water vapor generated by the heat dissipation mechanism is cooled through the cooling mechanism.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic structural diagram of an image acquisition instrument with a high-efficiency heat dissipation function for epidemic prevention and control according to the present invention;

FIG. 2 is a schematic structural diagram of a heat dissipation mechanism of the image acquisition instrument with high-efficiency heat dissipation function for epidemic prevention and control according to the present invention;

FIG. 3 is a schematic structural diagram of a water cooling assembly of the image acquisition instrument with high-efficiency heat dissipation function for epidemic prevention and control according to the present invention;

FIG. 4 is a schematic view of a connection structure of a cooling mechanism, a cooling unit, a rotating unit and a circulating unit of the image acquisition instrument with high-efficiency heat dissipation function for epidemic prevention and control of the present invention;

in the figure: 1. the cooling device comprises a main body, 2. heat dissipation fins, 3. a shell, 4. a water tank, 5. an atomizing spray head, 6. a motor, 7. a driving shaft, 8. a rotating rod, 9. a moving rod, 10. a moving wheel, 11. a sleeve, 12. a piston rod, 13. a first spring, 14. a first connecting pipe, 15. a second connecting pipe, 16. a cooling tank, 17. a condensation needle, 18. a box body, 19. a fixed pipe, 20. a sealing block, 21. a second spring, 22. a liquid inlet pipe, 23. a cooling pipe, 24. a fan, 25. a rotating shaft, 26. a half gear, 27. a rack, 28. a water pump, 29. a water outlet pipe, 30. a water level sensor, 31. a base and 32. a supporting rod.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.

As shown in fig. 1, an image acquisition instrument with a high-efficiency heat dissipation function for epidemic prevention and control comprises a main body 1, a support, a heat dissipation mechanism and a cooling mechanism, wherein the main body 1 is arranged on the support, the heat dissipation mechanism is arranged on the main body 1, and the cooling mechanism is arranged on the heat dissipation mechanism;

when the device uses, realize the control through main part 1, dispel the heat through the heat that the heat dissipation mechanism produced during to main part 1 operation, cool off the steam that the heat dissipation mechanism produced through cooling body.

As shown in fig. 2-3, the heat dissipation mechanism includes a heat dissipation assembly and a water cooling assembly, the heat dissipation assembly includes a plurality of heat dissipation fins 2, each heat dissipation fin 2 is arranged along the axis direction of the main body 1, the water cooling assembly includes a housing 3, a water tank 4, an atomizer 5, a driving unit, a moving unit and a pushing unit, the housing 3 is disposed on the main body 1, the heat dissipation fins 2 extend into the housing 3, the driving unit includes a motor 6 and a driving shaft 7, the motor 6 is horizontally disposed in the housing 3, the driving shaft 7 is mounted on the motor 6, the moving unit includes a rotating rod 8, a moving rod 9 and a moving wheel 10, the rotating rod 8 is disposed on the driving shaft 7, one end of the rotating rod 8 is connected with the driving shaft 7, the moving wheel 10 is disposed at one end of the moving rod 9 far away from the driving shaft 7, the moving rod 9 is disposed in the housing 3, the improved structure of the hydraulic oil cylinder is characterized in that a sliding groove is formed in the shell 3, the end portion of the moving rod 9 is located in the sliding groove, the moving rod 9 is in sliding connection with the sliding groove, a strip-shaped groove is formed in the moving rod 9, the moving wheel 10 is located in the strip-shaped groove, the moving wheel 10 is in rolling connection with the strip-shaped groove, the number of the pushing units is two, the two pushing units are respectively arranged on two sides of the moving rod 9, each pushing unit comprises a sleeve 11, a piston rod 12, a first spring 13, a first connecting pipe 14 and a second connecting pipe 15, the sleeve 11 is arranged in the shell 3, one end of the piston rod 12 is located in the sleeve 11, the other end of the piston rod 12 extends out of the sleeve 11 and abuts against the moving rod 9, a piston of the piston rod 12 is in sealing connection with the sleeve 11, the first spring 13 is arranged in the sleeve 11, one end of the first spring 13 is connected with the piston of the piston rod 12, and the other end of the first spring 13 is connected with the sleeve 11, the first connecting pipe 14 and the second connecting pipe 15 are both arranged at the top of the sleeve 11, the first connecting pipe 14 and the second connecting pipe 15 are both communicated with the inside of the sleeve 11, the water tank 4 is arranged on the shell 3, one sleeve 11 is communicated with the inside of the water tank 4 through the first connecting pipe 14 connected with the sleeve 11, the other sleeve 11 is communicated with the inside of the shell 3 through the other first connecting pipe 14, the atomizing nozzle 5 is arranged on the second connecting pipe 15 on the sleeve 11 communicated with the water tank 4, and the atomizing nozzle 5 is communicated with the inside of the sleeve 11 through the second connecting pipe 15;

the heat generated when the main body 1 operates is transferred to each radiating fin 2, the contact area with the air is increased through each radiating fin 2, thereby the heat exchange speed with the air is accelerated, thereby a better radiating effect is realized, the motor 6 is operated, the motor 6 drives the driving shaft 7 to rotate, the driving shaft 7 drives the fan 24 to rotate, the fan 24 accelerates the air flow speed, thereby the better radiating effect is realized, the driving shaft 7 rotates to drive the rotating rod 8 to rotate, the rotating rod 8 drives the moving wheel 10 to move, the moving track of the moving wheel 10 is circular, the circle center is positioned on the axis of the driving shaft 7, the radius is the length of the rotating rod 8, thereby the moving wheel 10 generates distance change left and right, thereby the moving rod 9 reciprocates left and right, when the moving rod 9 moves towards one side, the moving rod 9 pushes the piston rod 12 in the moving direction to move, thereby the space of the sealed cavity formed by the piston rod 12 and the sleeve 11 is reduced, so that the water in the sealed cavity is pressed into the second connecting pipe 15 and then sprayed out through each atomizer 5 on the second connecting pipe 15, so that the water vapor absorbs the heat on the heat radiating fins 2, thereby achieving a better heat radiating effect, when the moving rod 9 moves reversely, the piston rod 12 is not blocked, under the action of the restoring force of the first spring 13, the first spring 13 drives the piston rod 12 to move reversely, thereby increasing the space of the sealed cavity, thereby causing the water in the water tank 4 to flow into the sealed cavity through the first connecting pipe 14 for replenishment, when the moving rod 9 moves towards the other side, the moving rod 9 drives the other piston rod 12 to move, the other piston rod 12 drives the hot water vapor in the other sleeve 11 to be pressed into the cooling tank 16 through the second connecting pipe 15, when the moving rod 9 moves reversely, the restoring force of the first spring 13 pushes the piston rod 12 to move reversely again, so that the hot water vapor in the case 3 is introduced into the sleeve 11 through the first connection pipe 14.

As shown in fig. 4, the cooling mechanism includes a cooling tank 16 and a condensation pin 17, the cooling tank 16 is disposed on the housing 3, the sleeve 11 communicating with the inside of the housing 3 communicates with the inside of the cooling tank 16 through a second connection pipe 15 connected thereto, and the condensation pin 17 is disposed on the top of the cooling tank 16.

The hot water vapor introduced into the cooling tank 16 is cooled by the condensation pins 17.

As shown in fig. 4, in order to achieve better cooling effect, the cooling box 16 is provided with a cooling unit, the cooling unit comprises a box body 18, a fixed pipe 19, a sealing block 20, a second spring 21, a liquid inlet pipe 22 and a cooling pipe 23, the cooling pipe 23 is arranged in the cooling box 16, the cooling pipe 23 is spirally arranged, the box body 18 and the fixed pipe 19 are both arranged on the cooling box 16, the sealing block 20 is arranged in the fixed pipe 19, the sealing block 20 is connected with the fixed pipe 19 in a sealing way, the second spring 21 is disposed in the fixed tube 19, one end of the second spring 21 is connected with the sealing block 20, the other end of the second spring 21 is connected with the fixed pipe 19, the liquid inlet pipe 22 and the cooling pipe 23 are both arranged on the top of the fixed pipe 19, the fixed pipe 19 communicates with the inside of the case 18 through a liquid inlet pipe 22, and the case 18 communicates with the inside of the fixed pipe 19 through a cooling pipe 23.

The hot water steam sprayed out of the second connecting pipe 15 drives the fan 24 to rotate, the fan 24 drives the rotating shaft 25 to rotate, the rotating shaft 25 drives the half gear 26 to rotate, when the half gear 26 is meshed with the rack 27, the half gear 26 drives the rack 27 to move, the rack 27 drives the sealing block 20 to move, so that the space of the sealing cavity formed by the sealing block 20 and the fixed pipe 19 is increased, so that the air pressure in the sealing cavity is reduced, so that the external atmospheric pressure presses the cooling liquid in the box body 18 into the sealing cavity through the liquid inlet pipe 22, when the half gear 26 is not meshed with the rack 27, the second spring 21 is in a deformation state, the restoring force of the second spring 21 generates reverse thrust on the sealing block 20, so that the sealing block 20 moves reversely, so that the cooling liquid in the sealing cavity is pressed into the cooling pipe 23, the cooling liquid absorbs heat on the cooling pipe 23, and then flows along with the cooling liquid, the heat is taken away, so that a better water vapor cooling effect is realized.

In order to drive the operation of cooling unit, be equipped with the rotation unit on the cooling unit, the rotation unit includes fan 24, pivot 25, semi-gear 26 and rack 27, pivot 25 sets up on cooler bin 16, fan 24 cover is established on pivot 25, fan 24 and 25 key-type connections of pivot, fan 24 is located second connecting pipe 15 under, semi-gear 26 cover is established on pivot 25, semi-gear 26 and 25 key-type connections of pivot, rack 27 sets up on sealed block 20, rack 27 and semi-gear 26 mesh.

As shown in fig. 4, in order to save water resources, a circulation unit is provided in the cooling tank 16, the circulation unit includes a water pump 28, a drain pipe 29 and a water level sensor 30, the water pump 28 is provided in the cooling tank 16, the drain pipe 29 is provided on the water tank 4, the water tank 4 is communicated with the inside of the cooling tank 16 through the drain pipe 29 and the water pump 28, and the water level sensor 30 is provided in the cooling tank 16.

Along with the increase of water in the cooling tank 16, when the water level is located at the water level sensor 30, the water level sensor 30 sends an electric signal to the PLC, the PLC controls the water pump 28 to operate, and the water pump 28 discharges the water in the cooling tank 16 into the water tank 4 through the drain pipe 29, so that the water is recycled, and water resources are saved.

For supporting the device, the stand comprises a base 31 and a support bar 32, the support bar 32 is arranged on the base 31, and the main body 1 is arranged on the support bar 32.

In order to enable air or water to enter the sleeve 11 only through the first connecting pipe 14 and then to be discharged through the second connecting pipe 15, a one-way valve is arranged at the joint of the first connecting pipe 14 and the sleeve 11, and a one-way valve is arranged at the joint of the second connecting pipe 15 and the sleeve 11.

In order to enable the cooling liquid to enter the fixed pipe 19 only through the liquid inlet pipe 22 and then to be discharged through the liquid outlet pipe, a check valve is arranged at the joint of the liquid inlet pipe 22 and the fixed pipe 19, and a check valve is arranged at the joint of the cooling pipe 23 and the fixed pipe 19.

The atomizing spray heads 5 are provided with a plurality of atomizing spray heads 5, and each atomizing spray head 5 is arranged corresponding to each radiating fin 2.

In order to achieve a better heat dissipation effect, the driving shaft 7 is provided with a fan 24, and the fan 24 is arranged opposite to the heat dissipation fins 2.

When the device is used, monitoring is realized through the main body 1, heat generated when the main body 1 operates is transmitted to each radiating fin 2, the contact area with air is increased through each radiating fin 2, so that the heat exchange speed with the air is accelerated, and a better radiating effect is realized, the motor 6 is operated, the motor 6 drives the driving shaft 7 to rotate, the driving shaft 7 drives the fan 24 to rotate, the fan 24 accelerates the air flow speed, so that the better radiating effect is realized, the driving shaft 7 drives the rotating rod 8 to rotate, the rotating rod 8 drives the moving wheel 10 to move, the moving track of the moving wheel 10 is circular, the circle center of the moving wheel is positioned on the axis of the driving shaft 24, the radius is the length of the rotating rod 8, so that the moving wheel 10 generates distance change from left to right, so that the moving rod 9 reciprocates from left to right, when the moving rod 9 moves towards one side, the moving rod 9 pushes the piston rod 12 in the moving direction to move, thereby reducing the space of the sealed cavity formed by the piston rod 12 and the sleeve 11, allowing the water in the sealed cavity to enter the second connecting pipe 15 and then to be sprayed out through each atomizer 5 on the second connecting pipe 15, allowing the water vapor to absorb the heat on the heat dissipation fins 2, and achieving a better heat dissipation effect, when the moving rod 9 moves in the reverse direction, the piston rod 12 is not blocked, under the action of the restoring force of the first spring 13, the first spring 13 drives the piston rod 12 to move in the reverse direction, thereby increasing the space of the sealed cavity, allowing the water in the water tank 4 to flow into the sealed cavity through the first connecting pipe 14 for replenishment, at this time, the shell 3 is filled with the water vapor sprayed out by the atomizer 5, the water vapor is left in the shell 3 after absorbing heat, when the moving rod 9 moves towards the other side, the moving rod 9 drives the other piston rod 12 to move, the other piston rod 12 drives the hot water vapor in the other sleeve 11 to be pressed into the cooling tank 16 through the second connecting pipe 15, the hot water vapor entering the cooling tank 16 is cooled by the condensation needle 17 and the cooling pipe 23, and condensed water is stored in the cooling tank 16, meanwhile, the hot water vapor sprayed from the second connecting pipe 15 drives the fan 24 to rotate, the fan 24 drives the rotating shaft 25 to rotate, the rotating shaft 25 drives the half gear 26 to rotate, when the half gear 26 is engaged with the rack 27, the half gear 26 drives the rack 27 to move, the rack 27 drives the sealing block 20 to move, so that the space of the sealed cavity formed by the sealing block 20 and the fixed pipe 19 is increased, and the air pressure in the sealed cavity is reduced, so that the external atmospheric pressure presses the cooling liquid in the tank 18 into the sealed cavity through the liquid inlet pipe 22, when the half gear 26 is not engaged with the rack 27, the second spring 21 is in a deformed state, the restoring force of the second spring 21 generates a reverse thrust to the sealing block 20, so that the sealing block 20 moves in a reverse direction, so that the cooling liquid in the sealed cavity is pressed into the cooling pipe 23, the heat on the cooling pipe 23 is absorbed by the cooling liquid, then the heat is taken away along with the flowing of the cooling liquid, thereby realizing better water vapor cooling effect, when the moving rod 9 moves reversely, the restoring force of the first spring 13 pushes the piston rod 12 to move reversely again, so that the hot water vapor in the case 3 is introduced into the jacket 11 again through the first connection pipe 14, and as the water in the cooling tank 16 increases, when the water level is at the water level sensor 30, the water level sensor 30 sends an electric signal to the PLC, the PLC controls the water pump 28 to operate, the water pump 28 discharges the water in the cooling tank 16 into the water tank 4 through the drain pipe 29, therefore, the water is recycled, water resources are saved, the circulating flow of the cooling liquid is realized through the sprayed hot water vapor, extra driving force is not needed, and energy is saved.

Compared with the prior art, this an image acquisition instrument that is used for epidemic situation prevention and control and has high-efficient heat dissipation function, realize the control through main part 1, the heat that produces when moving main part 1 through heat dissipation mechanism dispels the heat, the steam that produces heat dissipation mechanism through cooling body cools off, compare with current heat dissipation mechanism, this mechanism passes through the forced air cooling, water-cooling and radiating fin 2 carry out multiple heat dissipation to main part 1, realize better radiating effect, and cool off and cyclic utilization steam through cooling body, the water resource has been saved, compare with current cooling body, this mechanism carries out dual cooling to steam through condensation needle 17 and the coolant liquid that flows, realize better cooling effect, thereby make the water in the water tank 4 keep lower stability, realize better water-cooling effect.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (9)

1. The image acquisition instrument with the efficient heat dissipation function for epidemic situation prevention and control is characterized by comprising a main body (1), a support, a heat dissipation mechanism and a cooling mechanism, wherein the main body (1) is arranged on the support, the heat dissipation mechanism is arranged on the main body (1), and the cooling mechanism is arranged on the heat dissipation mechanism;

the heat dissipation mechanism comprises a heat dissipation assembly and a water cooling assembly, the heat dissipation assembly comprises a plurality of heat dissipation fins (2), each heat dissipation fin (2) is uniformly arranged along the axis direction of a main body (1), the water cooling assembly comprises a shell (3), a water tank (4), an atomizing spray head (5), a driving unit, a moving unit and a pushing unit, the shell (3) is arranged on the main body (1), the heat dissipation fins (2) stretch into the shell (3), the driving unit comprises a motor (6) and a driving shaft (7), the motor (6) is horizontally arranged in the shell (3), the driving shaft (7) is arranged on the motor (6), the moving unit comprises a rotating rod (8), a moving rod (9) and a moving wheel (10), the rotating rod (8) is arranged on the driving shaft (7), one end of the rotating rod (8) is connected with the driving shaft (7), the moving wheel (10) is arranged at one end of the moving rod (9) far away from the driving shaft (7), the moving rod (9) is arranged in the shell (3), a sliding groove is formed in the shell (3), the end part of the moving rod (9) is positioned in the sliding groove, the moving rod (9) is in sliding connection with the sliding groove, a strip-shaped groove is formed in the moving rod (9), the moving wheel (10) is positioned in the strip-shaped groove, the moving wheel (10) is in rolling connection with the strip-shaped groove, the two pushing units are respectively arranged at two sides of the moving rod (9), each pushing unit comprises a sleeve (11), a piston rod (12), a first spring (13), a first connecting pipe (14) and a second connecting pipe (15), the sleeve (11) is arranged in the shell (3), one end of the piston rod (12) is positioned in the sleeve (11), the other end of the piston rod (12) extends out of the sleeve (11) and is abutted to the moving rod (9), the piston of the piston rod (12) is connected with the sleeve (11) in a sealing manner, the first spring (13) is arranged in the sleeve (11), one end of the first spring (13) is connected with the piston of the piston rod (12), the other end of the first spring (13) is connected with the sleeve (11), the first connecting pipe (14) and the second connecting pipe (15) are arranged at the top of the sleeve (11), the first connecting pipe (14) and the second connecting pipe (15) are both communicated with the interior of the sleeve (11), the water tank (4) is arranged on the shell (3), one sleeve (11) is communicated with the interior of the water tank (4) through the first connecting pipe (14) connected with the sleeve, the other sleeve (11) is communicated with the interior of the shell (3) through the other first connecting pipe (14), and the atomizing nozzle (5) is arranged on the second connecting pipe (15) on the sleeve (11) communicated with the water tank (4), the atomizing nozzle (5) is communicated with the interior of the sleeve (11) through a second connecting pipe (15);

the cooling mechanism comprises a cooling box (16) and a condensation needle (17), the cooling box (16) is arranged on the shell (3), a sleeve (11) communicated with the interior of the shell (3) is communicated with the interior of the cooling box (16) through a second connecting pipe (15) connected with the sleeve, and the condensation needle (17) is arranged at the top of the cooling box (16).

2. The image acquisition instrument with the efficient heat dissipation function for epidemic prevention and control according to claim 1, wherein a cooling unit is arranged on the cooling box (16), the cooling unit comprises a box body (18), a fixed tube (19), a sealing block (20), a second spring (21), a liquid inlet tube (22) and a cooling tube (23), the cooling tube (23) is arranged in the cooling box (16), the cooling tube (23) is spirally arranged, the box body (18) and the fixed tube (19) are both arranged on the cooling box (16), the sealing block (20) is arranged in the fixed tube (19), the sealing block (20) is hermetically connected with the fixed tube (19), the second spring (21) is arranged in the fixed tube (19), one end of the second spring (21) is connected with the sealing block (20), and the other end of the second spring (21) is connected with the fixed tube (19), liquid inlet pipe (22) and cooling tube (23) all set up at fixed pipe (19) top, fixed pipe (19) are through liquid inlet pipe (22) and the inside intercommunication of box (18), box (18) are through cooling tube (23) and the inside intercommunication of fixed pipe (19).

3. The image acquisition instrument with the efficient heat dissipation function for epidemic prevention and control according to claim 2, characterized in that, the cooling unit is provided with a rotation unit, the rotation unit comprises a fan (24), a rotation shaft (25), a half gear (26) and a rack (27), the rotation shaft (25) is arranged on the cooling box (16), the fan (24) is sleeved on the rotation shaft (25), the fan (24) is connected with the rotation shaft (25) in a key manner, the fan (24) is positioned under the second connecting pipe (15), the half gear (26) is sleeved on the rotation shaft (25), the half gear (26) is connected with the rotation shaft (25) in a key manner, the rack (27) is arranged on the sealing block (20), and the rack (27) is meshed with the half gear (26).

4. The image acquisition instrument with the efficient heat dissipation function for epidemic prevention and control as claimed in claim 3, wherein a circulation unit is arranged in the cooling box (16), the circulation unit comprises a water pump (28), a drain pipe (29) and a water level sensor (30), the water pump (28) is arranged in the cooling box (16), the drain pipe (29) is arranged on the water tank (4), the water tank (4) is communicated with the interior of the cooling box (16) through the drain pipe (29) and the water pump (28), and the water level sensor (30) is arranged in the cooling box (16).

5. The image acquisition instrument with the efficient heat dissipation function for epidemic prevention and control according to claim 1, wherein the bracket comprises a base (31) and a supporting rod (32), the supporting rod (32) is arranged on the base (31), and the main body (1) is arranged on the supporting rod (32).

6. The image acquisition instrument with the efficient heat dissipation function for epidemic prevention and control according to claim 1, wherein a one-way valve is arranged at the joint of the first connecting pipe (14) and the sleeve (11), and a one-way valve is arranged at the joint of the second connecting pipe (15) and the sleeve (11).

7. The image acquisition instrument with the efficient heat dissipation function for epidemic prevention and control according to claim 2, wherein a one-way valve is arranged at the joint of the liquid inlet pipe (22) and the fixed pipe (19), and a one-way valve is arranged at the joint of the cooling pipe (23) and the fixed pipe (19).

8. The image acquisition instrument with the efficient heat dissipation function for epidemic prevention and control according to claim 1, wherein the number of the atomizing nozzles (5) is multiple, and each atomizing nozzle (5) is arranged corresponding to each heat dissipation fin (2).

9. The image acquisition instrument with the efficient heat dissipation function for epidemic prevention and control according to claim 1, wherein a fan (24) is arranged on the driving shaft (7), and the fan (24) is arranged opposite to the heat dissipation fins (2).

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