CN111994491A - Large-scale storage facilities heat abstractor based on vibrations - Google Patents

Abstract

The invention relates to the technical field of storage equipment and discloses a vibration-based large-scale storage equipment heat dissipation device which comprises an input shaft, wherein the outer side of the input shaft is rotatably connected with a crankshaft flywheel, one end of the crankshaft flywheel is rotatably connected with a first connecting rod, one end of the first connecting rod is rotatably connected with a first connecting plate, the outer side of the input shaft is rotatably connected with a first gear, the outer side of the first gear is meshed with a second gear, the outer side of the second gear is rotatably connected with a sleeve shaft, and the outer side of the sleeve shaft is rotatably connected with a second connecting plate. This large-scale storage facilities heat abstractor based on vibrations through the connection of input shaft, second gear, has realized the even heat dissipation, has solved current storage device and can not evenly radiating problem when using, makes the temperature of device effectively reduce, convenient and practical makes the object easily preserve, can not influence the quality of preservation, and the practicality is high, can carry out effectual saving to the object.

Description

Large-scale storage facilities heat abstractor based on vibrations

Technical Field

The invention relates to the technical field of storage equipment, in particular to a vibration-based large-scale storage equipment heat dissipation device.

Background

The existing storage device is poor in heat dissipation performance, objects stored at the deeper bottom of the device, such as seeds, do not have good sealing and ventilation characteristics, meanwhile, when the storage device is used, the temperature of the whole storage device can rise through heat conduction of the objects, certain influence is generated, although the existing heat dissipation device is provided with a fan inside the storage device, the fan only ventilates to one position, heat dissipation cannot be uniform, the storage device can be influenced, the practicability is low, and the storage device is easy to damage due to vibration during transportation.

In order to solve the problems, the inventor provides a vibration-based large-scale storage equipment heat dissipation device, which realizes uniform heat dissipation through the connection of an input shaft and a second gear, solves the problem that the existing storage device cannot uniformly dissipate heat when in use, effectively reduces the temperature of the device, is convenient and practical, enables objects to be stored easily, does not influence the storage quality, has high practicability, can dissipate heat by using vibration in the transportation process, can effectively absorb vibration, and can effectively store the objects.

Disclosure of Invention

Technical problem to be solved

Aiming at the defects of the prior art, the invention provides the vibration-based large-scale storage equipment heat dissipation device which has the advantages of capability of dissipating heat of a bottom object, high practicability and uniform heat dissipation, and solves the problems that the bottom object is poor in heat dissipation performance, low in practicability and incapable of dissipating heat uniformly.

(II) technical scheme

In order to realize the purposes of heat dissipation, high practicability and uniform heat dissipation of the bottom object, the invention provides the following technical scheme: a vibration-based large-scale storage equipment heat dissipation device comprises an input shaft, wherein a crankshaft flywheel is rotatably connected to the outer side of the input shaft, a first connecting rod is rotatably connected to one end of the crankshaft flywheel, a first connecting plate is rotatably connected to one end of the first connecting rod, a first gear is rotatably connected to the outer side of the input shaft, a second gear is meshed to the outer side of the first gear, a sleeve shaft is rotatably connected to the outer side of the second gear, a second connecting plate is rotatably connected to the outer side of the sleeve shaft, a first piston is arranged on the outer side of the first connecting plate, a heat dissipation pipe is movably mounted on the outer side of the first piston, a first connecting shaft is movably connected to the inner portion of the first piston, a third gear is meshed to the outer side of the first connecting shaft, a fourth gear is meshed to the outer side of the third gear, a second connecting rod is rotatably connected to the outer side of the fourth gear, one end of the second connecting, the inside of the second gear is rotatably connected with a second connecting shaft, the outer side of the connecting shell is rotatably connected with a magnetic disc, and a magnetic piston is arranged above the magnetic disc.

Preferably, the input shaft is connected with motor drive, the outside rotation of input shaft is connected with the fan, and consequently, the motor can drive the input shaft and rotate, and the input shaft can drive the fan and rotate to dispel the heat.

Preferably, the outer side of the crankshaft flywheel is fixedly connected with a spring, and the spring can play a role in connection and vibration reduction through the elasticity of the spring.

Preferably, the outer side of the first connecting plate is connected with a shell in a sliding mode, the first connecting plate and the shell are fixedly connected with the spring, and the spring can play a role in connection and vibration reduction.

Preferably, the outer side of the sleeve shaft is provided with a sliding groove, the sliding groove is rotatably connected with the second connecting shaft, and the second connecting shaft can be rotated through the sliding groove.

Preferably, the second connecting plate and the first piston are internally provided with through holes, and cold air can be diffused through the through holes.

Preferably, the fourth gear and the second connecting rod are eccentrically connected, the connecting shell is movably connected with the second connecting shaft, the connecting gear is rotatably connected inside the connecting shell, the fan is rotatably connected outside the connecting gear, and the connecting gear is rotatably connected with the second connecting shaft.

Preferably, the outer side of the magnetic piston is connected with a cold accumulation shell in a sliding mode, the cold accumulation shell is fixedly connected with the radiating pipe, and the magnetic piston is fixedly connected with the spring.

(III) advantageous effects

Compared with the prior art, the invention provides a vibration-based large-scale storage equipment heat dissipation device, which has the following beneficial effects:

1. this large-scale storage facilities heat abstractor based on vibrations, through the connection of input shaft, bent axle flywheel, first connecting rod, first connecting plate, first gear, second gear, realized evenly dispelling the heat, solved current storage device can not evenly radiating problem when using, make the temperature of device effectively reduce, convenient and practical makes the object easily preserve, can not influence the storage quality, deep position also can carry out good ventilation and heat dissipation, improves the heat dispersion of bottom.

2. This large-scale storage facilities heat abstractor based on vibrations through the connection of sleeve axle, second connecting plate, first piston, cooling tube, first even axle, third gear, has realized effective reduce temperature to make storage device and preserved article avoid receiving the influence, solved current heat abstractor and equipped with the fan but radiating problem that can not be even in the device is inside, the practicality is high, can carry out effectual saving to the object.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of a heat pipe structure according to the present invention;

FIG. 3 is a schematic view of the gear structure of the present invention;

FIG. 4 is a schematic view of a crankshaft flywheel of the present invention;

FIG. 5 is an enlarged view of the structure at A in FIG. 1 according to the present invention;

FIG. 6 is an enlarged view of the structure at B in FIG. 2 according to the present invention;

FIG. 7 is a schematic diagram of a disk structure according to the present invention.

In the figure: 1. an input shaft; 2. a crankshaft flywheel; 3. a first link; 4. a first connecting plate; 5. a first gear; 6. a second gear; 7. a sleeve shaft; 8. a second connecting plate; 9. a first piston; 10. a radiating pipe; 11. a first coupling shaft; 12. a third gear; 13. a fourth gear; 14. a second link; 15. a connecting shell; 16. a limiting plate; 17. a second coupling shaft; 18. a magnetic disk; 19. a magnetic piston.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, a vibration-based heat dissipation device for large storage equipment, includes an input shaft 1, a crankshaft flywheel 2 rotatably connected to an outer side of the input shaft 1, a spring fixedly connected to an outer side of the crankshaft flywheel 2 for connecting and reducing vibration by an elastic force of the spring, the input shaft 1 being in transmission connection with a motor, and a fan rotatably connected to an outer side of the input shaft 1, so that the motor can drive the input shaft 1 to rotate, the input shaft 1 can drive the fan to rotate for dissipating heat, a first link 3 rotatably connected to an end of the crankshaft flywheel 2, a first link 4 rotatably connected to an end of the first link 3, a housing slidably connected to an outer side of the first link 4, the first link 4 and the housing both being fixedly connected to the spring, and having connection and reducing vibration by an elastic force of the spring, a first gear 5 rotatably connected to an outer side of the input shaft 1, a second gear 6 is meshed outside the first gear 5, a sleeve shaft 7 is rotatably connected outside the second gear 6, a second connecting plate 8 is rotatably connected outside the sleeve shaft 7, a first piston 9 is arranged outside the first connecting plate 4, through holes are formed inside the second connecting plate 8 and the first piston 9, cold air can be diffused through the through holes, a radiating pipe 10 is movably installed outside the first piston 9, a first connecting shaft 11 is movably connected inside the first piston 9, a third gear 12 is meshed outside the first connecting shaft 11, a fourth gear 13 is meshed outside the third gear 12, a second connecting rod 14 is rotatably connected outside the fourth gear 13, the fourth gear 13 and the second connecting rod 14 are eccentrically connected, a connecting shell 15 is movably connected with a second connecting shaft 17, a connecting gear is rotatably connected inside the connecting shell 15, and a fan is rotatably connected outside the connecting gear, the connecting gear is connected with the second connecting shaft 17 in a rotating mode, one end of the second connecting rod 14 is connected with the connecting shell 15 in a rotating mode, the upper end of the connecting shell 15 is provided with a limiting plate 16, the second gear 6 is connected with the second connecting shaft 17 in an internal rotating mode, a sliding groove is formed in the outer side of the sleeve shaft 7 and is connected with the second connecting shaft 17 in a rotating mode, the second connecting shaft 17 can rotate through the sliding groove, a magnetic disc 18 is connected to the outer side of the connecting shell 15 in a rotating mode, a magnetic piston 19 is arranged above the magnetic disc 18, the outer side of the magnetic piston 19 is connected with a cold accumulation shell in a sliding mode, the cold accumulation shell is fixedly connected with the radiating pipe 10.

The working principle is that when in use, the motor drives the input shaft 1 to rotate, so that the input shaft 1 drives the crankshaft flywheel 2 which is rotatably connected with the outer side to rotate, the crankshaft flywheel 2 is driven by the spring fixedly connected with the outer side to vibrate the first connecting plate 4 by the elasticity of the spring, the first connecting plate 4 vibrates up and down to compress the cooling liquid at the bottom end, when in transportation, the vibration generated in transportation can be utilized without the vibration of the crankshaft flywheel 2, the crankshaft flywheel 2 can be disassembled, the cooling liquid enters the radiating pipe 10 through the through hole arranged in the first piston 9 to absorb heat, so that the deeper bottom end in the device can radiate heat well, the condition that the position at the lower end does not have good sealing and ventilation characteristics is improved, the pressure of the other part of the cooling liquid through the through hole of the first piston 9 is smaller, the first piston 9 and the first connecting shaft 11 are pushed to move upwards, when the first connecting shaft 11 is engaged to rotate the third gear 12 clockwise, the third gear 12 is engaged to rotate the fourth gear 13 counterclockwise, the fourth gear 13 is eccentrically connected to rotate the second connecting rod 14 up and down to drive the connecting shell 15 to rotate up and down, the input shaft 1 drives the fan rotationally connected to the outside to rotate, thereby dissipating heat, the input shaft 1 drives the first gear 5 rotationally connected to the outside to rotate, the first gear 5 drives the second gear 6 to rotate by engagement, the second gear 6 drives the second connecting shaft 17 to rotate, the second connecting shaft 17 is engaged with each other by the connecting gear to drive the fan to rotate, the limit plate 16 limits the position, the fan on the upper side moves to dissipate heat uniformly, the second connecting shaft 17 is engaged with each other by the connecting gear and can drive the magnetic disk 18 to rotate, thereby rotating the magnetic disk 18, rotate to the magnetic piece, adsorb magnetism piston 19 downwards, when rotating to another piece, do not have magnetism, make the spring to 19 upwards stretchs magnetism pistons to make the cooling fluid in the cold-storage shell go into cooling tube 10, carry out even quick heat dissipation.

In conclusion, this large-scale storage facilities heat abstractor based on vibrations through input shaft 1, bent axle flywheel 2, first connecting rod 3, first connecting plate 4, first gear 5, the connection of second gear 6, has realized the even heat dissipation, has solved the problem that current storage device can not evenly dispel the heat when using, makes the temperature of device effectively reduce, convenient and practical makes the object easily preserve, can not influence the preservation quality, and good ventilation and heat dissipation can also be carried out to darker position, improve the heat dispersion of bottom.

This large-scale storage facilities heat abstractor based on vibrations through sleeve shaft 7, second connecting plate 8, first piston 9, cooling tube 10, first connecting plate 11, the connection of third gear 12, has realized effective hypothermia to make storage device and preserved article avoid receiving the influence, solved current heat abstractor and installed the inside radiating problem that the fan can not be even that is equipped with of device, the practicality is high, can carry out effectual saving to the object.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (8)

1. A vibration-based large-scale storage equipment heat dissipation device comprises an input shaft (1), and is characterized in that: the outer side of the input shaft (1) is rotatably connected with a crankshaft flywheel (2), one end of the crankshaft flywheel (2) is rotatably connected with a first connecting rod (3), one end of the first connecting rod (3) is rotatably connected with a first connecting plate (4), the outer side of the input shaft (1) is rotatably connected with a first gear (5), the outer side of the first gear (5) is meshed with a second gear (6), the outer side of the second gear (6) is rotatably connected with a sleeve shaft (7), the outer side of the sleeve shaft (7) is rotatably connected with a second connecting plate (8), the outer side of the first connecting plate (4) is provided with a first piston (9), the outer side of the first piston (9) is movably provided with a radiating pipe (10), the inner part of the first piston (9) is movably connected with a first connecting shaft (11), the outer side of the first connecting shaft (11) is meshed with a third gear (12), the outer side of the third gear (12) is meshed with a fourth, the outer side of the fourth gear (13) is rotatably connected with a second connecting rod (14), one end of the second connecting rod (14) is rotatably connected with a connecting shell (15), a limiting plate (16) is arranged at the upper end of the connecting shell (15), the inner part of the second gear (6) is rotatably connected with a second connecting shaft (17), the outer side of the connecting shell (15) is rotatably connected with a magnetic disc (18), and a magnetic piston (19) is arranged above the magnetic disc (18).

2. The large storage device vibration-based heat sink of claim 1, wherein: the input shaft (1) is in transmission connection with the motor, and the outer side of the input shaft (1) is rotatably connected with the fan.

3. The large storage device vibration-based heat sink of claim 1, wherein: and a spring is fixedly connected to the outer side of the crankshaft flywheel (2).

4. The large storage device vibration-based heat sink of claim 1, wherein: the outer side of the first connecting plate (4) is connected with a shell in a sliding mode, and the first connecting plate (4) and the shell are fixedly connected with a spring.

5. The large storage device vibration-based heat sink of claim 1, wherein: the outer side of the sleeve shaft (7) is provided with a sliding groove, and the sliding groove is rotationally connected with the second connecting shaft (17).

6. The large storage device vibration-based heat sink of claim 1, wherein: through holes are formed in the second connecting plate (8) and the first piston (9).

7. The large storage device vibration-based heat sink of claim 1, wherein: fourth gear (13), second connecting rod (14) eccentric connection, connecting shell (15) and second are axle (17) swing joint even, the inside of connecting shell (15) is rotated and is connected with connecting gear, and connecting gear's outside is rotated and is connected with the fan, connecting gear and second are even axle (17) and are rotated and be connected.

8. The large storage device vibration-based heat sink of claim 1, wherein: the outer side of the magnetic piston (19) is connected with a cold accumulation shell in a sliding mode, the cold accumulation shell is fixedly connected with the radiating pipe (10), and the magnetic piston (19) is fixedly connected with the spring.

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