CN216400578U - 3D prints with product shaping rapid cooling device - Google Patents

Abstract

The utility model discloses a product forming rapid cooling device for 3D printing, which comprises 3D printing equipment, wherein the side walls of the left side and the right side of the 3D printing equipment are respectively provided with a heat dissipation mechanism, each heat dissipation mechanism comprises a heat dissipation frame and a fan, and a humidification mechanism is arranged below the heat dissipation mechanism on the right side. The utility model relates to a product forming rapid cooling device for 3D printing, which belongs to the field of cooling devices, and is characterized in that through the arranged heat dissipation mechanisms, the operation of blowing at one end and sucking at the other end is realized by utilizing the heat dissipation mechanisms at two sides of a 3D printing device, so that the air fluidity in the 3D printing device is realized, the heat in the 3D printing device is discharged out in an accelerated manner, the heat dissipation mechanism at the right side is matched with the humidifying mechanism for use, the water-cooling heat dissipation effect on a formed product is further realized, the temperature of the formed product is rapidly reduced, the production efficiency is improved, and the arranged dustproof mechanism is used for preventing dust from entering the 3D printing device when the heat dissipation mechanism at the right side works.

Description

3D prints with product shaping rapid cooling device

Technical Field

The utility model relates to the field of cooling devices, in particular to a product forming rapid cooling device for 3D printing.

Background

3D printing (3DP), a technique for constructing objects by layer-by-layer printing using bondable materials such as powdered metals or plastics based on digital model files, is one of the rapid prototyping techniques, also known as additive manufacturing. 3D printing is typically achieved using digital technology material printers. The method is often used for manufacturing models in the fields of mold manufacturing, industrial design and the like, and is gradually used for directly manufacturing some products, and parts printed by the technology are already available. The technology has applications in jewelry, footwear, industrial design, construction, engineering and construction (AEC), automotive, aerospace, dental and medical industries, education, geographic information systems, civil engineering, firearms, and other fields. Traditional 3D printing apparatus can not realize rapid cooling's operation to fashioned product, and is poor to fashioned product cooling effect, serious influence production efficiency.

SUMMERY OF THE UTILITY MODEL

The utility model mainly aims to provide a product forming rapid cooling device for 3D printing, which can effectively solve the problems in the background technology.

In order to achieve the purpose, the utility model adopts the technical scheme that:

the utility model provides a 3D prints with product shaping rapid cooling device, includes 3D printing apparatus, all be equipped with heat dissipation mechanism on 3D printing apparatus's the left and right sides lateral wall, heat dissipation mechanism includes heat dissipation frame and fan, right side the below of heat dissipation mechanism is equipped with humidification mechanism, humidification mechanism includes atomizer, water tank and water pump, and one side of the heat dissipation mechanism on right side is equipped with dustproof mechanism, dustproof mechanism includes dustproof frame, dust screen, connecting plate, compression spring and dop.

Preferably, the heat dissipation opening has all been seted up on 3D printing apparatus's the left and right sides lateral wall, heat dissipation opening department fixed mounting has the heat dissipation frame, just the heat dissipation frame is located 3D printing apparatus's outside, the opening has been seted up to one side of heat dissipation frame, fixed mounting has the fan on one side lateral wall of heat dissipation frame, just the fan is located the rear end of opening.

Preferably, the top surface central part of heat dissipation frame has seted up the connecting hole, equal fixed mounting has a set of symmetrical fixed block on the both sides lateral wall of fan, just the card hole has been seted up to the top surface of fixed block.

Preferably, the water tank is placed below the fan, the top surface front end fixed mounting of water tank has the water inlet, just the water inlet communicates with the water tank each other, the top surface rear end fixed mounting of water tank has the water pump, through first connecting pipe fixed connection between water pump and the water tank.

Preferably, the atomizer is fixedly mounted on the top surface of the interior of the heat dissipation frame and located below the connecting hole, the atomizer is fixedly connected with the water pump through a second connecting pipe, and the second connecting pipe penetrates through the connecting hole.

Preferably, the dustproof screen is fixedly mounted in the dustproof frame, the connecting plate is fixedly mounted on two sides of the outer wall of the dustproof frame, spring grooves are formed in the upper end and the lower end of the connecting plate respectively, compression springs are fixedly mounted at the bottoms of the spring grooves, clamping heads are fixedly mounted at the front ends of the compression springs, retaining rings are fixedly mounted at the notches of the spring grooves, and the clamping heads penetrate the retaining rings.

Compared with the prior art, the utility model has the following beneficial effects:

according to the utility model, through the arranged heat dissipation mechanisms, the operation of blowing at one end and sucking at the other end is realized by utilizing the heat dissipation mechanisms at the two sides of the 3D printing equipment, so that the air flowability in the 3D printing equipment is realized, the heat in the 3D printing equipment is discharged out in an accelerated manner, the heat dissipation mechanism at the right side is matched with the humidifying mechanism, the water-cooling heat dissipation effect is further realized on the molded product, the temperature of the molded product is rapidly reduced, and the production efficiency is improved.

Drawings

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

fig. 2 is a schematic diagram of the overall structure of the 3D printing apparatus of the present invention;

FIG. 3 is a schematic diagram of the heat dissipation mechanism of the present invention with a disassembled structure;

FIG. 4 is a schematic view of the overall structure of the humidifying mechanism of the present invention;

fig. 5 is a schematic structural disassembly diagram of the dust-proof mechanism of the present invention.

In the figure: 1. a 3D printing device; 2. a heat dissipation mechanism; 3. a humidifying mechanism; 4. a dust-proof mechanism; 5. a heat dissipation port; 6. a heat dissipation frame; 7. a port; 8. connecting holes; 9. an atomizing spray head; 10. a fan; 11. a fixed block; 12. a clamping hole; 13. a water tank; 14. a water inlet; 15. a water pump; 16. a first connecting pipe; 17. a second connecting pipe; 18. a dust-proof frame; 19. a dust screen; 20. a connecting plate; 21. a spring slot; 22. a compression spring; 23. clamping a head; 24. and (4) a baffle ring.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the utility model easy to understand, the utility model is further described with the specific embodiments.

As shown in fig. 1-5, a 3D prints with product shaping rapid cooling device, including 3D printing apparatus 1, all be equipped with heat dissipation mechanism 2 on the left and right sides lateral wall of 3D printing apparatus 1, heat dissipation mechanism 2 includes heat dissipation frame 6 and fan 10, the below of right side heat dissipation mechanism 2 is equipped with humidification mechanism 3, humidification mechanism 3 includes atomizer 9, water tank 13 and water pump 15, one side of heat dissipation mechanism 2 on right side is equipped with dustproof mechanism 4, dustproof mechanism 4 includes dustproof frame 18, dust screen 19, connecting plate 20, compression spring 22 and dop 23.

As shown in fig. 2-3, in this embodiment, in order to realize the circulation of air inside the 3D printing apparatus 1, accelerate the dissipation speed of heat inside the 3D printing apparatus 1, and realize air cooling for the molded product inside the 3D printing apparatus 1, the left and right side walls of the 3D printing apparatus 1 are both provided with heat dissipation ports 5, the heat dissipation ports 5 are fixedly provided with heat dissipation frames 6, the heat dissipation frames 6 are located outside the 3D printing apparatus 1, one side of the heat dissipation frame 6 is provided with through ports 7, one side wall of the heat dissipation frame 6 is fixedly provided with a fan 10, the fan 10 is located at the rear end of the through ports 7, the center of the top surface of the heat dissipation frame 6 is provided with a connection hole 8, two side walls of the fan 10 are both fixedly provided with a set of symmetrical fixing blocks 11, and the top surface of the fixing blocks 11 is provided with clamping holes 12, when in use, the fan 10 in the left heat dissipation mechanism 2 performs an air suction operation, the fan 10 on right side will make the operation of blowing, the fan 10 on right side is bloied in to heat dissipation frame 6 through opening 7, the wind that blows out will enter into 3D printing apparatus 1 through thermovent 5, meanwhile, left fan 10 will make the operation of induced drafting in to 3D printing apparatus 1, and induced draft through thermovent 5 with the air in 3D printing apparatus 1, 3D printing apparatus 1's air will be discharged the external world by fan 10 through opening 7 of seting up on heat dissipation frame 6, realize the radiating rate through improving 3D printing apparatus 1 to 3D printing apparatus 1's shaping product in 3D printing apparatus 1.

As shown in fig. 4, in this embodiment, in order to implement water-cooling heat dissipation on a molded product, a water tank 13 is placed below a fan 10, a water inlet 14 is fixedly installed at the front end of the top surface of the water tank 13, the water inlet 14 is communicated with the water tank 13, a water pump 15 is fixedly installed at the rear end of the top surface of the water tank 13, the water pump 15 is fixedly connected with the water tank 13 through a first connecting pipe 16, an atomizer 9 is fixedly installed on the inner top surface of a heat dissipation frame 6 and located below a connecting hole 8, the atomizer 9 is fixedly connected with the water pump 15 through a second connecting pipe 17, the second connecting pipe 17 passes through the connecting hole 8, when the heat dissipation mechanism 2 on the right side is in use, cold water is added into the water tank 13 through the water inlet 14 and the water pump 15 is turned on, the water pump 15 pumps out the cold water in the water tank 13 through the first connecting pipe 16 and conveys the cold water into the atomizer 9 through the second connecting pipe 17, atomizer 9 will be in heat dissipation frame 6 water mist that sprays downwards, blow in 3D printing apparatus 1 owing to fan 10 this moment, can blow into 3D printing apparatus 1 with atomizer 9 spun water mist together in, the water mist not only can reduce the inside temperature of 3D printing apparatus 1 after entering into 3D printing apparatus 1, still can carry out the water-cooling heat dissipation to the shaping product in the 3D printing apparatus 1 simultaneously.

As shown in fig. 5, in this embodiment, in order to avoid that the right heat dissipation mechanism 2 brings dust in the outside air into the 3D printing apparatus 1 when blowing air into the 3D printing apparatus 1, the dust screen 19 is fixedly installed in the frame of the dust frame 18, the connection plates 20 are fixedly installed on both sides of the outer wall of the dust frame 18, the upper and lower ends of the connection plates 20 are respectively provided with the spring slots 21, the bottom of each spring slot 21 is fixedly provided with the compression spring 22, the front end of the compression spring 22 is fixedly provided with the chuck 23, the notch of the spring slot 21 is fixedly provided with the retaining ring 24, the chuck 23 passes through the retaining ring 24, when the right heat dissipation mechanism is in use, the dust frame 18 is installed on the rear end of the right fan 10, during the installation process, the chuck 23 is squeezed by the fixing block 11, the compression spring 22 installed in the spring slot 21 formed in the connection plate 20 retracts to drive the retaining ring 24 into the spring slot 21, until the chuck 23 is not squeezed by the fixed block 11 any more, after the fixed block is mounted to a certain extent, the chuck 23 is not pressed by the fixed block 11 any more, the compression spring 22 performs a recovery operation in the spring groove 21 and pushes the chuck 23 forward, so that the chuck 23 enters the clamping hole 12 formed in the fixed block 11, the dustproof frame 18 is mounted at the rear end of the fan 10, when the fan 10 operates, external air is sucked, when the air is sucked into the fan 10, the air passes through the dustproof frame 18, and at this time, the dustproof net 19 mounted in the dustproof frame 18 adsorbs and blocks dust in the air to prevent the dust from entering the 3D printing device 1.

While the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof or for parts thereof without departing from the scope of the utility model.

Claims (6)

1. The utility model provides a 3D prints and uses product shaping rapid cooling device which characterized in that: including 3D printing apparatus (1), all be equipped with heat dissipation mechanism (2) on the left and right sides lateral wall of 3D printing apparatus (1), heat dissipation mechanism (2) is including heat dissipation frame (6) and fan (10), right side the below of heat dissipation mechanism (2) is equipped with humidification mechanism (3), humidification mechanism (3) are including atomizer (9), water tank (13) and water pump (15), and one side of heat dissipation mechanism (2) on right side is equipped with dustproof mechanism (4), dustproof mechanism (4) are including dustproof frame (18), dust screen (19), connecting plate (20), compression spring (22) and dop (23).

2. The 3D prints and uses product shaping rapid cooling device of claim 1, characterized in that: the heat dissipation device is characterized in that a heat dissipation opening (5) is formed in the side wall of the left side and the right side of the 3D printing device (1), a heat dissipation frame (6) is fixedly mounted at the position of the heat dissipation opening (5), the heat dissipation frame (6) is located outside the 3D printing device (1), an opening (7) is formed in one side of the heat dissipation frame (6), a fan (10) is fixedly mounted on the side wall of one side of the heat dissipation frame (6), and the fan (10) is located at the rear end of the opening (7).

3. The 3D prints and uses product shaping rapid cooling device of claim 2, characterized in that: connecting hole (8) have been seted up at the top surface central point of heat dissipation frame (6), equal fixed mounting has fixed block (11) of a set of symmetry on the both sides lateral wall of fan (10), just card hole (12) have been seted up to the top surface of fixed block (11).

4. The 3D prints and uses product shaping rapid cooling device of claim 3 characterized in that: the fan is characterized in that the water tank (13) is arranged below the fan (10), a water inlet (14) is fixedly mounted at the front end of the top surface of the water tank (13), the water inlet (14) is communicated with the water tank (13), a water pump (15) is fixedly mounted at the rear end of the top surface of the water tank (13), and the water pump (15) is fixedly connected with the water tank (13) through a first connecting pipe (16).

5. The product forming rapid cooling device for 3D printing according to claim 4, wherein: atomizer (9) fixed mounting is on the inside top surface of heat dissipation frame (6) and is located the below of connecting hole (8), through second connecting pipe (17) fixed connection between atomizer (9) and water pump (15), just connecting hole (8) are passed in second connecting pipe (17).

6. The product forming rapid cooling device for 3D printing according to claim 5, wherein: fixed mounting has dust screen (19) in the frame of dustproof frame (18), the equal fixed mounting in outer wall both sides of dustproof frame (18) has connecting plate (20), spring groove (21) have been seted up respectively at the upper and lower both ends of connecting plate (20), the tank bottom fixed mounting of spring groove (21) has compression spring (22), the front end fixed mounting of compression spring (22) has dop (23), the notch department fixed mounting of spring groove (21) has fender ring (24), dop (23) pass fender ring (24).

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