CN219153657U - Energy-saving injection mold cooling device - Google Patents

Abstract

The utility model discloses an energy-saving injection mold cooling device, which comprises a base, wherein a cooling box is fixed on the upper surface of the base, a water tank is arranged at the top of the cooling box, an air cooling assembly is arranged at one side of the cooling box, a placing table for placing an injection mold is arranged in the cooling box, the bottom of the placing table is rotationally connected in the base, and a rotation driving assembly for placing the table is arranged in the base; according to the utility model, the water tank and the heat exchange box are arranged at the top of the cooling box, so that when the air cooling assembly introduces hot air carried out by the injection molding piece into the air duct between the heat exchange box and the water tank, the hot air is in heat transfer with the outer wall of the water tank, and the heat is partially exchanged into the water tank.

Description

Energy-saving injection mold cooling device

Technical Field

The utility model relates to the technical field of injection molds, in particular to an energy-saving injection mold cooling device.

Background

After injection molding of an injection mold in the prior art, the injection mold is usually placed on a production line for water immersion cooling or a fan is hung at the top of the production line, and the cooling mode is used for cooling by air cooling, so that the heat energy of an injection molding piece can not be recovered.

The patent CN216941718U discloses an energy-saving injection mold cooling device, which comprises a base, wherein a cooling bin is fixedly arranged at the top of the base, and a cooling component is arranged at the top of the base and positioned at one side of the cooling bin (2); the cooling assembly comprises a cooling box, a fan is fixedly arranged at the top of the cooling box, an air inlet end of the fan penetrates through the cooling box and extends to an inner cavity of the cooling box to be communicated with a cooling pipe, and an air exhaust end of the fan penetrates through the cooling bin and extends to the inner cavity of the cooling bin to be communicated with an air exhaust assembly; according to the utility model, through the arrangement of the cooling component, the outside air can be blown off to the surface of the die body after being cooled, so that the die body is cooled, and the die body is rotated through the driving component, so that the die body is uniformly subjected to wind.

The cooling device adopts the hand-operated rotation die body to save energy consumption, and is suitable for cooling injection molding parts of small working chambers. However, the structure ensures that the heat of the injection molding part can not be recovered after the air is taken out of the cooling bin through refrigeration, and the energy utilization rate is not high enough.

Disclosure of Invention

The utility model aims to provide an energy-saving injection mold cooling device, which aims to solve the problems that the injection molding part in the background art is cooled, the self heat of the injection molding part cannot be recycled, and the energy utilization rate is not high enough.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides an energy-conserving injection mold cooling device, includes the base, the upper surface of base is fixed with the cooling tank, the top of cooling tank is provided with the water tank, one side of cooling tank is provided with air-cooled component, be provided with the platform of placing that supplies injection mold to place in the cooling tank, the bottom of placing the platform is rotated and is connected in the base, be provided with the rotation drive assembly who places the platform in the base, the water tank outside is provided with the heat exchange box, be provided with heat transfer structure in the heat exchange box, one side of heat exchange box is provided with the tuber pipe connecting piece.

Preferably, the heat exchange structure comprises an air deflector, an air channel is formed between the inner wall of the heat exchange box and the outer wall of the water tank, the air deflector is fixed in the air channel, an air inlet is formed in the top of the heat exchange box, and the air deflector is located on one side of the air inlet.

Preferably, the heat exchange structure further comprises an air outlet, the air outlet is arranged on one side, far away from the air inlet, of the top of the heat exchange box, and the air outlet is communicated with the air duct.

Preferably, the air pipe connecting piece comprises an air outlet pipe, one end of the air outlet pipe is communicated with the inner cavity of the cooling box, and the other end of the air outlet pipe is connected with the air inlet.

Preferably, the air pipe connecting piece further comprises an air inlet pipe, one end of the air inlet pipe is connected with the air outlet, and the other end of the air inlet pipe is connected with the air cooling assembly.

Preferably, the air cooling assembly comprises a shell, a fan is rotatably connected to the inner wall on one side of the shell, a motor for driving the fan to rotate is mounted on one side of the shell through screws, and the air inlet pipe is communicated with the top of the shell.

Preferably, the air cooling assembly further comprises a dispersing plate, the dispersing plate is fixed on one side of the shell close to the cooling box, an air duct is formed in one side of the dispersing plate, and the shell is communicated with the inner cavity of the cooling box through the air duct.

Preferably, the placing table is in a circular arrangement, and an integrally formed annular surrounding edge is arranged on the upper surface of the placing table.

Preferably, the top of water tank is provided with the moisturizing mouth, the top of heat exchange box is provided with the sealing plug of moisturizing mouth, one side of water tank is connected with the outlet pipe, the outlet pipe runs through the heat exchange box and communicates with the outside of heat exchange box.

Preferably, the rotation driving assembly comprises a rotating rod, the rotating rod is rotationally connected in the base, one end of the rotating rod is fixedly provided with a rocking handle, the outer wall of the rotating rod is fixedly provided with a first bevel gear, the outer wall of the rotating shaft of the placing table is provided with a second bevel gear, and the first bevel gear is meshed with the second bevel gear.

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

according to the utility model, the water tank and the heat exchange box are arranged at the top of the cooling box, so that when the air cooling assembly introduces hot air carried out by the injection molding piece into the air duct between the heat exchange box and the water tank, the hot air is in heat transfer with the outer wall of the water tank, and the heat is partially exchanged into the water tank.

Drawings

FIG. 1 is an isometric view of the present utility model;

FIG. 2 is a schematic view of the structure of the back side of the present utility model;

FIG. 3 is a schematic view of the structure of the inside of the base of the present utility model;

fig. 4 is a schematic view of the structure of the inside of the heat exchange tank of the present utility model.

In the figure: 1. a base; 2. a cooling box; 3. a water tank; 4. an air cooling assembly; 5. a placement table; 6. a rotary drive assembly; 7. a heat exchange box; 8. a heat exchange structure; 9. an air duct connecting piece; 801. an air deflector; 802. an air duct; 803. an air inlet; 804. an air outlet; 901. an air outlet pipe; 902. an air inlet pipe; 401. a housing; 402. a fan; 403. a motor; 404. a diffuser plate; 405. a wind groove; 10. surrounding edges; 11. a water supplementing port; 12. sealing the rubber plug; 601. a rotating rod; 602. a rocking handle; 603. a first bevel gear; 604. a second bevel gear; 13. and a water outlet pipe.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-4, the present utility model provides a technical solution: the utility model provides an energy-conserving injection mold cooling device, including base 1, the upper surface of base 1 is fixed with cooling tank 2, the top of cooling tank 2 is provided with water tank 3, one side of cooling tank 2 is provided with forced air cooling subassembly 4, be provided with in the cooling tank 2 and supply the injection mold to place the platform 5, the bottom of placing the platform 5 is rotated and is connected in base 1, be provided with in the base 1 and place the rotation drive assembly 6 of platform 5, the water tank 3 outside is provided with heat transfer box 7, be provided with heat transfer structure 8 in the heat transfer box 7, one side of heat transfer box 7 is provided with tuber pipe connecting piece 9.

Through setting up forced air cooling subassembly 4 to placing the injection molding on placing the platform 5 forced air cooling to will be passed through the heat exchange box 7 through tuber pipe connecting piece 9 by the heat that the injection molding surface carried out in, make the water in the water tank 3 intensify, this mode can utilize the waste heat of injection molding to the water intensification, can improve the waste heat utilization ratio of injection molding.

The heat exchange structure 8 comprises an air deflector 801, an air duct 802 is formed between the inner wall of the heat exchange box 7 and the outer wall of the water tank 3, the air deflector 801 is fixed in the air duct 802, an air inlet 803 is formed in the top of the heat exchange box 7, and the air deflector 801 is located on one side of the air inlet 803. Through setting up aviation baffle 801, make the wind that has the heat get into wind channel 802 after can export around water tank 3 outer wall, extension and the route of water tank 3 outer wall contact, extension heat transfer time.

The heat exchange structure 8 further comprises an air outlet 804, the air outlet 804 is arranged on one side, far away from the air inlet 803, of the top of the heat exchange box 7, and the air outlet 804 is communicated with the air duct 802. By providing the air outlet 804, the air enters the housing 401 to circulate, and the cooling time of the injection molding is prolonged, but the waste heat utilization can be improved, and the cooling device is suitable for cooling the injection molding in a small-sized working chamber.

The air duct connecting piece 9 comprises an air outlet duct 901, one end of the air outlet duct 901 is communicated with the inner cavity of the cooling box 2, and the other end of the air outlet duct 901 is connected with the air inlet 803. The heat of the inner cavity of the cooling box 2 is penetrated into the air duct 802 by arranging the air outlet pipe 901.

The air duct connecting piece 9 further comprises an air inlet duct 902, one end of the air inlet duct 902 is connected with the air outlet 804, the other end of the air inlet duct 902 is connected with the air cooling assembly 4, and air conveyed out of the air duct 802 is sent into the shell 401 through the air inlet duct 902.

The air cooling assembly 4 comprises a shell 401, a fan 402 is rotatably connected to the inner wall of one side of the shell 401, a motor 403 for driving the fan 402 to rotate is mounted on one side of the shell 401 through screws, and an air inlet pipe 902 is communicated with the top of the shell 401. The motor 403 is started, and the fan 402 is rotated, so that the air in the housing 401 can be blown into the cooling box 2 through the air duct 405.

The air cooling assembly 4 further comprises a diffusing plate 404, the diffusing plate 404 is fixed on one side of the shell 401 close to the cooling box 2, an air duct 405 is formed in one side of the diffusing plate 404, and the shell 401 is communicated with the inner cavity of the cooling box 2 through the air duct 405.

The placing table 5 is circularly arranged, and an integrally formed annular surrounding edge 10 is arranged on the upper surface of the placing table 5. Through setting up surrounding edge 10, when placing the platform 5 and rotate, injection mold places and is difficult for the slippage on placing the platform 5.

The top of water tank 3 is provided with moisturizing mouth 11, and the top of heat exchange box 7 is provided with the sealing plug 12 of moisturizing mouth 11, and one side of water tank 3 is connected with outlet pipe 13, and outlet pipe 13 runs through heat exchange box 7 and communicates with the outside of heat exchange box 7. The water tank 3 is supplemented with water by arranging the water supplementing port 11, and the water after temperature rise is led out by the water outlet pipe 13.

The rotary driving assembly 6 comprises a rotary rod 601, the rotary rod 601 is rotatably connected in the base 1, a rocking handle 602 is fixed at one end of the rotary rod 601, a first bevel gear 603 is fixed on the outer wall of the rotary rod 601, a second bevel gear 604 is arranged on the outer wall of the rotary shaft of the placement table 5, and the first bevel gear 603 is meshed with the second bevel gear 604; the rocking handle 602 is rocked, the rotating rod 601 rotates, the first bevel gear 603 drives the second bevel gear 604 to rotate, and the placing table 5 rotates.

When the cooling device is used, the molded injection mold is placed on the placing table 5, the door of the cooling box 2 is closed, the motor 403 is started, the fan 402 rotates, air in the inner cavities of the cooling box 2, the heat exchange box 7 and the shell 401 circulates internally, the fan 402 blows air from the air groove 405 to the injection mold, the air with heat is introduced into the air duct 802 through the air outlet pipe 901, the hot air contacts with the outer wall of the water tank 3, heat exchange with water in the water tank 3 is realized, and the air after heat exchange returns to the shell 401 through the air inlet pipe 902; although this mode can lengthen the cooling time of injection molding, can improve waste heat utilization, be applicable to the injection molding cooling of small-size studio, the water after the temperature rise in the water tank 3 can be used for daily washing.

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

Claims (10)

1. An energy-conserving injection mold cooling device which characterized in that: including base (1), the last fixed surface of base (1) is provided with cooling tank (2), the top of cooling tank (2) is provided with water tank (3), one side of cooling tank (2) is provided with forced air cooling subassembly (4), be provided with in cooling tank (2) and supply placing platform (5) that injection mold placed, the bottom of placing platform (5) is rotated and is connected in base (1), be provided with in base (1) and place rotation drive subassembly (6) of platform (5), water tank (3) outside is provided with heat exchange box (7), be provided with heat exchange structure (8) in heat exchange box (7), one side of heat exchange box (7) is provided with tuber pipe connecting piece (9).

2. The energy-saving injection mold cooling device according to claim 1, wherein: the heat exchange structure (8) comprises an air deflector (801), an air duct (802) is formed between the inner wall of the heat exchange box (7) and the outer wall of the water tank (3), the air deflector (801) is fixed in the air duct (802), an air inlet (803) is formed in the top of the heat exchange box (7), and the air deflector (801) is located on one side of the air inlet (803).

3. The energy-saving injection mold cooling device according to claim 2, wherein: the heat exchange structure (8) further comprises an air outlet (804), the air outlet (804) is arranged on one side, far away from the air inlet (803), of the top of the heat exchange box (7), and the air outlet (804) is communicated with the air duct (802).

4. An energy efficient injection mold cooling apparatus according to claim 3, wherein: the air pipe connecting piece (9) comprises an air outlet pipe (901), one end of the air outlet pipe (901) is communicated with the inner cavity of the cooling box (2), and the other end of the air outlet pipe (901) is connected with the air inlet (803).

5. The energy-efficient injection mold cooling apparatus according to claim 4, wherein: the air pipe connecting piece (9) further comprises an air inlet pipe (902), one end of the air inlet pipe (902) is connected with the air outlet (804), and the other end of the air inlet pipe (902) is connected with the air cooling assembly (4).

6. The energy-efficient injection mold cooling apparatus according to claim 5, wherein: the air cooling assembly (4) comprises a shell (401), a fan (402) is rotatably connected to the inner wall of one side of the shell (401), a motor (403) for driving the fan (402) to rotate is mounted on one side of the shell (401) through screws, and the air inlet pipe (902) is communicated with the top of the shell (401).

7. The energy-efficient injection mold cooling apparatus according to claim 6, wherein: the air cooling assembly (4) further comprises a dispersing plate (404), the dispersing plate (404) is fixed on one side, close to the cooling box (2), of the shell (401), an air duct (405) is formed in one side of the dispersing plate (404), and the shell (401) is communicated with an inner cavity of the cooling box (2) through the air duct (405).

8. The energy-efficient injection mold cooling apparatus according to claim 7, wherein: the placing table (5) is in a circular shape, and an integrally formed annular surrounding edge (10) is arranged on the upper surface of the placing table (5).

9. The energy-efficient injection mold cooling apparatus according to claim 8, wherein: the top of water tank (3) is provided with moisturizing mouth (11), the top of heat exchange box (7) is provided with sealing plug (12) of moisturizing mouth (11), one side of water tank (3) is connected with outlet pipe (13), outlet pipe (13) run through heat exchange box (7) and with the outside intercommunication of heat exchange box (7).

10. The energy-efficient injection mold cooling apparatus according to claim 9, wherein: the rotary driving assembly (6) comprises a rotary rod (601), the rotary rod (601) is rotationally connected in the base (1), a rocking handle (602) is fixed at one end of the rotary rod (601), a first bevel gear (603) is fixed on the outer wall of the rotary rod (601), a second bevel gear (604) is arranged on the outer wall of the rotary shaft of the placement table (5), and the first bevel gear (603) is meshed with the second bevel gear (604).

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