CN216027575U - High-efficient forming device of precision mold that radiating effect is good - Google Patents

Abstract

The utility model discloses a precise mold efficient forming device with a good heat dissipation effect, which comprises a base, wherein the upper surface of the base is rotatably connected with a first shell, the inner side wall of the first shell is connected with a supporting plate in a sliding manner, the upper surface of the supporting plate is in threaded connection with a second shell, one side of the outer wall of the second shell is in threaded connection with a third shell, the inner side wall of the third shell is in threaded connection with a servo motor, and an output shaft of the servo motor is inserted into the second shell and is fixedly connected with fan blades; the heat that the servo motor lateral wall produced can be absorbed through setting up the heat dissipation copper, then discharges the heat from the inside of third casing through the heat dissipation copper pipe, through starting the heat dissipation fan, can dispel the heat to the servo motor of third casing inside, through setting up the through-hole, can increase the inside thermal diffusivity of third casing to improve the radiating efficiency of this device, and then can satisfy people's demand.

Description

High-efficient forming device of precision mold that radiating effect is good

Technical Field

The utility model relates to the technical field of precision molds, in particular to a precision mold efficient forming device with a good heat dissipation effect.

Background

On the basis of the technical conditions of the existing die machining, the part cannot be cooled, so that the heat dissipation efficiency of the precision die is low, the requirements of people cannot be met, the function of the existing precision die is single, and only the requirement of people for cooling is met.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a precise mould high-efficiency forming device with a good heat dissipation effect so as to solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: a high-efficiency forming device of a precision mold with good heat dissipation effect comprises a base, wherein the upper surface of the base is rotatably connected with a first shell, the inner side wall of the first shell is slidably connected with a supporting plate, the upper surface of the supporting plate is in threaded connection with a second shell, one side of the outer wall of the second shell is in threaded connection with a third shell, the inner side wall of the third shell is in threaded connection with a servo motor, an output shaft of the servo motor is inserted into the second shell and is fixedly connected with fan blades, heat dissipation copper plates are arranged on the upper surface and the lower surface of the servo motor, heat dissipation copper pipes which are arranged at equal intervals are welded on one sides of the heat dissipation copper plates far away from the servo motor, one ends of the heat dissipation copper pipes far away from the heat dissipation copper plates penetrate through the inner side wall of the third shell, a third through groove is formed on one side of the third shell far away from the second shell, and heat dissipation fans are in threaded connection with the inner side wall of the third through groove, the upper surface threaded connection of second casing has the fourth casing, the inside of fourth casing is equipped with the coolant, the bottom intercommunication of fourth casing has the connecting pipe, the one end that the fourth casing was kept away from to the connecting pipe inserts in the inside of second casing.

As further preferable in the present technical solution: one side threaded connection that third casing was kept away from to the second casing has the screen panel, the inside wall bonding of second casing has the filter screen.

As further preferable in the present technical solution: the first through groove that the equidistance was arranged is seted up to one side of first casing outer wall, the second through groove that the equidistance was arranged is seted up to the lateral wall of backup pad, the inside wall in first through groove is linked together with the inside wall in second through groove, the inside wall in first through groove and the inside wall in second through groove are pegged graft and are had the bolt.

As further preferable in the present technical solution: and a connecting block is welded on one side of the outer wall of the fourth shell, and the outer side wall of the connecting block is hinged with a cover plate through a pin shaft.

As further preferable in the present technical solution: the front surface and the rear surface of the third shell are provided with through holes which are arranged at equal intervals.

As further preferable in the present technical solution: and the pipe orifice of the connecting pipe is fixedly connected with an electromagnetic valve.

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

the heat dissipation device comprises a third shell, a heat dissipation copper plate, a through hole and a heat dissipation copper pipe, wherein the heat dissipation copper plate is arranged on the outer side wall of the servo motor;

secondly, the coolant is thrown into the fourth shell, and then the electromagnetic valve is controlled to be opened, so that the coolant falls into the second shell through the connecting pipe, and when the servo motor drives the fan blades to rotate through the output shaft of the servo motor, wind power generated by the fan blades is used for heat dissipation;

thirdly, slide from top to bottom through the inside with the backup pad along first casing to highly carrying out the regulation of freedom to this device, then insert the bolt inside wall and the second through-groove of first through-groove, thereby fix the position of this device.

Drawings

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

FIG. 2 is a schematic view of the internal structure of a third housing according to the present invention;

FIG. 3 is a schematic view of the internal structure of the fourth housing and the connecting tube according to the present invention;

fig. 4 is a schematic view of a connection structure of the second housing, the third housing and the through hole according to the present invention.

In the figure: 1. a base; 2. a first housing; 3. a support plate; 4. a second housing; 5. a third housing; 6. a servo motor; 7. a fan blade; 8. a heat-dissipating copper plate; 9. a heat dissipation copper pipe; 10. a third through groove; 11. a heat dissipation fan; 12. a fourth housing; 13. a coolant; 14. a connecting pipe; 15. connecting blocks; 16. a cover plate; 17. a mesh enclosure; 18. a filter screen; 19. a first through groove; 20. a second through groove; 21. a bolt; 22. a through hole; 23. an electromagnetic valve.

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.

Examples

Referring to fig. 1-4, the present invention provides a technical solution: a precise mold high-efficiency forming device with good heat dissipation effect comprises a base 1, wherein the upper surface of the base 1 is rotatably connected with a first shell 2, the inner side wall of the first shell 2 is slidably connected with a support plate 3, the upper surface of the support plate 3 is in threaded connection with a second shell 4, one side of the outer wall of the second shell 4 is in threaded connection with a third shell 5, the inner side wall of the third shell 5 is in threaded connection with a servo motor 6, an output shaft of the servo motor 6 is inserted into the second shell 4 and is fixedly connected with fan blades 7, heat dissipation copper plates 8 are respectively arranged on the upper surface and the lower surface of the servo motor 6, heat dissipation copper pipes 9 which are arranged at equal intervals are welded on one sides of the heat dissipation copper plates 8, one ends of the heat dissipation copper pipes 9, far away from the heat dissipation copper plates 8, penetrate through the inner side wall of the third shell 5, far away from the second shell 4, third through grooves 10 are formed in a manner, and heat dissipation fans 11 are in threaded connection with the inner side walls of the third through grooves 10, a fourth housing 12 is screwed to the upper surface of the second housing 4, a coolant 13 is provided inside the fourth housing 12, a connection pipe 14 is communicated with the bottom of the fourth housing 12, and one end of the connection pipe 14, which is far from the fourth housing 12, is inserted into the second housing 4.

In this embodiment, specifically: a mesh enclosure 17 is connected to one side of the second shell 4 far away from the third shell 5 in a threaded manner, and a filter screen 18 is bonded to the inner side wall of the second shell 4; through setting up filter screen 18, can play the effect of filtering and intercepting to debris such as dust.

In this embodiment, specifically: one side of the outer wall of the first shell 2 is provided with first through grooves 19 which are arranged at equal intervals, the outer side wall of the supporting plate 3 is provided with second through grooves 20 which are arranged at equal intervals, the inner side wall of each first through groove 19 is communicated with the inner side wall of each second through groove 20, and the inner side walls of the first through grooves 19 and the inner side walls of the second through grooves 20 are inserted with bolts 21; the first through groove 19, the second through groove 20 and the latch 21 are arranged to facilitate fixing the positions of the first housing 2 and the support plate 3.

In this embodiment, specifically: a connecting block 15 is welded on one side of the outer wall of the fourth shell 12, and a cover plate 16 is hinged to the outer side wall of the connecting block 15 through a pin shaft.

In this embodiment, specifically: the front surface and the rear surface of the third shell 5 are both provided with through holes 22 which are arranged at equal intervals; by providing the through hole 22, the heat dissipation property inside the third casing 5 can be increased.

In this embodiment, specifically: the orifice of the connecting pipe 14 is fixedly connected with an electromagnetic valve 23; by providing the electromagnetic valve 23, the flow rate of the coolant 13 can be controlled.

Working principle or structural principle, when in use, the support plate 3 slides up and down along the inside of the first shell 2 to freely adjust the height of the device, then the bolt 21 is inserted into the inner side wall of the first through groove 19 and the inside of the second through groove 20 to fix the position of the device, the heat generated by the outer side wall of the servo motor 6 can be absorbed by arranging the heat-radiating copper plate 8, then the heat is discharged from the inside of the third shell 5 through the heat-radiating copper pipe 9, the servo motor 6 in the third shell 5 can be radiated by starting the heat-radiating fan 11, the heat radiation performance in the third shell 5 can be increased by arranging the through hole 22, the coolant 13 is put into the inside of the fourth shell 12, then the electromagnetic valve 23 is controlled to be opened, so that the coolant 13 falls into the inside of the second shell 4 through the connecting pipe 14, when the servo motor 6 drives the fan blades 7 to rotate through the output shaft thereof, the coolant 13 is blown out by the wind generated by the fan blades 7.

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 utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a high-efficient forming device of precision mold that radiating effect is good, includes base (1), its characterized in that: the upper surface of the base (1) is rotatably connected with a first shell (2), the inner side wall of the first shell (2) is slidably connected with a supporting plate (3), the upper surface of the supporting plate (3) is in threaded connection with a second shell (4), one side of the outer wall of the second shell (4) is in threaded connection with a third shell (5), the inner side wall of the third shell (5) is in threaded connection with a servo motor (6), an output shaft of the servo motor (6) is inserted into the second shell (4) and is fixedly connected with fan blades (7), the upper surface and the lower surface of the servo motor (6) are both provided with heat dissipation copper plates (8), one side of each heat dissipation copper plate (8) far away from the servo motor (6) is welded with heat dissipation copper pipes (9) which are arranged at equal intervals, one ends of the heat dissipation copper pipes (9) far away from the heat dissipation copper plates (8) penetrate through the inner side wall of the third shell (5), the third casing (5) keep away from one side of second casing (4) and seted up the third and lead to groove (10), the inside wall threaded connection that the third led to groove (10) has heat dissipation fan (11), the upper surface threaded connection of second casing (4) has fourth casing (12), the inside of fourth casing (12) is equipped with coolant (13), the bottom intercommunication of fourth casing (12) has connecting pipe (14), the one end that fourth casing (12) were kept away from in connecting pipe (14) is inserted in the inside of second casing (4).

2. The efficient forming device for the precision mold with the good heat dissipation effect as recited in claim 1, wherein: one side of the second shell (4) far away from the third shell (5) is in threaded connection with a mesh cover (17), and a filter screen (18) is bonded on the inner side wall of the second shell (4).

3. The efficient forming device for the precision mold with the good heat dissipation effect as recited in claim 1, wherein: first logical groove (19) that the equidistance was arranged are seted up to one side of first casing (2) outer wall, the second that the equidistance was arranged is seted up to the lateral wall of backup pad (3) leads to groove (20), the inside wall that first logical groove (19) and second led to groove (20) is linked together, the inside wall that first logical groove (19) and second led to groove (20) are pegged graft and are had bolt (21).

4. The efficient forming device for the precision mold with the good heat dissipation effect as recited in claim 1, wherein: one side welding of fourth casing (12) outer wall has connecting block (15), the lateral wall of connecting block (15) articulates through the round pin axle has apron (16).

5. The efficient forming device for the precision mold with the good heat dissipation effect as recited in claim 1, wherein: the front surface and the rear surface of the third shell (5) are provided with through holes (22) which are arranged at equal intervals.

6. The efficient forming device for the precision mold with the good heat dissipation effect as recited in claim 1, wherein: the nozzle of the connecting pipe (14) is fixedly connected with an electromagnetic valve (23).

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