A high-precision copper handicraft micro-sculpture processing device

By combining exhaust and blowing components, the problem of high-temperature copper shavings splashing in the copper craft micro-carving device was solved, achieving efficient waste cleaning and temperature reduction, and improving work efficiency.

CN224476757UActive Publication Date: 2026-07-10TONGLING TONGTIANXIA CULTURAL CREATIVE CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
TONGLING TONGTIANXIA CULTURAL CREATIVE CO LTD
Filing Date
2025-09-15
Publication Date
2026-07-10

AI Technical Summary

Technical Problem

Existing micro-carving devices for copper crafts generate high-temperature copper shavings during the carving process, which can easily cause burns and require frequent cleaning, wasting manpower.

Method used

The system combines a ventilation component and a blowing component. Airflow is used to draw in the waste generated during engraving and blow it into the feeding trough. The waste is collected and compressed by a collection component, reducing accumulation and cleaning frequency.

Benefits of technology

It enables rapid cleaning of high-temperature waste, prevents splashing and accumulation, improves work efficiency, and reduces table surface temperature.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model relates to a kind of processing device for high-precision copper handicraft micro-sculpture, belong to handicraft micro-sculpture processing technical field, including shell and micro-sculpture component, the left side of the shell is provided with suction unit, the right side of the shell is provided with blowing assembly, the inside of the shell is provided with collection component, the micro-sculpture component includes No. 3 motor and drill bit. By blowing assembly blowing, the metal scrap produced by carving is sucked, so as to realize the high-temperature metal scrap produced by carving is cleaned quickly, prevent splashing and accumulation on the countertop, and the suction assembly arranged below the baffle is used to suck the scrap, and the transverse airflow formed during the suction process can also carry away the heat around the handicraft, realize the cooling effect, the linkage effect is formed between the collection component and the suction assembly, the suctioned metal scrap is collected in the collection box, and it is repeatedly extruded, the volume of metal scrap is reduced, the capacity of the collection box is improved, and the collection box is poured frequently.
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Description

Technical Field

[0001] This utility model relates to the field of micro-carving technology for handicrafts, and specifically to a high-precision micro-carving device for copper handicrafts. Background Technology

[0002] The copper craft micro-carving processing device is a device used to perform tiny and fine carving on copper materials. It uses tiny cutting tools or abrasives to perform cutting, grinding and other processing operations on the surface of copper crafts through precise mechanical movements to achieve the effect of micro-carving.

[0003] According to the publicly available announcement (CN217197590U), a carving device for copper craft production is disclosed. This technology discloses a device comprising: a base plate, multiple support columns connected to the top of the base plate, a first motor mounted on the top of each support column via a mounting plate, the bottom output ends of each first motor penetrating the mounting plate and connected to lifting screws, sliding carriages slidably connected to each support column, multiple screw holes on each sliding carriage, multiple lifting screws threaded into each screw hole, connecting rods rotatably connected to each sliding carriage, power rods rotatably connected to the other ends of each connecting rod, a carving plate rotatably connected between the other ends of the power rods, a second motor mounted on the carving plate, and a carving knife connected to the bottom output end of the second motor penetrating the carving plate. The top of the base plate is connected to a clamping system. The first motor mounted on the top of the mounting plate moves, driving the lifting screw fixedly connected to the output end of the first motor to rotate. This, in turn, drives the slide carriage slidably connected to the support column to move. This, in turn, drives the connecting rod rotatably connected to the slide carriage and the power rod rotatably connected to the other end of the connecting rod to move. This, in turn, drives the second motor mounted on the engraving plate to move, driving the engraving knife fixedly connected to the output end of the second motor to perform the engraving movement. The clamping system fixedly connected to the top of the base plate moves to perform the clamping operation. Therefore, this engraving device for copper craft production is easy to clamp and fix, and it is convenient to perform irregular engraving operations on multiple surfaces during engraving, making it highly flexible in use.

[0004] However, the above technical solutions cannot solve the problem of waste generated during the carving process of copper crafts. Because a large amount of high-temperature copper shavings are generated during the carving process, these high-temperature copper shavings can easily cause burns when they fly, and the work surface needs to be cleaned regularly, resulting in unnecessary waste of manpower.

[0005] To address the aforementioned issues, this application proposes a high-precision micro-carving processing device for copper handicrafts. Utility Model Content

[0006] This utility model addresses the technical problems existing in the prior art by providing a high-precision micro-carving processing device for copper crafts.

[0007] The technical solution of this utility model to solve the above-mentioned technical problems is as follows: A high-precision copper craft micro-carving processing device includes a shell and a micro-carving component. A ventilation component is provided on the left side of the shell, a blowing component is provided on the right side of the shell, and a collection component is provided inside the shell. The micro-carving component includes a No. 3 motor and a drill bit. The output end of the No. 3 motor is fixedly connected to the drill bit.

[0008] The exhaust assembly includes a first bevel gear, a first rotating shaft, a first fan, and a first dust filter. The interior of the first bevel gear is fixedly connected to the first rotating shaft, and the end of the first rotating shaft away from the first bevel gear is fixedly connected to the first fan. The outer surface of the first dust filter is fixedly connected to the housing. The blower assembly includes a third bevel gear, a third rotating shaft, a second fan, and a second dust filter. The interior of the third bevel gear is fixedly connected to the third rotating shaft, and the end of the third rotating shaft away from the third bevel gear is fixedly connected to the second fan. The outer surface of the second dust filter is fixedly connected to the housing.

[0009] The collection assembly includes a collection box, a first screw, and an extrusion plate. The inside of the collection box is rotatably connected to the first screw, and the side surface of the first screw is threadedly connected to the extrusion plate.

[0010] Preferably, a first motor is fixedly connected to the rear surface of the housing, and a second rotating shaft is fixedly connected to the output end of the first motor. Multiple second bevel gears are fixedly connected to the side surface of the second rotating shaft, and the side surfaces of the second bevel gears mesh with the first bevel gear. The first motor drives the second rotating shaft, which in turn drives the second bevel gear and the first bevel gear, causing the first fan on the first rotating shaft to rotate and generate a leftward suction airflow, facilitating the suction of waste materials.

[0011] Preferably, a second motor is fixedly connected to the rear surface of the housing, and a fourth rotating shaft is fixedly connected to the output end of the second motor. Multiple fourth bevel gears are fixedly connected to the side surface of the fourth rotating shaft, and the side surface of the fourth bevel gear meshes with a third bevel gear. The second motor drives the fourth rotating shaft, which in turn drives the fourth and third bevel gears, causing the second fan on the third rotating shaft to generate an airflow blowing to the left, facilitating the blowing of waste chips to the left into the feeding chute.

[0012] Preferably, a No. 4 motor is fixedly connected to the rear surface of the housing, and a No. 2 screw is fixedly connected to the output end of the No. 4 motor. The side surface of the No. 2 screw is threadedly connected to the longitudinal slide plate. A No. 5 motor is fixedly connected to the left surface of the longitudinal slide plate, and the output end of the No. 5 motor is fixedly connected to the No. 3 screw. The side surface of the No. 3 screw is threadedly connected to the transverse slide plate. A No. 6 motor is fixedly connected to the upper surface of the transverse slide plate, and a No. 4 screw is fixedly connected to the output end of the No. 6 motor. A vertical slide plate is threadedly connected to the side surface of the No. 4 screw, and the front surface of the vertical slide plate is fixedly connected to the No. 3 motor. Rotation of the No. 2 screw drives the longitudinal slide plate to move longitudinally, rotation of the No. 3 screw drives the transverse slide plate to move laterally, and rotation of the No. 4 screw drives the vertical slide plate to move vertically up and down, thus achieving omnidirectional movement of the drill bit, facilitating high-precision micro-carving.

[0013] Preferably, the interior of the housing is provided with a feeding trough, and a guide plate is provided below the feeding trough. The waste material sucked from the feeding trough is guided into the collection box by the guide plate, which facilitates the collection of waste material.

[0014] Preferably, a turntable is fixedly connected to the end of the first screw away from the collection box, and a handle is rotatably connected inside the turntable. By rotating the handle, the first screw can be easily rotated in the extrusion plate, thereby pushing the extrusion plate back and forth to extrude metal scraps.

[0015] Preferably, the lower surface of the housing is provided with four rollers arranged in a rectangular array. The rollers facilitate the movement of mobile devices and improve flexibility.

[0016] The beneficial effects of this utility model are:

[0017] By using a blower to blow the metal shavings generated during carving from the work surface to the exhaust vent, where they are sucked in, the high-temperature metal shavings generated during carving are quickly cleaned up, preventing them from splashing and accumulating on the work surface. The suction component located below the baffle sucks in the shavings, and the horizontal airflow generated during the suction process also carries away the heat around the artwork, thus achieving a cooling effect.

[0018] By setting up a collection component that works in conjunction with the suction component, the suctioned metal scraps are collected in a collection box. The collection box is then repeatedly squeezed by a compression plate to reduce its volume, increase its capacity, and allow it to collect more scraps before needing to be replaced. This reduces the frequency of emptying the collection box and improves work efficiency. Attached Figure Description

[0019] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0020] Figure 2 This is a partial structural schematic diagram of the present invention;

[0021] Figure 3 This is a schematic diagram of the collection box structure of this utility model;

[0022] Figure 4 for Figure 2 Enlarged schematic diagram of the structure at point A in the middle;

[0023] Figure 5 for Figure 2 Enlarged schematic diagram of the structure at point B.

[0024] The attached diagram lists the components represented by each number as follows:

[0025] 1. Housing; 2. Bevel Gear No. 1; 3. Shaft No. 1; 4. Fan No. 1; 5. Dustproof Net No. 1; 6. Motor No. 1; 7. Shaft No. 2; 8. Bevel Gear No. 2; 9. Bevel Gear No. 3; 10. Shaft No. 3; 11. Fan No. 2; 12. Dustproof Net No. 2; 13. Motor No. 2; 14. Shaft No. 4; 15. Bevel Gear No. 4; 16. Collection Box; 17. Screw No. 1; 18. Extrusion Plate; 19. Motor No. 3; 20. Drill Bit; 21. Motor No. 4; 22. Screw No. 2; 23. Longitudinal Slide Plate; 24. Motor No. 5; 25. Screw No. 3; 26. Lateral Slide Plate; 27. Motor No. 6; 28. Screw No. 4; 29. ​​Vertical Slide Plate; 30. Feed Chute; 31. Guide Plate; 32. Turntable; 33. Handle; 34. Roller. Detailed Implementation

[0026] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0027] Reference Figure 1-5A high-precision copper craft micro-carving processing device includes a housing 1 and a micro-carving component. A ventilation component is located on the left side of the housing 1, a blowing component is located on the right side of the housing 1, and a collection component is located inside the housing 1. The micro-carving component includes a No. 3 motor 19 and a drill bit 20. The output end of the No. 3 motor 19 is fixedly connected to the drill bit 20. A No. 4 motor 21 is fixedly connected to the rear surface of the housing 1. A No. 2 screw 22 is fixedly connected to the output end of the No. 4 motor 21. The side surface of the No. 2 screw 22 is threadedly connected to a longitudinal sliding plate 23. A No. 5 motor 24 is fixedly connected to the left surface of the longitudinal sliding plate 23. The output end of the No. 5 motor 24 is fixedly connected to a No. 3 screw 25. The side surface of the No. 3 screw 25 is threadedly connected to a transverse sliding plate 26. A No. 6 motor 27 is fixedly connected to the upper surface of the transverse sliding plate 26. A No. 4 screw 28 is fixedly connected to the output end of the No. 6 motor 27. A vertical sliding plate 29 is threadedly connected to the side surface of the No. 4 screw 28. The front surface of the vertical sliding plate 29 is fixedly connected to the No. 3 motor 19. The longitudinal slide plate 23 moves longitudinally by rotating screw 22, the transverse slide plate 26 moves laterally by rotating screw 25, and the vertical slide plate 29 moves vertically by rotating screw 28, thus enabling omnidirectional movement of the drill bit 20 for high-precision micro-carving. The lower surface of the housing 1 is equipped with four rollers 34 arranged in a rectangular array. The rollers 34 facilitate movement of the equipment and improve flexibility.

[0028] The exhaust assembly includes a first bevel gear 2, a first rotating shaft 3, a first fan 4, and a first dust filter 5. The interior of the first bevel gear 2 is fixedly connected to the first rotating shaft 3. The end of the first rotating shaft 3 away from the first bevel gear 2 is fixedly connected to the first fan 4. The outer surface of the first dust filter 5 is fixedly connected to the housing 1. The blower assembly includes a third bevel gear 9, a third rotating shaft 10, a second fan 11, and a second dust filter 12. The interior of the third bevel gear 9 is fixedly connected to the third rotating shaft 10. The end of the third rotating shaft 10 away from the third bevel gear 9 is fixedly connected to the second fan 11. The outer surface of the second dust filter 12 is fixedly connected to the housing 1. A first motor 6 is fixedly connected to the rear surface of the housing 1. A second rotating shaft 7 is fixedly connected to the output end of the first motor 6. Multiple second bevel gears 8 are fixedly connected to the side surface of the second rotating shaft 7. The side surface of the second bevel gears 8 meshes with the first bevel gear 2. Motor 6 drives shaft 7, which in turn drives bevel gear 8 and bevel gear 2, causing fan 4 on shaft 3 to rotate and generate a leftward suction airflow to facilitate the extraction of waste. Motor 13 is fixedly connected to the rear surface of housing 1. Shaft 14 is fixedly connected to the output end of motor 13. Multiple bevel gears 15 are fixedly connected to the side surface of shaft 14, and the side surface of bevel gears 15 meshes with bevel gear 9. Motor 13 drives shaft 14, which in turn drives bevel gears 15 and bevel gear 9, causing fan 11 on shaft 10 to generate a leftward airflow to blow waste into the discharge chute 30.

[0029] The collection assembly includes a collection box 16, a first screw 17, and an extrusion plate 18. The inside of the collection box 16 is rotatably connected to the first screw 17, and the side surface of the first screw 17 is threadedly connected to the extrusion plate 18. A discharge trough 30 is provided inside the housing 1, and a guide plate 31 is provided below the discharge trough 30. Waste material sucked from the discharge trough 30 is guided into the collection box 16 through the guide plate 31 for easy collection. A turntable 32 is fixedly connected to the end of the first screw 17 away from the collection box 16, and a handle 33 is rotatably connected inside the turntable 32. By rotating the handle 33, the first screw 17 can be easily rotated within the extrusion plate 18, thereby pushing the extrusion plate 18 back and forth to extrude metal scraps.

[0030] Working principle:

[0031] When micro-carving copper crafts, motor 6 and motor 13 are activated. Motor 6 drives shaft 7 to rotate, shaft 7 drives bevel gear 8 to rotate, bevel gear 8 drives bevel gear 2 to rotate, and bevel gear 2 drives fan 4 on shaft 3 to rotate, generating suction airflow. Simultaneously, motor 13 drives shaft 14 to rotate, shaft 14 drives bevel gear 15 to rotate, bevel gear 15 drives bevel gear 9 to rotate, and bevel gear 9 drives fan 4 on shaft 10 to rotate. The fan 11 rotates to generate a blowing airflow, which, through a combination of blowing and suction, creates an airflow that flows laterally into the feeding trough 30. This airflow carries the waste generated from the carving on the housing 1 into the feeding trough 30, and then guides it into the collection box 16 through the guide plate 31. When a large amount of waste accumulates in the collection box 16, the handle 33 is held to rotate the turntable 32, which drives the screw 17 to rotate in the extrusion plate 18. This pushes the extrusion plate 18 to repeatedly squeeze the waste, compressing it into a smaller volume. This allows the collection box 16 to hold more waste without the need for frequent emptying.

[0032] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. It will be apparent to those skilled in the art that this utility model is not limited to the details of the exemplary embodiments described above, and that it can be implemented in other specific forms without departing from the spirit or basic characteristics of this utility model. Therefore, the embodiments should be considered exemplary and non-limiting in all respects. The scope of this utility model is defined by the appended claims rather than the foregoing description, and thus all variations falling within the meaning and scope of equivalents of the claims are intended to be included within this utility model. No reference numerals in the claims should be construed as limiting the scope of the claims.

[0033] Furthermore, it should be understood that although this specification describes embodiments, not every embodiment contains only one independent technical solution. This narrative style is merely for clarity. Those skilled in the art should consider the specification as a whole, and the technical solutions in each embodiment can also be appropriately combined to form other embodiments that can be understood by those skilled in the art.

Claims

1. A high-precision micro-carving processing device for copper handicrafts, comprising a housing (1) and a micro-carving component, characterized in that, A ventilation assembly is provided on the left side of the housing (1), a blowing assembly is provided on the right side of the housing (1), a collection assembly is provided inside the housing (1), and the micro-carving assembly includes a No. 3 motor (19) and a drill bit (20). The output end of the No. 3 motor (19) is fixedly connected to the drill bit (20). The exhaust assembly includes a first bevel gear (2), a first rotating shaft (3), a first fan (4), and a first dustproof net (5). The interior of the first bevel gear (2) is fixedly connected to the first rotating shaft (3). The end of the first rotating shaft (3) away from the first bevel gear (2) is fixedly connected to the first fan (4). The outer surface of the first dustproof net (5) is fixedly connected to the housing (1). The blower assembly includes a third bevel gear (9), a third rotating shaft (10), a second fan (11), and a second dustproof net (12). The interior of the third bevel gear (9) is fixedly connected to the third rotating shaft (10). The end of the third rotating shaft (10) away from the third bevel gear (9) is fixedly connected to the second fan (11). The outer surface of the second dustproof net (12) is fixedly connected to the housing (1). The collection assembly includes a collection box (16), a first screw (17) and an extrusion plate (18). The interior of the collection box (16) is rotatably connected to the first screw (17), and the side surface of the first screw (17) is threadedly connected to the extrusion plate (18).

2. The high-precision micro-carving processing device for copper handicrafts according to claim 1, characterized in that, A first motor (6) is fixedly connected to the rear surface of the housing (1). A second rotating shaft (7) is fixedly connected to the output end of the first motor (6). A plurality of second bevel gears (8) are fixedly connected to the side surface of the second rotating shaft (7). The side surface of the second bevel gear (8) meshes with the first bevel gear (2).

3. The high-precision micro-carving processing device for copper handicrafts according to claim 1, characterized in that, The rear surface of the housing (1) is fixedly connected to a No. 2 motor (13), the output end of the No. 2 motor (13) is fixedly connected to a No. 4 rotating shaft (14), the side surface of the No. 4 rotating shaft (14) is fixedly connected to multiple No. 4 bevel gears (15), and the side surface of the No. 4 bevel gears (15) meshes with the No. 3 bevel gear (9).

4. The high-precision micro-carving processing device for copper handicrafts according to claim 1, characterized in that, The rear surface of the housing (1) is fixedly connected to a No. 4 motor (21), the output end of the No. 4 motor (21) is fixedly connected to a No. 2 screw (22), the side surface of the No. 2 screw (22) is threadedly connected to a longitudinal slide plate (23), the left surface of the longitudinal slide plate (23) is fixedly connected to a No. 5 motor (24), the output end of the No. 5 motor (24) is fixedly connected to a No. 3 screw (25), the side surface of the No. 3 screw (25) is threadedly connected to a transverse slide plate (26), the upper surface of the transverse slide plate (26) is fixedly connected to a No. 6 motor (27), the output end of the No. 6 motor (27) is fixedly connected to a No. 4 screw (28), the side surface of the No. 4 screw (28) is threadedly connected to a vertical slide plate (29), and the front surface of the vertical slide plate (29) is fixedly connected to a No. 3 motor (19).

5. The high-precision micro-carving processing device for copper handicrafts according to claim 1, characterized in that, The housing (1) is provided with a feeding trough (30) inside, and a guide plate (31) is provided below the feeding trough (30).

6. The high-precision micro-carving processing device for copper handicrafts according to claim 1, characterized in that, The end of the first screw (17) away from the collection box (16) is fixedly connected to a turntable (32), and the inside of the turntable (32) is rotatably connected to a handle (33).

7. The high-precision micro-carving processing device for copper handicrafts according to claim 1, characterized in that, The lower surface of the housing (1) is provided with rollers (34), and the number of rollers (34) is four and they are distributed in a rectangular array.