An integrated processing device for copper removal and sorting of waste motor stators.

By designing an integrated processing device for copper removal and sorting of waste motor stators with copper cutting, clamping, pulling and sorting mechanisms, the problem of impurities in copper affecting purity has been solved, and efficient online automatic separation and improvement of copper purity have been achieved.

CN122298774APending Publication Date: 2026-06-30SICHUAN ZHONGKUANG RENEWABLE RESOURCES CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
SICHUAN ZHONGKUANG RENEWABLE RESOURCES CO LTD
Filing Date
2026-05-08
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

In existing technologies, after the stator of a waste motor is dismantled, the copper wire coil is mixed with impurities such as iron filings, silicon steel sheet fragments, and paint powder, which affects the purity of the copper material. This requires manual secondary sorting, which is inefficient and costly.

Method used

An integrated processing device including copper cutting, clamping, copper pulling and sorting mechanisms was designed. The copper material is automatically separated from impurities online through vibrating screening and servo motor driven sorting mechanism. The copper cutting mechanism cuts the copper wire, the clamping mechanism fixes the stator, the copper pulling mechanism pulls out the copper wire, and the sorting mechanism performs high-frequency vibrating screening.

Benefits of technology

It enables online automatic separation of copper from impurities, improving copper purity, reducing the need for manual sorting, and increasing dismantling efficiency and the recycling value of copper.

✦ Generated by Eureka AI based on patent content.

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Abstract

This invention discloses an integrated processing device for copper removal and sorting of waste motor stators, relating to the field of waste motor recycling technology. The integrated processing device includes a sorting box, a copper-cutting mechanism, a clamping mechanism, a copper-pulling mechanism, and a sorting mechanism. A copper-removing box communicating with the interior is fixedly installed on the top of the sorting box. The sorting mechanism is located inside the sorting box and includes a vibrating frame, a screening screen frame, a fixed plate, a servo motor, and a cam. The vibrating frame is located inside the sorting box, and the screening screen frame is held in place within the vibrating frame. In this integrated processing device, the servo motor drives the cam to rotate, pushing the vibrating frame to reciprocate along a slide bar. Under the reset action of the spring, high-frequency vibration is generated, achieving online automatic separation of copper and impurities. The purity of the copper is significantly improved, eliminating the need for manual secondary sorting.
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Description

Technical Field

[0001] This invention relates to the field of waste motor recycling technology, and in particular to an integrated processing device for dismantling copper from waste motor stators and sorting copper materials. Background Technology

[0002] After dismantling the stator of a waste motor, the pulled-out copper wire coils contain impurities such as iron filings, silicon steel sheet fragments, and paint powder. These impurities adhere to the copper wire, affecting the purity of the copper and reducing its recycling value. Current methods largely rely on manual secondary sorting after dismantling, requiring workers to manually shake off and pick out impurities. This is inefficient, produces inconsistent sorting quality, and consumes significant labor costs. For example, Chinese patent document CN203737699U discloses a copper wire extraction machine for motor coils in waste household appliances. It includes a frame structure, a coil support component, a coil clamp component opposite to the coil support component, and a pulling component that drives the coil clamp component to move towards or away from the coil support component. This machine can pull out the copper wire from the motor coil, replacing the traditional manual operation method with auxiliary tools and improving sorting efficiency.

[0003] However, this device only has the function of pulling copper. After the copper is pulled, the copper wire falls directly into the collection area. Impurities such as iron filings and paint powder are still mixed with the copper material. It is necessary to rely on manual secondary sorting and cleaning after disassembly. It cannot achieve online automatic sorting and purification, and the purity of the copper material is difficult to guarantee. Therefore, this invention proposes an integrated processing device for copper disassembly and copper material sorting of waste motor stators. Summary of the Invention

[0004] The purpose of this invention is to provide an integrated processing device for copper removal and sorting of waste motor stators, which can solve the problem that impurities such as iron filings, silicon steel sheet fragments, and paint powder are mixed in the copper coils after copper removal, affecting the purity of the copper material and reducing its recycling value.

[0005] To achieve the above objectives, the present invention provides the following technical solution: an integrated processing device for copper removal and sorting of waste motor stators, comprising: The sorting box has a copper disassembly box fixedly installed on its top, which communicates with its interior. The copper-cutting mechanism, located inside the copper-removal box, is used to cut copper wires. The clamping mechanism is located inside the copper disassembly box and directly below the copper cutting mechanism. The clamping mechanism is used to fix the stator. The copper pulling mechanism is located inside the copper removal box and directly below the clamping mechanism. The copper pulling mechanism is used to pull out the copper wire. The sorting mechanism is located inside the sorting box. The sorting mechanism includes a vibrating frame, a screening screen frame, a fixed plate, a servo motor, and a cam. The vibrating frame is installed inside the sorting box, and the screening screen frame is snapped into the vibrating frame. A material discharge chute is opened at the bottom of the vibrating frame. A fixed plate is fixedly installed on one inner wall of the sorting box. A servo motor is fixedly installed on the top of the fixed plate, and a cam is rotatably installed on the bottom of the fixed plate. The shaft of the servo motor is connected to the cam for transmission, and the cam is in contact with the outer surface of one side of the vibrating frame.

[0006] Preferably, the sorting mechanism further includes sliding sleeves, sliding rods, and springs. Two sets of sliding sleeves are fixedly installed at the bottom of the vibration frame, and two sets of sliding rods are fixedly installed between the inner walls of both sides of the sorting box. Both sets of sliding sleeves are movably sleeved on the corresponding sliding rods. A set of springs is sleeved on each of the two sets of sliding rods. One end of each set of springs is fixedly connected to the inner wall of the other side of the sorting box, and the other end of each set of springs is fixedly connected to the corresponding sliding sleeve.

[0007] Preferably, the copper-cutting mechanism includes a first support plate, a first electric push rod, an annular cutter, and a first connecting plate. The first support plate is fixedly installed between the inner walls of the two sides of the copper-cutting box. The first electric push rod is fixedly installed on the top of the first support plate. The annular cutter is provided directly below the first support plate. The first connecting plate is integrally formed on the top of the annular cutter. The free end of the first electric push rod passes through the first support plate and is fixedly connected to the first connecting plate.

[0008] Preferably, the clamping mechanism includes a fixed frame, a second electric push rod, and a V-shaped clamping plate. A set of fixed frames is fixedly installed on the inner walls of both sides of the copper box. A set of second electric push rods is fixedly installed between the inner walls of both sides of the two sets of fixed frames. The free ends of the two sets of second electric push rods pass through one side of the corresponding fixed frame and are fixedly installed with a set of V-shaped clamping plates.

[0009] Preferably, the copper pulling mechanism includes a second support plate, a third electric push rod, a support ring, a second connecting plate, an L-shaped plate, a fourth electric push rod, and an arc-shaped clamping plate. The second support plate is fixedly installed between the inner walls of the two sides of the copper removal box. The third electric push rod is fixedly installed at the bottom of the second support plate. The support ring is provided directly above the second support plate. The second connecting plate is integrally formed at the bottom of the support ring. The free end of the third electric push rod passes through the second support plate and is fixedly connected to the second connecting plate. Four sets of L-shaped plates are fixedly installed on the outer surface of the support ring and are evenly distributed in a ring. A set of fourth electric push rods is fixedly installed on the side of each of the four sets of L-shaped plates facing away from the support ring. The free ends of the four sets of fourth electric push rods pass through the corresponding L-shaped plates and are fixedly installed with an arc-shaped clamping plate.

[0010] Preferably, the copper disassembly box has a retrieval and placement opening on its front side, and a movable window covering the retrieval and placement opening is fitted onto the outer surface of the front side of the copper disassembly box. Two sets of sliding grooves are provided on the front side of the copper disassembly box, and two sets of sliders are fixedly installed on the outer surface of the rear side of the movable window. Both sets of sliders are slidably installed in the corresponding sliding grooves.

[0011] Preferably, the sorting box has a material inlet on the front side, and a cover plate is hinged to the material inlet.

[0012] Preferably, the front side of the sorting box has a pull-out opening, and a collection box is placed at the bottom inside the sorting box, with the collection box movably positioned inside the pull-out opening.

[0013] Preferably, a tapered plate is fixedly installed on the top of the second support plate.

[0014] Preferably, a set of rubber pads is fixedly installed on the side of each of the two sets of V-shaped clamps that are close to each other.

[0015] Compared with the prior art, the beneficial effects of the present invention are: This integrated processing device for copper removal and sorting of waste motor stators utilizes a sorting mechanism consisting of a vibrating frame, a screening screen frame, a sliding sleeve, a sliding rod, a spring, a servo motor, and a cam. After copper is pulled, the copper wire falls into the screening screen frame. The servo motor drives the cam to rotate, pushing the vibrating frame to reciprocate along the sliding rod. Under the reset action of the spring, high-frequency vibration is generated, causing the copper wire to tumble and vibrate within the screening screen frame. Fine impurities such as iron filings and paint powder fall through the screen holes to the bottom of the sorting box, while the copper wire remains on the screening screen frame. This achieves automatic online separation of copper and impurities, significantly improving the purity of the copper and eliminating the need for manual secondary sorting. The screening screen frame is snapped into place inside the vibrating frame; simply flipping up the cover allows the screen frame to be removed for cleaning or to empty the copper material, making operation convenient.

[0016] This integrated processing device for copper removal and sorting of waste motor stators utilizes a copper-cutting mechanism, a clamping mechanism, and a copper-pulling mechanism. The stator is placed on a support ring, and V-shaped clamps on both sides clamp the stator under the drive of a second electric push rod. The first electric push rod drives the annular cutter to move down and cut the upper copper coil of the stator in one go. Subsequently, four sets of fourth electric push rods drive the arc-shaped clamps to work with the support ring to clamp the lower copper coil. The third electric push rod drives the support ring and the arc-shaped clamps to move down as a whole to pull the copper wire out of the iron core. The copper cutting and copper pulling are completed in the same station in a coordinated manner, eliminating the need to transfer the stator and resulting in high dismantling efficiency.

[0017] This integrated processing device for copper removal and sorting of waste motor stators features a conical plate at the top of the second support plate. The pulled-out copper wire slides down the inclined surface of the conical plate into the screening mesh frame, preventing the copper wire from remaining on the second support plate. The front of the copper removal box has a liftable movable window. It can be opened by sliding upwards to pick up and put down the stator, and closed by sliding downwards to seal the operating space and prevent debris from splashing. A collection box is placed at the bottom of the sorting box to collect the impurities that fall off the screen, making it easy to clean regularly. Attached Figure Description

[0018] The present invention will be further described below with reference to the accompanying drawings and embodiments: Figure 1 This is a frontal perspective view of the present invention; Figure 2 This is a schematic diagram of the internal structure of the sorting box of the present invention; Figure 3 This is a schematic diagram of the internal structure of the copper box of the present invention; Figure 4 This is a front sectional view of the copper box disassembly method of the present invention; Figure 5 This is a schematic diagram of the copper-cutting mechanism of the present invention; Figure 6 This is a schematic diagram of the clamping mechanism of the present invention; Figure 7 This is a schematic diagram of the copper pulling mechanism of the present invention; Figure 8 This is a bottom perspective view of the support ring of the present invention.

[0019] Reference numerals: 1. Sorting box; 2. Copper removal box; 3. Sorting mechanism; 31. Vibrating frame; 32. Screening mesh frame; 33. Sliding sleeve; 34. Sliding rod; 35. Spring; 36. Fixing plate; 37. Servo motor; 38. Cam; 4. Copper cutting mechanism; 41. First support plate; 42. First electric push rod; 43. Circular cutter; 44. First connecting plate; 5. Clamping mechanism; 51. Fixing frame; 52. Second electric push rod; 53. V-shaped clamping plate; 6. Copper pulling mechanism; 61. Second support plate; 62. Third electric push rod; 63. Support ring; 64. Second connecting plate; 65. L-shaped plate; 66. Fourth electric push rod; 67. Arc-shaped clamping plate; 7. Movable window; 8. Slider; 9. Slide groove; 10. Cover plate; 11. Collection box; 12. Conical plate. Detailed Implementation

[0020] Please see Figure 1-8This invention provides a technical solution: an integrated processing device for copper removal and sorting of waste motor stators, comprising a sorting box 1, a copper removal box 2, a sorting mechanism 3, a copper cutting mechanism 4, a clamping mechanism 5, and a copper pulling mechanism 6. The copper removal box 2 is fixedly installed on the top of the sorting box 1, and the two are internally connected, allowing the copper wires after pulling to fall directly into the sorting mechanism 3 below for online screening without manual transfer. The front side of the copper removal box 2 has a pick-and-place opening, with a movable window 7 fitted into it. Two sets of sliders 8 are fixedly installed on the rear outer surface of the movable window 7. The front side of the copper removal box 2 has two sets of sliding grooves 9, with the two sets of sliders 8 slidingly installed in their corresponding grooves 9. Sliding the movable window 7 upwards opens the pick-and-place opening for removing and placing the stator, providing ample operating space; sliding downwards closes the opening, effectively preventing debris from splashing outwards during copper cutting and pulling, maintaining a clean working environment.

[0021] The copper cutting mechanism 4 is located inside the copper removal box 2 and is used to cut all the copper coils on the upper surface of the stator in one go. The copper cutting mechanism 4 includes a first support plate 41, a first electric push rod 42, an annular cutter 43, and a first connecting plate 44. The first support plate 41 is fixedly installed between the inner walls of both sides of the copper removal box 2 to provide stable support for the entire copper cutting action. The first electric push rod 42 is fixedly installed on the top of the first support plate 41, and the annular cutter 43 is located directly below the first support plate 41. The annular cutter 43 adopts an annular blade structure, which can cover all the copper coil ends on the upper surface of the stator with a single press, resulting in high cutting efficiency. The top of the annular cutter 43 is integrally formed with the first connecting plate 44. The free end of the first electric push rod 42 passes through the first support plate 41 and is fixedly connected to the first connecting plate 44. The first electric push rod 42 pushes the annular cutter 43 to move down smoothly, cuts the copper coils cleanly against the upper surface of the stator, and then automatically resets. The annular design of the blade ensures that each bundle of copper wires is stressed synchronously, resulting in a clean cut without residue.

[0022] The clamping mechanism 5 is located inside the copper removal box 2 and directly below the copper cutting mechanism 4. It is used to reliably fix the stator core during the copper cutting and pulling process. The clamping mechanism 5 includes a fixed frame 51, a second electric push rod 52, and a V-shaped clamping plate 53. A set of fixed frames 51 is fixedly installed on the inner walls of the left and right sides of the copper removal box 2. A set of second electric push rods 52 is fixedly installed inside each of the two sets of fixed frames 51. The free ends of the two sets of second electric push rods 52 pass through the corresponding fixed frames 51 on the side facing the stator and a set of V-shaped clamping plates 53 is fixedly installed thereon. The two sets of second electric push rods 52 push the V-shaped clamping plates 53 synchronously to clamp the outer circle of the stator from both sides. The self-centering characteristic of the V-shaped clamping surface allows waste stators of different diameters to be automatically centered and clamped, with strong compatibility. A set of rubber pads is fixedly installed on the side of the two sets of V-shaped clamping plates 53 that are close to each other, which increases the clamping friction and makes the stator more securely fixed. At the same time, it buffers the clamping force to avoid hard damage to the surface of the waste stator core.

[0023] The copper pulling mechanism 6 is located inside the copper removal box 2 and directly below the clamping mechanism 5. It is used to pull out the copper coil on the lower end face of the stator as a whole to achieve copper-iron separation. The copper pulling mechanism 6 includes a second support plate 61, a third electric push rod 62, a support ring 63, a second connecting plate 64, an L-shaped plate 65, a fourth electric push rod 66, and an arc-shaped clamping plate 67. The second support plate 61 is fixedly installed between the inner walls of both sides of the copper removal box 2 to provide pull-out reaction force support. The third electric push rod 62 is fixedly installed at the bottom of the second support plate 61. The support ring 63 is located directly above the second support plate 61. The bottom of the support ring 63 is integrally formed with the second connecting plate 64. The free end of the third electric push rod 62 passes through the second support plate 61 and is fixedly connected to the second connecting plate 64. The third electric push rod 62 drives the support ring 63 to flatten. The lifting and lowering mechanism completes the pulling and resetting actions. Four sets of L-shaped plates 65 are fixedly installed on the outer surface of the support ring 63, evenly distributed in a ring. A fourth electric push rod 66 is fixedly installed on the side of each L-shaped plate 65 facing away from the support ring 63. The free ends of the four sets of fourth electric push rods 66 pass through the corresponding L-shaped plates 65 and are fixedly installed with an arc-shaped clamping plate 67. The four sets of fourth electric push rods 66 drive the arc-shaped clamping plate 67 to move towards the center, coordinating with the support ring 63 to form a closed, tightly gripping posture from the outer ring of the copper wire coil. The four sets of arc-shaped clamping plates 67 apply force evenly, ensuring balanced force on the copper wire coil, reliable clamping without slippage, and pulling the entire copper wire coil downwards out of the iron core groove to complete the copper-iron separation. A conical plate 12 is fixedly installed on the top of the second support plate 61. The pulled-out copper wire automatically slides down the inclined surface of the conical plate 12 into the sorting box 1, preventing the copper wire from accumulating on the second support plate 61.

[0024] The sorting mechanism 3 is located inside the sorting box 1 and is used to perform online vibration screening on the pulled-out copper wires to remove mixed impurities. The sorting mechanism 3 includes a vibrating frame 31, a screening screen frame 32, a sliding sleeve 33, a sliding rod 34, a spring 35, a fixing plate 36, a servo motor 37, and a cam 38. The vibrating frame 31 is located inside the sorting box 1. The screening screen frame 32 is snapped into the vibrating frame 31. It can be directly inserted during installation and easily removed by lifting it upwards for cleaning or changing the screen size. The bottom of the vibrating frame 31 has a material drop chute, through which the screened fine impurities fall into the lower space. The fixing plate 36 is fixedly installed on one side of the inner wall of the sorting box 1. The servo motor 37 is fixedly installed on the top of the fixing plate 36. The cam 38 is rotatably installed on the bottom of the fixing plate 36. The shaft of the servo motor 37 is connected to the cam 38 for transmission. The cam 38 is in contact with one side of the outer surface of the vibrating frame 31. The servo motor 37 drives the cam 38 to rotate, and the high point of the cam 38 periodically pushes the vibrating frame 31 to one side. Two sets of sliding sleeves 33 are fixedly installed at the bottom of the frame 31, and two sets of sliding rods 34 are fixedly installed between the inner walls of both sides of the sorting box 1. The two sets of sliding sleeves 33 are respectively movably sleeved on the corresponding sliding rods 34. The sliding cooperation between the sliding sleeves 33 and the sliding rods 34 provides a stable reciprocating guide for the vibrating frame 31, ensuring smooth screening without jamming. A set of springs 35 is sleeved on each of the two sets of sliding rods 34. One end of each set of springs 35 is fixedly connected to one side of the inner wall of the sorting box 1, and the other end is fixedly connected to the corresponding sliding sleeve 33. After the cam 38 pushes the vibrating frame 31 to one side, the elastic force of the spring 35 pulls the vibrating frame 31 back to its original position. This reciprocating motion forms a high-frequency vibration. The copper wire continuously tumbles and shakes inside the screening screen frame 32. Fine impurities such as iron filings and paint powder fall into the collection box 11 below through the screen holes, while the copper material remains on the screening screen frame 32 to complete automatic separation and purification. The purity of the copper material is significantly improved, and no manual secondary sorting is required.

[0025] The front of the sorting box 1 has a material inlet, and a cover plate 10 is hinged to the material inlet. By flipping up the cover plate 10, the screening frame 32 and the screened copper material can be removed together. After closing the cover plate 10, the next batch of screening can continue. The front of the sorting box 1 also has a pull-out opening. A collection box 11 is placed at the bottom inside the sorting box 1. The collection box 11 is movably set in the pull-out opening. Impurities falling off the screen are collected in the collection box 11. It can be pulled out and cleaned periodically, making maintenance convenient.

[0026] Working principle: The sliding window 7 opens the loading and unloading opening, and the waste motor stator is placed on the support ring 63. Two sets of second electric push rods 52 push the V-shaped clamping plate 53 to clamp the outer circle of the stator from both sides to complete the fixation. The first electric push rod 42 drives the annular cutter 43 to move down, and the annular cutter 43 cuts the copper coil in one go along the upper end face of the stator. The cutter then resets. Four sets of fourth electric push rods 66 drive the arc-shaped clamping plate 67 to move towards the center, and together with the support ring 63, clamps the copper wire coil on the lower end face of the stator from the outer ring. The third electric push rod 62 drives the support ring 63 and the arc-shaped clamping plate 67 to move down as a whole, pulling the copper wire out of the iron core. The pulled-out copper wire moves along the first... The conical plate at the top of the second support plate 61 slides down onto the screening frame 32 inside the sorting box 1, and the arc-shaped clamp 67 is released and reset. The servo motor 37 drives the cam 38 to rotate, pushing the vibrating frame 31 to move back and forth along the slide rod 34. The spring 35 causes the vibrating frame 31 to bounce back and reset. The screening frame 32 vibrates at high frequency with the vibrating frame 31. Impurities such as iron filings and paint powder attached to the copper wire fall into the collection box 11 below through the screen holes. The copper material is retained on the screening frame 32 and the sorting is completed. The screening frame 32 can be removed and the copper material poured out by flipping up the cover plate 10. The collection box 11 is pulled out to clean the impurities. After processing, the sliding window 7 slides down to close the copper dismantling box 2.

[0027] The embodiments of the present invention have been described in detail above with reference to the accompanying drawings. However, the present invention is not limited to the above embodiments. Within the scope of knowledge possessed by those skilled in the art, various changes can be made without departing from the spirit of the present invention.

Claims

1. An integrated processing device for dismantling copper from waste motor stators and sorting copper materials, characterized in that, include: The sorting box (1) has a copper disassembly box (2) that communicates with its interior fixedly installed on its top. The copper cutting mechanism (4) is located inside the copper dismantling box (2) and is used to cut copper wires; The clamping mechanism (5) is located inside the copper dismantling box (2) and directly below the copper cutting mechanism (4). The clamping mechanism (5) is used to fix the stator. The copper pulling mechanism (6) is located inside the copper disassembly box (2) and directly below the clamping mechanism (5). The copper pulling mechanism (6) is used to pull out copper wires. The sorting mechanism (3) is located inside the sorting box (1). The sorting mechanism (3) includes a vibrating frame (31), a screening frame (32), a fixed plate (36), a servo motor (37), and a cam (38). The sorting box (1) is equipped with a vibrating frame (31). The screening frame (32) is clamped inside the vibrating frame (31). The bottom of the vibrating frame (31) is provided with a material discharge chute. A fixed plate (36) is fixedly installed on one side of the inner wall of the sorting box (1). A servo motor (37) is fixedly installed on the top of the fixed plate (36). A cam (38) is rotatably installed on the bottom of the fixed plate (36). The shaft of the servo motor (37) is connected to the cam (38) for transmission. The cam (38) is in contact with the outer surface of one side of the vibrating frame (31).

2. The integrated processing device for copper removal and sorting of waste motor stators according to claim 1, characterized in that: The sorting mechanism (3) also includes a sliding sleeve (33), a sliding rod (34) and a spring (35). Two sets of sliding sleeves (33) are fixedly installed at the bottom of the vibration frame (31). Two sets of sliding rods (34) are fixedly installed between the inner walls of the two sides of the sorting box (1). The two sets of sliding sleeves (33) are movably sleeved on the corresponding sliding rods (34). A set of springs (35) is sleeved on each of the two sets of sliding rods (34). One end of each set of springs (35) is fixedly connected to the inner wall of the other side of the sorting box (1), and the other end of each set of springs (35) is fixedly connected to the corresponding sliding sleeve (33).

3. The integrated processing device for copper removal and sorting of waste motor stators according to claim 2, characterized in that: The copper cutting mechanism (4) includes a first support plate (41), a first electric push rod (42), an annular cutter (43), and a first connecting plate (44). The first support plate (41) is fixedly installed between the inner walls of the two sides of the copper removal box (2). The first electric push rod (42) is fixedly installed on the top of the first support plate (41). The annular cutter (43) is provided directly below the first support plate (41). The first connecting plate (44) is integrally formed on the top of the annular cutter (43). The free end of the first electric push rod (42) passes through the first support plate (41) and is fixedly connected to the first connecting plate (44).

4. The integrated processing device for copper removal and sorting of waste motor stators according to claim 3, characterized in that: The clamping mechanism (5) includes a fixed frame (51), a second electric push rod (52) and a V-shaped clamp (53). A set of fixed frames (51) is fixedly installed on both sides of the inner wall of the copper box (2). A set of second electric push rods (52) is fixedly installed between the inner walls of both sides of the two sets of fixed frames (51). The free ends of the two sets of second electric push rods (52) pass through one side of the corresponding fixed frame (51) and are fixedly installed with a set of V-shaped clamps (53).

5. The integrated processing device for copper removal and sorting of waste motor stators according to claim 4, characterized in that: The copper pulling mechanism (6) includes a second support plate (61), a third electric push rod (62), a support ring (63), a second connecting plate (64), an L-shaped plate (65), a fourth electric push rod (66), and an arc-shaped clamping plate (67). The second support plate (61) is fixedly installed between the inner walls of the two sides of the copper disassembly box (2). The third electric push rod (62) is fixedly installed at the bottom of the second support plate (61). The support ring (63) is set directly above the second support plate (61). The bottom of the support ring (63) is integrally formed. A second connecting plate (64) is provided. The free end of the third electric push rod (62) passes through the second support plate (61) and is fixedly connected to the second connecting plate (64). Four sets of L-shaped plates (65) are fixedly installed on the outer surface of the support ring (63) and are evenly distributed in a ring. A set of fourth electric push rods (66) is fixedly installed on the side of each of the four sets of L-shaped plates (65) away from the support ring (63). The free ends of the four sets of fourth electric push rods (66) pass through the corresponding L-shaped plates (65) and are fixedly installed with a set of arc-shaped clamps (67).

6. The integrated processing device for copper removal and sorting of waste motor stators according to claim 5, characterized in that: The copper dismantling box (2) has a pick-up and put-out opening on the front side. The outer surface of the front side of the copper dismantling box (2) is fitted with a movable window (7) covering the pick-up and put-out opening. The front side of the copper dismantling box (2) has two sets of sliding grooves (9). The outer surface of the rear side of the movable window (7) is fixedly installed with two sets of sliders (8). Both sets of sliders (8) are slidably installed in the corresponding sliding grooves (9).

7. The integrated processing device for copper removal and sorting of waste motor stators according to claim 6, characterized in that: The sorting box (1) has a material inlet on the front side, and a cover plate (10) is hinged to the material inlet.

8. The integrated processing device for copper removal and sorting of waste motor stators according to claim 7, characterized in that: The sorting box (1) has a pull-out opening on the front side, and a collection box (11) is placed on the bottom inner side of the sorting box (1). The collection box (11) is movably set inside the pull-out opening.

9. The integrated processing device for copper removal and sorting of waste motor stators according to claim 8, characterized in that: A tapered plate (12) is fixedly installed on the top of the second support plate (61).

10. The integrated processing device for copper removal and sorting of waste motor stators according to claim 9, characterized in that: A set of rubber pads is fixedly installed on the side of the two sets of V-shaped clamps (53) that are close to each other.