A busbar winding device

Abstract

The application belongs to the field of busbars, and particularly relates to a busbar winding equipment, which comprises a supporting box, a horizontally arranged hydraulic rod II is fixedly connected to the middle part of the supporting box, the output end of the hydraulic rod II is arranged outside the supporting box, a rotating seat is rotationally connected to the output end of the hydraulic rod II, a vertical disc is arranged on one side of the supporting box, three guide discs are rotationally connected to the side of the vertical disc away from the supporting box, a hydraulic rod I is fixedly connected to the outside of the supporting box, and the hydraulic rod I is arranged in parallel with a hydraulic rod III. Through the simultaneous and same-direction extension and shortening of the hydraulic rod III and the hydraulic rod I, the three guide discs on the top remain stationary, the busbar body can be neatly wound layer by layer on the surface of the winding roller, the neatness of winding is ensured, the busbar body keeps relatively hovering during the whole winding process, the arrangement process is guided by the movement of the winding roller, and thus the fragile busbar body is not damaged.

Description

Technical Field

[0001] This invention belongs to the field of busbars, specifically a busbar winding device. Background Technology

[0002] Busbars, also known as laminated busbars, are multi-layered laminated power module electrical connection components that can connect multiple circuits to a power distribution point. They feature repeatable electrical performance, low inductance, anti-interference, high reliability, space saving, and simple and quick assembly.

[0003] Busbars can be classified into rigid busbars and flexible busbars based on their materials. Flexible busbars are generally made of thin metal sheets, have a certain degree of elasticity, and are relatively long. They are often used in more precise electrical devices with a large surface area and a thin thickness.

[0004] Because the busbar is a thin sheet of metal, if it moves left or right during the winding process, it is easy for the busbar to vibrate, causing it to break or be damaged. At the same time, the busbar cannot be bent or stretched too much, as this can easily induce metal fatigue. Therefore, the winding process is subject to many restrictions, making it difficult to wind the busbar into a neatly arranged roll.

[0005] Therefore, the present invention provides a busbar winding device. Summary of the Invention

[0006] In order to overcome the shortcomings of the prior art, at least one technical problem raised in the background art is solved.

[0007] The technical solution adopted by this invention to solve its technical problem is as follows: A busbar winding device according to this invention includes a support box. A horizontally arranged hydraulic rod two is fixedly connected to the middle of the support box. The output end of the hydraulic rod two protrudes outside the support box. A rotating seat is rotatably connected to the output end of the hydraulic rod two. A vertical disk is arranged on one side of the support box. Three guide disks are rotatably connected to the side of the vertical disk away from the support box. A hydraulic rod one is fixedly connected to the outside of the support box. The hydraulic rod one and hydraulic rod three are arranged parallel to each other. A support frame is fixedly connected to the output end of the hydraulic rod three. The support frame is bent. A drive motor is fixedly connected to the end of the support frame. A winding mechanism is connected between the drive motor and the rotating seat. The busbar body wraps around three guide discs and connects to the outside of the take-up roller. The guide discs allow the busbar body to wrap around them before finally connecting to the outside of the take-up roller at its bottom. The take-up roller has sliding grooves on its surface to clamp the ends of the busbar body. A drive motor then rotates the take-up roller. Simultaneous extension and retraction of hydraulic rods three and one in the same direction, while the three guide discs remain stationary, allow the busbar body to be neatly wound layer by layer on the surface of the take-up roller, ensuring uniformity during winding. Throughout the winding process, the busbar body remains relatively suspended, guided by the movement of the take-up roller, thus preventing damage to the fragile busbar body.

[0008] Preferably, the three guide discs are arranged sequentially from top to bottom. Each guide disc has an inner groove on its outer side, the width of which is the same as the width of the busbar body. A connecting seat is fixed between the guide disc and the support box. A battery for powering the drive motor is fixedly connected to the middle of the support frame. The busbar body is cut parallel to the top of the uppermost guide disc, circles half a turn, then circles the right half of the middle guide disc, and finally circles the left half of the bottom guide disc before being wound up by the take-up roller. This not only ensures the busbar body is taut and wound up, but also, in conjunction with the inner groove on the outer side of the guide disc, restricts the busbar body, preventing it from moving left or right during movement, reducing offset during winding and improving winding quality.

[0009] Preferably, a cutting component is connected below the connecting seat to cut the busbar body. An adhesive component is connected to the bottom of the outer side of the vertical disc to adhere the wound busbar body to the take-up roller. After a roll of take-up roller is wound, the unwound busbar body is cut off by the cutting component, and then the adhesive component adheres the wound busbar body to the take-up roller. At this time, a roll of take-up roller is wound. The hydraulic rod is activated to extend, allowing enough space to remove the take-up roller and replace it with a new take-up roller for repeated winding.

[0010] Preferably, the cutting assembly includes a hydraulic rod three, which is fixedly connected to the middle of the connecting seat. A horizontally arranged parallel seat is fixedly connected to the bottom of the hydraulic rod three. An inner groove is opened on the side of the parallel seat near the vertical plate. An electric telescopic rod two is fixedly connected to the inner side of the inner groove. A set of electric cutting scissors is fixedly connected to the output end of the electric telescopic rod two. Two through holes are opened on the side of the take-up roller near the hydraulic rod two. When the take-up is completed, the hydraulic rod three is activated to extend, allowing the parallel seat to sink. At this time, the inner groove is aligned with the through holes. The electric telescopic rod two is activated to allow the electric cutting scissors to extend and pass through the through holes. When the take-up roller finishes winding, the busbar body is located on the side of the take-up roller near the hydraulic rod two, and the taut and suspended busbar body is aligned with the through holes, which facilitates cutting by the electric cutting scissors.

[0011] Preferably, the output end of the second electric telescopic rod is flat, and there are two electric cutters in a set. The blade of the electric cutter near the first hydraulic rod is fitted with a rubber sleeve, and the through hole is semi-circular. In order to prevent the upper busbar body from shifting under tension after cutting, the two electric cutters press down simultaneously during cutting. One is responsible for cutting, and the other is responsible for clamping the front end of the busbar body, ensuring that the upper unwound busbar body remains taut. When the new take-up roller is placed, the fixed end of the busbar body can be picked up directly and fixed with the new take-up roller for the next round of take-up.

[0012] Preferably, the bonding assembly includes an electric telescopic rod, which is fixed to the bottom outer side of the vertical disc. A bonding block is fixed to the bottom output end of the electric telescopic rod. When a roll of busbar is wound up but not yet cut, the electric telescopic rod is activated to extend downwards. At this time, the bottom of the electric telescopic rod is aligned with the busbar body. During the extension process, the bonding block directly presses against the busbar body. As the bonding block is pressed down, its bottom adheres to the wound busbar body on the outside of the take-up roller. After the bonding block is pressed, a portion of it separates and permanently adheres to the outside of the take-up roller. The remaining bonding block is used for the next bonding process. This operation allows the wound busbar body to remain stably on the outside of the take-up roller, ensuring the integrity of the wound busbar.

[0013] Preferably, the bonding block is composed of multiple overlapping adhesive pads. The bottom surface of the adhesive pad is coated with pressure-sensitive adhesive, and the top surface of the adhesive pad is smooth paper. Multiple spring telescopic rods are fixed to the outer bottom surface of the electric telescopic rod one. The multiple spring telescopic rods surround the outer side of the bonding block, and the rear half of the spring telescopic rods is located in the outer shell of the electric telescopic rod one. When the bonding block is pressed down and contacts the surface of the take-up roller, the pressure-sensitive adhesive at the bottom of the adhesive pad will adhere to the busbar body below. After adhesion, as the electric telescopic rod one rises, because the adhesion force between the upper adhesive pad and the smooth paper is relatively small, the bottom layer of adhesive pad will remain on the take-up roller, completing the separation and adhesion process. The electric telescopic rod one can retract on its own during the extrusion process. After the electric telescopic rod one extends, it can restrict the outer side of the bonding block and prevent the bonding block from shifting.

[0014] Preferably, a recycling bin is provided below the support frame. The top surface of the recycling bin is open, and the bottom surface of the inner wall of the recycling bin is inclined. After a roll of the busbar is wound up, the hydraulic rod extends outward, causing the winding roller to fall into the recycling bin. Since the bottom surface of the inner side of the recycling bin is inclined, the falling winding roller will roll downward, neatly collecting multiple winding rollers.

[0015] Preferably, a docking plate is fixedly connected to the outer side of the take-up roller, and solenoid valves adapted to the docking plate are fixedly connected to the output end of the drive motor and the end of the rotating seat. By extending hydraulic rod two and hydraulic rod one, the take-up roller is moved to the top of the recycling box. When the solenoid valve is released, hydraulic rod two retracts and hydraulic rod one extends, allowing the take-up roller to fall vertically below the take-up roller, which improves the stability of recycling the take-up roller.

[0016] Preferably, the recycling bin is bent, and a cushioning pad is fixed to the bottom surface of the recycling bin. The cushioning pad is located below the take-up roller. A lifting plate is slidably connected to the bottom of the end of the recycling bin away from the cushioning pad. Multiple vertical springs are fixed between the bottom of the lifting plate and the recycling bin. The bent recycling bin allows the take-up roller to move to the vertical area of ​​the recycling bin for storage when it rolls downward, so that more take-up rollers can be received. The cushioning pad is used to reduce the impact force when the take-up roller falls into the recycling bin, and the combination of the lifting plate and vertical springs is used to reduce the impact when the take-up roller falls into the vertical area.

[0017] The beneficial effects of this invention are as follows:

[0018] 1. The busbar winding device of the present invention, by setting guide discs, allows the busbar body to be wound around three guide discs, and finally the bottom is connected to the outside of the winding roller. The surface of the winding roller is provided with sliding grooves for clamping the end of the busbar body. Then, the winding roller is driven by a drive motor to rotate. The hydraulic rod three and hydraulic rod one extend and shorten simultaneously and in the same direction, while the three guide discs above remain stationary, allowing the busbar body to be neatly wound layer by layer on the surface of the winding roller, ensuring the neatness of the winding. Throughout the winding process, the busbar body remains relatively suspended, and the arrangement process is guided by the movement of the winding roller, so as not to damage the fragile busbar body.

[0019] 2. The busbar winding device of the present invention, by setting the guide disc, cuts the busbar body parallel to the top of the uppermost guide disc, circles half a circle, then circles the right half circle of the middle guide disc, and finally circles the left half circle of the bottom guide disc before being wound by the winding roller. This not only ensures the taut winding of the busbar body, but also, in conjunction with the inner groove on the outer side of the guide disc, restricts the busbar body, preventing it from moving left or right during the movement, reducing the offset during the winding process and improving the winding quality. Attached Figure Description

[0020] The invention will now be further described with reference to the accompanying drawings.

[0021] Figure 1 This is a perspective view of the present invention;

[0022] Figure 2 This is a perspective view of the winding roller and support frame of the present invention;

[0023] Figure 3 This is a perspective view of the winding roller and hydraulic rod II of the present invention;

[0024] Figure 4 This is a perspective view of the connector of the present invention;

[0025] Figure 5 This is a perspective view of the electric telescopic rod of the present invention;

[0026] Figure 6 This is a perspective view of the hydraulic rod three of the present invention;

[0027] Figure 7 This is a side view of the electric cutting shears of the present invention;

[0028] In the diagram: 1. Support box; 2. Take-up roller; 3. Recycling box; 4. Buffer pad; 5. Support frame; 6. Hydraulic rod one; 7. Guide plate; 8. Connecting seat; 10. Drive motor; 11. Battery; 12. Hydraulic rod two; 13. Connecting plate; 14. Through hole; 15. Solenoid valve; 16. Rotating seat; 17. Hydraulic rod three; 18. Parallel seat; 19. Electric telescopic rod one; 20. Vertical plate; 21. Spring telescopic rod; 22. Adhesive block; 23. Adhesive pad; 24. Electric cutter; 25. Electric telescopic rod two; 26. Busbar body. Detailed Implementation

[0029] To make the technical means, creative features, objectives and effects of this invention easier to understand, the invention will be further described below in conjunction with specific embodiments.

[0030] like Figures 1 to 3 As shown in the figure, a busbar winding device according to an embodiment of the present invention includes a support box 1. A horizontally arranged hydraulic rod 2 12 is fixedly connected to the middle of the support box 1. The output end of the hydraulic rod 2 12 protrudes outside the support box 1. A rotating seat 16 is rotatably connected to the output end of the hydraulic rod 2 12. A vertical disk 20 is arranged on one side of the support box 1. Three guide disks 7 are rotatably connected to the side of the vertical disk 20 away from the support box 1. A hydraulic rod 1 6 is fixedly connected to the outside of the support box 1. The hydraulic rod 1 6 and the hydraulic rod 3 17 are arranged parallel to each other. A support frame 5 is fixedly connected to the output end of the hydraulic rod 3 17. The support frame 5 is bent. A drive motor 10 is fixedly connected to the end of the support frame 5. A winding roller 2 is connected between the drive motor 10 and the rotating seat 16. The busbar body 26 is connected to the outside of the winding roller 2 after passing around the three guide disks 7.

[0031] During operation, since the bus belt is a thin sheet of metal, if it moves left or right during the winding process, it is easy for the bus belt to vibrate, causing the bus belt to break or be damaged. At the same time, the bus belt cannot be bent or stretched too much, as this can easily induce metal fatigue. Therefore, the winding process is subject to many restrictions, making it difficult to wind the bus belt into a neatly arranged roll.

[0032] With the guide discs 7 in place, the busbar body 26 is wrapped around the three guide discs 7, and finally the bottom is connected to the outside of the take-up roller 2. The surface of the take-up roller 2 is provided with sliding grooves for clamping the end of the busbar body 26. Then, the drive motor 10 drives the take-up roller 2 to rotate. The hydraulic rods 17 and 6 extend and shorten simultaneously and in the same direction. The three guide discs 7 above remain stationary, allowing the busbar body 26 to be neatly wound layer by layer on the surface of the take-up roller 2, ensuring the neatness of the winding. Throughout the winding process, the busbar body 26 remains relatively suspended, and the arrangement process is guided by the movement of the take-up roller 2, so as not to damage the fragile busbar body 26.

[0033] like Figures 1 to 3 As shown, the three guide discs 7 are arranged from top to bottom. The outer side of the guide disc 7 is provided with an inner groove. The width of the inner groove is the same as the width of the busbar body 26. A connecting seat 8 is fixed between the guide disc 7 and the support box 1. A battery 11 that supplies power to the drive motor 10 is fixed in the middle of the support frame 5.

[0034] During operation, the busbar body 26 is cut parallel to the top guide plate 7, circles half a circle, then circles the right half of the middle guide plate 7, and finally circles the left half of the bottom guide plate 7 before being wound up by the take-up roller 2. This not only ensures the taut winding of the busbar body 26, but also, in conjunction with the inner groove on the outer side of the guide plate 7, restricts the busbar body 26, preventing it from moving left or right during the movement, reducing the offset during the winding process and improving the winding quality.

[0035] like Figures 1 to 4 As shown, a cutting component is connected below the connecting seat 8. The cutting component is used to cut the busbar body 26. An adhesive component is connected to the bottom of the outer side of the vertical disc 20. The adhesive component is used to adhesive the wound busbar body 26 to the winding roller 2.

[0036] During operation, once a roll of take-up roller 2 has been wound up, the unwound busbar body 26 is cut off by the cutting component. Then, the adhesive component will stick the wound busbar body 26 onto the take-up roller 2. At this point, a roll of take-up roller 2 has been wound up. The hydraulic rod 6 is then activated to extend, allowing the take-up roller 2 to have enough space to be removed and replaced with a new take-up roller 2 for repeated winding.

[0037] like Figures 4 to 7As shown, the cutting assembly includes a hydraulic rod 17, which is fixed to the middle of the connecting seat 8. A horizontally arranged parallel seat 18 is fixed to the bottom of the hydraulic rod 17. An inner groove is opened on the side of the parallel seat 18 near the vertical plate 20. An electric telescopic rod 25 is fixed to the inner side of the inner groove. A set of electric cutting scissors 24 is fixed to the output end of the electric telescopic rod 25. Two through holes 14 are opened on the side of the take-up roller 2 near the hydraulic rod 12.

[0038] After winding is completed, hydraulic rod 17 is extended to lower parallel seat 18. At this time, the inner groove is aligned with the through hole 14. Electric telescopic rod 25 is activated to extend electric cutter 24 and pass through through hole 14. When winding roller 2 finishes winding, the busbar body 26 is located on the side of winding roller 2 close to hydraulic rod 12, and the taut and suspended busbar body 26 is aligned with through hole 14, which facilitates cutting by electric cutter 24.

[0039] like Figures 4 to 7 As shown, the output end of the electric telescopic rod 25 is flat, and there are two electric cutting scissors 24. The blade of the electric cutting scissors 24 near the hydraulic rod 6 is fitted with a rubber sleeve, and the through hole 14 is semi-circular.

[0040] During operation, in order to prevent the upper busbar body 26 from shifting under tension after cutting, two electric cutters 24 press down simultaneously during cutting. One is responsible for cutting, and the other is responsible for clamping the front end of the busbar body 26, ensuring that the upper unwound busbar body 26 remains taut. When the new take-up roller 2 is placed, the fixed end of the busbar body 26 can be picked up directly and fixed with the new take-up roller 2 for the next round of take-up.

[0041] like Figures 4 to 6 As shown, the adhesive assembly includes an electric telescopic rod 19, which is fixed to the bottom of the outer side of the vertical disc 20, and an adhesive block 22 is fixed to the bottom output end of the electric telescopic rod 19.

[0042] During operation, when a roll of busbar body 26 is wound up but not yet cut, the electric telescopic rod 19 is activated to extend downwards. At this time, the bottom of the electric telescopic rod 19 is aligned with the busbar body 26. During the extension process, the bonding block 22 directly presses against the busbar body 26. As the bonding block 22 is pressed down, the bottom of the bonding block 22 will bond with the wound busbar body 26 on the outside of the take-up roller 2. After the bonding block 22 is pressed, part of the bonding block 22 will separate and permanently bond to the outside of the take-up roller 2. The remaining bonding block 22 is used for the next bonding process. This operation allows the wound busbar body 26 to remain stably on the outside of the take-up roller 2, ensuring the integrity of the wound busbar.

[0043] like Figures 4 to 6 As shown, the bonding block 22 is composed of multiple overlapping adhesive pads 23. The bottom surface of the adhesive pad 23 is coated with pressure-sensitive adhesive, and the top surface of the adhesive pad 23 is smooth paper. Multiple spring telescopic rods 21 are fixed to the outer bottom surface of the electric telescopic rod 19. The multiple spring telescopic rods 21 surround the outer side of the bonding block 22, and the rear half of the spring telescopic rods 21 is located in the outer shell of the electric telescopic rod 19.

[0044] During operation, when the bonding block 22 is pressed down and contacts the surface of the take-up roller 2, the pressure-sensitive adhesive at the bottom of the adhesive pad 23 will adhere to the busbar body 26 below. After adhesion, as the electric telescopic rod 19 rises, because the adhesion force between the upper adhesive pad 23 and the smooth paper is relatively small, the bottom adhesive pad 23 will remain on the take-up roller 2, completing the separation and adhesion process. The electric telescopic rod 19 can retract on its own during the extrusion process. After the electric telescopic rod 19 extends, it can restrict the outer side of the bonding block 22 and prevent the bonding block 22 from shifting.

[0045] like Figures 1 to 2 As shown, a recycling bin 3 is provided below the support frame 5. The top surface of the recycling bin 3 is open, and the bottom surface of the inner wall of the recycling bin 3 is inclined.

[0046] During operation, after a roll of the busbar body 26 is wound up, the hydraulic rod 6 extends outward, causing the winding roller 2 to fall into the recycling box 3. Since the inner bottom surface of the recycling box 3 is inclined, the falling winding roller 2 will roll downward, neatly collecting multiple winding rollers 2.

[0047] like Figures 1 to 3 As shown, a docking plate 13 is fixedly connected to the outer side of the take-up roller 2. The output end of the drive motor 10 and the end of the rotating seat 16 are both fixedly connected to a solenoid valve 15 that is compatible with the docking plate 13. During operation, the take-up roller 2 is moved above the recycling box 3 by the extension of the hydraulic rod 2 12 and the hydraulic rod 1 6. At the same time as the solenoid valve 15 is released, the hydraulic rod 2 12 retracts and the hydraulic rod 1 6 extends, allowing the take-up roller 2 to fall vertically below the take-up roller 2, which improves the stability of the recycling take-up roller 2.

[0048] like Figures 1 to 2 As shown, the recycling bin 3 is bent, and a buffer pad 4 is fixed to the bottom surface of the recycling bin 3. The buffer pad 4 is located below the winding roller 2. A lifting plate is slidably connected to the bottom of the recycling bin 3 away from the buffer pad 4. Multiple vertical springs are fixed between the bottom of the lifting plate and the recycling bin 3.

[0049] During operation, the bent recycling bin 3 allows the take-up roller 2 to move to the vertical area of ​​the recycling bin 3 for storage when it rolls downwards, thus accommodating more take-up rollers 2. The buffer pad 4 is designed to mitigate the impact when the take-up roller 2 falls into the recycling bin 3, while the combination of the lifting plate and the vertical spring is used to mitigate the impact when the take-up roller 2 falls into the vertical area.

[0050] During operation, the busbar body 26 is wound around the three guide discs 7 by the guide discs 7, and finally connected to the outside of the take-up roller 2 at the bottom. The surface of the take-up roller 2 is provided with sliding grooves for clamping the end of the busbar body 26. Then, the take-up roller 2 is rotated by the drive motor 10. The hydraulic rods 17 and 6 extend and shorten simultaneously and in the same direction. The three guide discs 7 above remain stationary, so that the busbar body 26 can be neatly wound layer by layer on the surface of the take-up roller 2, ensuring the neatness of the winding. The busbar body 26 remains relatively suspended throughout the winding process, and the arrangement process is guided by the movement of the take-up roller 2, so as not to damage the fragile busbar body 26.

[0051] The busbar body 26 is cut parallel to the top of the guide plate 7, goes around half a circle, then around the right half of the middle guide plate 7, and finally around the left half of the bottom guide plate 7 before being wound up by the take-up roller 2. This not only ensures that the busbar body 26 is taut and wound up, but also, in conjunction with the inner groove on the outside of the guide plate 7, restricts the busbar body 26 so that it cannot move left or right during the movement, reducing the offset during the winding process and improving the winding quality.

[0052] After a roll of take-up roller 2 is finished being wound up, the unwound busbar body 26 is cut off by the cutting assembly. Then the adhesive assembly will stick the wound busbar body 26 onto the take-up roller 2. At this time, a roll of take-up roller 2 is finished being wound up. The hydraulic rod 6 is activated to extend, so that the take-up roller 2 has enough space to be removed and replaced with a new take-up roller 2 for repeated winding.

[0053] After winding is completed, hydraulic rod 17 is extended to lower parallel seat 18. At this time, the inner groove is aligned with the through hole 14. Electric telescopic rod 25 is activated to extend electric cutter 24 and pass through through hole 14. When winding roller 2 finishes winding, the busbar body 26 is located on the side of winding roller 2 close to hydraulic rod 12, and the taut and suspended busbar body 26 is aligned with through hole 14, which facilitates cutting by electric cutter 24.

[0054] To prevent the upper busbar body 26 from shifting under tension after cutting, two electric cutters 24 press down simultaneously during cutting. One cuts the busbar body 26, while the other clamps the front end of the busbar body 26, ensuring that the upper unwound busbar body 26 remains taut. Once the new take-up roller 2 is in place, the fixed end of the busbar body 26 can be picked up directly and fixed to the new take-up roller 2 for the next round of winding.

[0055] When a roll of busbar body 26 is wound up and has not been cut, the electric telescopic rod 19 is activated to extend downwards. At this time, the bottom of the electric telescopic rod 19 is aligned with the busbar body 26. During the extension process, the bonding block 22 directly presses against the busbar body 26. As the bonding block 22 is pressed down, the bottom of the bonding block 22 will be bonded to the outside of the winding roller 2 where the busbar body 26 is wound up. After the bonding block 22 is pressed, part of the bonding block 22 will be separated and permanently bonded to the outside of the winding roller 2. The remaining bonding block 22 is used for the next bonding process. This operation allows the wound busbar body 26 to remain stably on the outside of the winding roller 2, ensuring the integrity of the wound body.

[0056] When the bonding block 22 is pressed down and contacts the surface of the take-up roller 2, the pressure-sensitive adhesive at the bottom of the adhesive pad 23 will adhere to the busbar body 26 below. After adhesion, as the electric telescopic rod 19 rises, the adhesive pad 23 at the bottom layer will remain on the take-up roller 2 due to the weak adhesion between the upper adhesive pad 23 and the smooth paper, thus completing the separation and adhesion process. The electric telescopic rod 19 can retract on its own during the extrusion process. After the electric telescopic rod 19 extends, it can restrict the outer side of the bonding block 22 and prevent the bonding block 22 from shifting.

[0057] After a roll of the busbar body 26 is wound up, as the hydraulic rod 6 extends outward, the winding roller 2 falls into the recycling box 3. Since the inner bottom surface of the recycling box 3 is inclined, the falling winding roller 2 will roll downwards to collect multiple winding rollers 2 neatly.

[0058] By extending hydraulic rod 12 and hydraulic rod 6, the take-up roller 2 is moved above the recycling box 3. At the same time as releasing the solenoid valve 15, hydraulic rod 12 retracts and hydraulic rod 6 extends, allowing the take-up roller 2 to fall vertically below the take-up roller 2, which improves the stability of the recycling take-up roller 2.

[0059] The bent recycling bin 3 allows the take-up roller 2 to move to the vertical area of ​​the recycling bin 3 for storage when it rolls downwards, which can receive more take-up rollers 2. The buffer pad 4 is used to reduce the impact force when the take-up roller 2 falls into the recycling bin 3, and the combination of the lifting plate and the vertical spring is used to reduce the impact when the take-up roller 2 falls into the vertical area.

[0060] The foregoing has shown and described the basic principles, main features, and advantages of the present invention. Those skilled in the art should understand that the present invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of the invention. Various changes and modifications can be made to the invention without departing from its spirit and scope, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of protection of the present invention is defined by the appended claims and their equivalents.

Claims

1. A busbar rewinding device, characterized in that: The system includes a support box (1), a horizontally arranged hydraulic rod two (12) fixedly connected to the middle of the support box (1), the output end of the hydraulic rod two (12) protruding outside the support box (1), the output end of the hydraulic rod two (12) rotatably connected to a rotating seat (16), a vertical disk (20) is provided on one side of the support box (1), three guide disks (7) are rotatably connected to the side of the vertical disk (20) away from the support box (1), a hydraulic rod one (6) fixedly connected to the outside of the support box (1), the hydraulic rod one (6) and the hydraulic rod three (17) are arranged in parallel, a support frame (5) is fixedly connected to the output end of the hydraulic rod one (6), the support frame (5) is arranged in a bent shape, a drive motor (10) is fixedly connected to the end of the support frame (5), a take-up roller (2) is connected between the drive motor (10) and the rotating seat (16), and the busbar body (26) is connected to the outside of the take-up roller (2) after passing around the three guide disks (7). The three guide discs (7) are arranged from top to bottom. The guide discs (7) have an inner groove on their outer side. The width of the inner groove is the same as the width of the busbar body (26). A connecting seat (8) is fixed between the guide discs (7) and the support box (1). A battery (11) that supplies power to the drive motor (10) is fixed in the middle of the support frame (5). A cutting component is connected below the connecting seat (8), which is used to cut the busbar body (26). An adhesive component is connected to the bottom of the outer side of the vertical disc (20), which is used to adhesive the wound busbar body (26) into the winding roller (2). The cutting assembly includes a hydraulic rod three (17), which is fixed to the middle of the connecting seat (8). A horizontally arranged parallel seat (18) is fixed to the bottom of the hydraulic rod three (17). An inner groove is opened on the side of the parallel seat (18) near the vertical plate (20). An electric telescopic rod two (25) is fixed to the inner side of the inner groove. A set of electric cutting scissors (24) is fixed to the output end of the electric telescopic rod two (25). Two through holes (14) are opened on the side of the winding roller (2) near the hydraulic rod two (12).

2. The busbar winding device according to claim 1, characterized in that: The output end of the electric telescopic rod two (25) is flat. There are two electric cutting shears (24). The blade of the electric cutting shears (24) near the hydraulic rod one (6) is fitted with a rubber sleeve. The through hole (14) is semi-circular.

3. The busbar rewinding device according to claim 2, characterized in that: The adhesive assembly includes an electric telescopic rod (19), which is fixed to the bottom of the outside of the vertical disc (20), and an adhesive block (22) is fixed to the bottom output end of the electric telescopic rod (19).

4. A busbar rewinding device according to claim 3, characterized in that: The bonding block (22) is composed of multiple overlapping adhesive pads (23). The bottom surface of the adhesive pad (23) is covered with pressure-sensitive adhesive, and the top surface of the adhesive pad (23) is smooth paper. Multiple spring telescopic rods (21) are fixed to the outer bottom surface of the electric telescopic rod (19). The multiple spring telescopic rods (21) surround the outside of the bonding block (22), and the rear half of the spring telescopic rods (21) is located in the outer shell of the electric telescopic rod (19).

5. A busbar rewinding device according to claim 4, characterized in that: A recycling bin (3) is provided below the support frame (5). The top surface of the recycling bin (3) is open, and the bottom surface of the inner wall of the recycling bin (3) is inclined.

6. A busbar rewinding device according to claim 5, characterized in that: The outer side of the take-up roller (2) is fixedly connected to a docking plate (13), and the output end of the drive motor (10) and the end of the rotating seat (16) are both fixedly connected to a solenoid valve (15) that is compatible with the docking plate (13).

7. A busbar rewinding device according to claim 6, characterized in that: The recycling bin (3) is bent. A buffer pad (4) is fixed to the bottom of the inside of the recycling bin (3). The buffer pad (4) is located below the winding roller (2). A lifting plate is slidably connected to the bottom of the recycling bin (3) away from the buffer pad (4). Multiple vertical springs are fixed between the bottom of the lifting plate and the recycling bin (3).

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