Automatic thread trimming and stripping machine with inductance
By designing an automatic wire cutting and strip stacking machine, the automatic cutting and flipping of the connection components are used to realize the automated processing of inductors, which solves the problem of inconsistent lead wire cutting, improves efficiency and reduces labor costs.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- SUMIDA ELECTRIC CHANGDE CO LTD
- Filing Date
- 2025-07-07
- Publication Date
- 2026-06-19
AI Technical Summary
In the current inductor processing, inconsistent lead wire cutting leads result in low work efficiency, high labor costs, and an inability to achieve automated processing.
The automatic wire cutting and strip feeding machine for inductors is designed with an automatic cutting mechanism, an automatic strip feeding mechanism, a feeding guide rail and a conveying guide rail, combined with a negative pressure adsorption component, a flipping and contacting component and a receiving magnetic suction component, to realize the automatic flipping and strip feeding of inductors and the automatic cutting of leads.
This achieved consistent lead length, improved processing efficiency, reduced manual intervention, and enabled automated inductor processing.
Smart Images

Figure CN224384071U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of inductor processing equipment, specifically to an automatic wire cutting, strip passing, and panel assembling machine for inductors. Background Technology
[0002] After the inductor core and ring are assembled, the leads need to be cut, followed by stripping and board arrangement. Currently, lead cutting is mainly done manually. The inductor is removed from the fixture, flipped over, and placed in the loading plate for board arrangement, thus achieving stripping. After stripping, the inductor is conveyed backward, and adhesive is applied to the back of the inductor to bond the core and ring. This inductor processing method has drawbacks. Manual cutting cannot guarantee consistent lead lengths, making subsequent soldering to the pins inconvenient. This results in low efficiency, high labor costs, and the need for manual intervention in wire cutting and stripping, preventing automated inductor processing. Summary of the Invention
[0003] To address the shortcomings of the existing technology, this utility model proposes an automatic wire cutting and strip-passing machine for inductors. This machine facilitates automatic cutting of the wire ends to ensure the length of the lead wires. By automatically flipping and passing the inductors through strips, no manual intervention is required. This improves efficiency and allows the equipment to replace manual labor, achieving automated processing of inductor wire cutting and strip passing.
[0004] To achieve the above objectives, the present invention provides an automatic wire cutting and strip feeding machine for inductors, comprising an automatic cutting mechanism, an automatic strip feeding mechanism, a feeding guide rail and a conveying guide rail. The feeding guide rail and the conveying guide rail are both mounted on a table. Automatic cutting mechanisms are provided on both sides of the feeding guide rail. A pressure fixture assembly is provided above the feeding guide rail. A fixed fixture assembly is installed on the feeding guide rail. A conveying guide rail is provided on one side of the feeding guide rail. An automatic strip feeding mechanism is provided above the feeding guide rail and the conveying guide rail.
[0005] The automatic conveying mechanism includes a negative pressure adsorption component, a flipping and contacting component, and a receiving magnetic suction component. An installation plate is provided above the feeding guide rail and the conveying guide rail. The negative pressure adsorption component and the receiving magnetic suction component are arranged opposite to each other and are rotatably connected to the installation plate. The installation plate is provided with flipping and contacting components that are connected to the negative pressure adsorption component and the receiving magnetic suction component respectively. The flipping and contacting components enable the negative pressure adsorption component and the receiving magnetic suction component to rotate 90°, and both the negative pressure adsorption component and the receiving magnetic suction component can be raised and lowered.
[0006] Preferably, the negative pressure adsorption assembly includes a first rotating seat, a first lifting assembly, and a negative pressure adsorption head. The first rotating seat is rotatably connected to the mounting plate, and the flipping docking assembly docks with the first rotating seat. The flipping docking assembly enables the first rotating seat to rotate 90°. A lifting seat is provided below the first rotating seat, and multiple adsorption heads are installed side by side on the lifting seat. The first lifting assembly is provided between the lifting seat and the first rotating seat.
[0007] Preferably, the continuous receiving assembly includes a second rotating seat, a second lifting assembly, and a magnetic block. The magnetic block is located below the second rotating seat, and the second lifting assembly is located between the magnetic block and the second rotating seat. The second rotating seat is rotatably connected to the mounting plate, and the flipping receiving assembly is connected to the second rotating seat and drives the second rotating seat to rotate.
[0008] Preferably, the flipping contact assembly includes a rotating shaft, a limiting assembly, and a sector-shaped piece. The sector-shaped piece is fixed on the outer circumference of the rotating shaft. A limiting assembly is provided on one side of the rotating shaft. The limiting assembly includes a fixed seat and limit switches. A fixed seat is installed on the mounting base. Two sets of limit switches are installed on the fixed seat. The rotating shaft rotates to make the two sides of the sector-shaped piece contact the limit switches. When the sector-shaped piece contacts the limit switches, the rotating shaft rotates in the direction of rotation. A lifting assembly is installed between the mounting plate and the sector-shaped piece. The lifting assembly is eccentrically connected to the sector-shaped piece.
[0009] Preferably, a rotating rod is fixed to the top of the negative pressure adsorption head. The rotating rod passes through the lifting seat and is rotatably connected to the lifting seat. A gear is fixed on each rotating rod. A rack is installed on the lifting seat by sliding fit. The gear on each rotating rod meshes with the rack. A translation cylinder is set between the lifting seat and the rack. The translation cylinder realizes the translation of the rack, thus realizing the 45° rotation of the inductor.
[0010] Preferably, the automatic cutting mechanism includes a thread tail trimming assembly, a thread tail clamping assembly, and a three-axis motion platform. The three-axis motion platform is mounted on the platform, and a thread trimming seat is mounted on the platform. Two sets of opposing thread tail trimming assemblies are mounted below the thread trimming seat. The thread tail trimming assemblies slide with the thread trimming seat, and a locking assembly is provided between the thread trimming seat and the thread tail trimming assemblies to adjust the distance between the two sets of thread tail trimming assemblies. A thread tail clamping assembly is mounted on the outside of each set of thread tail trimming assemblies to clamp the end of the thread before cutting, thus facilitating the cutting of the thread tail.
[0011] Preferably, the fixture assembly includes a stop block and a clamping block. A retractable stop block is provided on one side of the feed guide rail. When the stop block extends above the feed guide rail, it restricts the conveying of the fixture. Clamping blocks are provided on both sides of the feed guide rail. Cylinders are installed on the clamping blocks and the outer wall of the feed guide rail, and the clamping blocks are extended and retracted by the cylinders. A slot is opened on the clamping block. When the clamping block closes, the fixture is inserted into the slot. An inclined groove is fixed on the clamping block. A wiring tail groove is installed on the table, and the inclined groove extends above the wiring tail groove. The pressure fixture assembly includes a pressure bar, a pressure block, and an elastic telescopic rod. The pressure bar is located directly above the conveying guide rail. A cylinder is provided between the pressure bar and the outer wall of the feed guide rail, and the pressure bar is raised and lowered by the cylinder. Multiple pressing blocks are arranged side by side under the pressure bar. An elastic telescopic rod is fixed on the top of each pressing block. The elastic telescopic rod passes through the pressure bar, and a spring is sleeved on the elastic telescopic rod to press the pressing block down.
[0012] Preferably, there are two conveying rails arranged side by side, with interconnected gaps at both ends of the two conveying rails. Pushing components are provided at the gaps to switch the conveying rails.
[0013] Compared with the prior art, the advantages of this utility model are:
[0014] This enables automated cutting and strip feeding operations, making it suitable for automated inductor manufacturing.
[0015] During the stripping process, the inductor is flipped over and rotated to facilitate subsequent processing.
[0016] When cutting the wire, press the inductor firmly and collect the cut wire tail directly. Attached Figure Description
[0017] Figure 1 This is a perspective view of the present invention.
[0018] Figure 2 This is a schematic diagram of the pressure fixture assembly, the fixed fixture assembly, the inclined groove, and the feed guide rail of this utility model.
[0019] Figure 3 This is a schematic diagram of the pressure fixture assembly, the fixed fixture assembly, and the feed guide rail of this utility model.
[0020] Figure 4 This is a schematic diagram of the automatic cutting mechanism of this utility model.
[0021] Figure 5 This is a schematic diagram of the automatic strip feeding mechanism of this utility model.
[0022] Figure 6 This is the front view of the automatic bar-passing mechanism of this utility model.
[0023] Figure 7 This is a schematic diagram of the flip-up docking component of this utility model.
[0024] Figure 8 This is a top view of the utility model's conveyor rail and pushing assembly.
[0025] The components include: 1. Automatic cutting mechanism; 2. Thread tail trimming assembly; 3. Thread tail clamping assembly; 4. Three-axis motion platform; 5. Thread trimming seat; 6. Locking assembly; 7. Automatic strip feeding mechanism; 8. Negative pressure adsorption assembly; 9. First rotating seat; 10. First lifting assembly; 11. Negative pressure adsorption head; 12. Lifting seat; 13. Flipping and connecting assembly; 14. First rotating shaft; 14.1. Second rotating shaft; 15. Limiting assembly; 16. Fixed seat; 17. Limit switch; 18. Fan-shaped plate; 19. Lifting assembly; 20. Material receiving magnetic suction assembly; 21. Second rotating... 22. Rotary seat, 23. Second lifting assembly, 24. Magnetic block, 25. Feeding guide rail, 26. Conveying guide rail, 27. Table surface, 28. Pressing fixture assembly, 29. Pressing strip, 30. Pressing block, 31. Elastic telescopic rod, 32. Pressing block, 33. Fixed fixture assembly, 34. First stop block, 35. Clamping block, 36. Slot, 37. Wiring tail slot, 39. Material plate, 40. Mounting plate, 41. Rotating rod, 42. Gear, 43. Rack, 44. Translation cylinder, 45. Notch, 46. Pushing assembly, 47. Second stop block. Detailed Implementation
[0026] The present invention will now be further described with reference to the accompanying drawings.
[0027] like Figure 1-8The automatic wire cutting and strip feeding machine for inductors includes an automatic cutting mechanism 1, an automatic strip feeding mechanism 7, a feeding guide rail 24, and a conveying guide rail 25. Both the feeding guide rail 24 and the conveying guide rail 25 are mounted on a table 26. Each feeding guide rail 24 and the conveying guide rail 25 includes a conveyor belt and clamping plates. The clamping plates are bolted to the table 26. Rollers driven by a motor are mounted on the two clamping plates. The conveyor belt is looped around the two rollers, and the outer walls of the conveyor belt contact the inner walls of the clamping plates. The feeding guide rail 24 and the conveying guide rail 25 are arranged side-by-side. An automatic cutting mechanism 1 is installed on the table 26 on both sides of the feeding guide rail 24. The automatic cutting mechanism 1 cuts the wire ends of the inductors on both sides of the fixture, facilitating subsequent processing. A pressure fixture assembly 27 is installed above the feeding guide rail 24 to press the inductors on the feeding guide rail 24, preventing them from slipping during cutting. When the wire jumps, the motor of the conveyor belt is de-energized when the pressure fixture assembly 27 presses down, and the conveyor belt stops conveying. A fixed fixture assembly 32 is installed on the feed guide rail 24. Since the automatic cutting mechanism 1 needs to cut the wire tail, this ensures the position of the automatic cutting mechanism 1 and the inductor. When the fixture holding the inductor is conveyed to the underside of the automatic cutting mechanism 1, the fixed fixture assembly 32 extends into the feed guide rail 24 to block the fixture from being conveyed backward. Then the pressure fixture assembly 27 presses the fixture in the middle. A conveying guide rail 25 is set on one side of the feed guide rail 24. An automatic strip feeding mechanism 7 is set above the feed guide rail 24 and the conveying guide rail 25. A material plate 39 conveyed on the conveying guide rail 25 is placed on the conveying guide rail 25. The automatic strip feeding mechanism 7 clamps the inductor on the fixture on the feed guide rail 24 and places it on the material plate 39 on the conveying guide rail 25.
[0028] The automatic conveying mechanism 7 includes a negative pressure adsorption component 8, a flipping and contacting component 13, and a receiving magnetic suction component 20. An mounting plate 40 is installed above the feeding guide rail 24 and the conveying guide rail 25, and the bottom of the mounting plate 40 is fixed to the table surface 26 by bolts. The negative pressure adsorption component 8 and the receiving magnetic suction component 20 are arranged opposite each other and are rotatably connected to the mounting plate 40, allowing them to rotate. The mounting plate 40 is equipped with the flipping and contacting component 13, which is connected to both the negative pressure adsorption component 8 and the receiving magnetic suction component 20, enabling them to rotate 90°. Both the negative pressure adsorption component 8 and the receiving magnetic suction component 20 can be raised and lowered during operation. When the fixture is conveyed directly below the negative pressure adsorption component 8, the negative pressure adsorption component 8 descends to adsorb the inductor on the fixture. Then, the negative pressure adsorption component 8 rises and rotates 90° clockwise under the drive of the flipping and contacting component 13. The receiving magnetic suction component 20 rotates 90° counterclockwise under the drive of the flipping and contacting component 13. Then, the negative pressure adsorption component 8 and the receiving magnetic suction component 20 rise simultaneously. In this way, the inductor on the negative pressure adsorption component 8 presses against the receiving magnetic suction component 20. The negative pressure adsorption component 8 is in contact with the negative pressure state and loses its adsorption on the inductor. At the same time, the receiving magnetic suction component 20 magnetically attracts the inductor. Then, the negative pressure adsorption component 8 and the receiving magnetic suction component 20 return to their original positions through rotation. The receiving magnetic suction component 20 descends and places the inductor on the rack, thus automatically completing the flipping and passing of the inductor.
[0029] There are two conveying guides 25 arranged side by side. The two conveying guides 25 respectively convey inductive material plates 39 and empty material plates 39. There are interconnected notches 45 on the clamping plates at both ends of the two conveying guides 25. A pushing component 46 is fixed to the clamping plate on the left side of the notch 45 by bolts. The conveying guide 25 is switched by the pushing component 46, which is a push plate driven by a cylinder. The cylinder body is fixed to the clamping plate by bolts. The push plate is fixed to the piston rod of the cylinder by bolts. The push plate pushes the material plate 39 on one conveying guide 25 to the next conveying guide 25.
[0030] The fixture assembly 32 includes a first stop 33 and clamping blocks 34. A retractable first stop 33 is provided on one side of the feed guide rail 24. A cylinder is bolted to the outer side of the clamping plate, and the first stop 33 is fixed to the piston rod of the cylinder by bolts. When the cylinder is raised, the first stop 33 extends above the feed guide rail 24, restricting the fixture from being conveyed backward along the feed guide rail 24. Clamping blocks 34 are provided on the left and right sides of the feed guide rail 24. Clamping blocks 34 are bolted to the outer wall of the feed guide rail 24 (i.e., the outer wall of the clamping plate of the feed guide rail 24). The cylinder's piston rod is fixed to the outer wall of the clamping block 34 by bolts. The clamping block 34 is vertically offset from the first stop block 33. The cylinder enables the clamping block 34 to extend and retract. A slot 35 is provided on the inner side of the clamping block 34. When the clamping block 34 closes, it extends into the feed guide rail 24, and the fixture is engaged in the slot 35, thus restricting the fixture's back-and-forth movement on the feed guide rail 24. An inclined groove 36 is fixed to each clamping block 34 by bolts. A wiring tail groove 37 is installed on the table 26 by bolts, and the inclined groove 36 extends into the wiring tail groove 37. When wire cutting is required, clamping block 34 extends into the feed guide rail 24 to clamp the fixture. Simultaneously, the inductor wire tail is directly above the inclined groove 36. When the limit cut is performed, the wire tail falls onto the inclined groove 36 and slides down into the wire tail groove 37, thus completing the collection. The pressure fixture assembly 27 includes a pressure bar 28, a pressure block 29, and an elastic telescopic rod 30. The pressure bar 28 is located directly above the conveying guide rail 25. A cylinder is fixed between the pressure bar 28 and the outer wall of the feed guide rail 24 (i.e., the outer wall of the clamping plate of the feed guide rail 24) by bolts. The cylinder body is secured by bolts. On the outer wall of the clamping plate, the piston rod of the cylinder is fixed to the bottom of the pressure bar 28 by bolts. The pressure bar 28 is raised and lowered by the cylinder. Multiple pressing blocks 31 are arranged side by side under the pressure bar 28. An elastic telescopic rod 30 is fixed to the top of each pressing block 31 by bolts. The elastic telescopic rod 30 passes through the pressure bar 28 and moves up and down along the pressure bar 28. A spring is sleeved on the elastic telescopic rod 30. The spring presses the elastic telescopic rod 30 down. At the same time, the elastic telescopic rod 30 presses down the pressing block 31. This prevents the inductor from jumping up and down when cutting the wire.
[0031] The automatic cutting mechanism 1 includes a thread tail trimming assembly 2, a thread tail clamping assembly 3, and a three-axis motion platform 4. The three-axis motion platform 4, specifically an XYZ three-axis motion platform 4, is installed on the table 26 via bolts. A thread trimming seat 5 is bolted onto the three-axis motion platform 4. There are two sets of thread trimming seats 5, each set facing each other. Below each set of thread trimming seats 5, two sets of opposing thread tail trimming assemblies 2 are installed. A slider is fixed to the thread tail trimming assembly 2 via bolts. A groove is formed on the thread trimming seat 5, and the slider moves left and right within the groove. A locking assembly 6, which is a bolt, is provided between the thread trimming seat 5 and the thread tail trimming assembly 2. The bolt passes through the thread trimming seat 5 and is threaded into the thread tail trimming assembly 2. A screw feed is provided on the thread trimming seat 5. The sliding oblong hole locks the wire cutter base 5 and the wire cutter tail assembly 2 when the bolt is tightened. When the bolt is loosened, the wire cutter tail assembly 2 moves on the wire cutter base 5, thus adjusting the distance between the two sets of wire cutter tail assemblies 2 and adjusting the length of the lead wire after cutting the wire tail. A wire clamping tail assembly 3 is installed on the outside of each set of wire cutter tail assemblies 2 by bolt fastening. Before cutting the wire, the end of the wire tail is clamped, which makes it easier to cut the wire tail. Both the wire cutter tail assembly 2 and the wire clamping tail assembly 3 are finger cylinders. The scissors are fixed to the clamping arm of the wire cutter tail assembly by bolt fastening. The clamping arm of the wire clamping tail assembly 3 is fixed to the clamping arm by bolt fastening. The clamping arm is close to the outer side of the scissors. Before cutting the wire tail, the wire tail is clamped by the clamping arm. Then the wire cutter tail assembly 2 closes the scissors. This clamps both ends of the lead wire to be cut, which makes it easier to cut the wire tail.
[0032] After the limit shearing is completed, the clamp is released, and at the same time the first stop 33 exits the feed guide rail 24. The fixture is conveyed backward. A cylinder is bolted to the feed guide rail 24. A second stop 47 is fixed to the piston rod of the cylinder by bolts. The second stop 47 is extended into the feed guide rail 24 by the lifting of the cylinder and stops the conveying of the fixture. When the fixture conveyor belt is directly below the negative pressure adsorption component 8, the rear end of the fixture abuts against the second stop 47.
[0033] The negative pressure adsorption assembly 8 includes a first rotating seat 9, a first lifting assembly 10, and negative pressure adsorption heads 11. The first rotating seat 9 is rotatably connected to a mounting plate 40. A first rotating shaft 14 is fixed to the first rotating seat 9 by welding. The first rotating shaft 14 passes through the mounting plate 40, and the mounting plate 40 rotatably engages with the first rotating seat. A flipping contact assembly 13 is connected to the first rotating shaft 14 on the first rotating seat 9, enabling the first rotating seat 9 to rotate 90°. A lifting seat 12 is located below the first rotating seat 9, and multiple adsorption heads are mounted side-by-side on the lifting seat 12. A first lifting assembly 10 is fixed between the lifting seat 12 and the first rotating seat 9 by bolts. The first lifting assembly 10 is a cylinder. The lifting seat 12 has a groove. A guide rail that is inserted into the groove is fixed on the first rotating seat 9 by integral molding. In this way, the lifting seat 12 moves up and down along the first rotating seat 9. The first rotating seat 9 is fixed to the cylinder body of the first lifting assembly 10 by bolts. The piston rod of the first lifting assembly 10 is fixed to the top of the lifting seat 12 by bolts. In this way, the lifting seat 12 is raised and lowered by the first lifting assembly 10, thereby realizing the raising and lowering of the negative pressure suction head 11.
[0034] The continuous receiving assembly includes a second rotating seat 21, a second lifting assembly 22, and a magnetic block 23. The magnetic block 23 is located below the second rotating seat 21, and the second lifting assembly 22 is located between the magnetic block 23 and the second rotating seat 21. The second lifting assembly 22 is a cylinder, and its cylinder body is bolted to the second rotating seat 21. The piston rod of the second lifting assembly 22 is bolted to the magnetic block 23, which is an electromagnet. When energized, the magnetic block 23 becomes magnetic and attracts inductors. A second rotating shaft 14.1 is fixed to the second rotating seat 21 by welding. The second rotating shaft 14.1 passes through the mounting plate 40 and rotates with the mounting plate 40. The flipping receiving assembly 13 connects to the second rotating seat 21 and drives the second rotating seat 21 to rotate.
[0035] The flip-out assembly 13 includes a limiting assembly 15 and a sector-shaped plate 18. Both the first rotating shaft 14 and the second rotating shaft 14.1 pass through the mounting plate 40. A 90° sector-shaped plate 18 is welded to the outer circumference of the first rotating shaft 14 and the second rotating shaft 14.1. The limiting assembly 15 is bolted to the mounting plate 40 on one side of the first rotating shaft 14 and the second rotating shaft 14.1. The limiting assembly 15 includes a fixing seat 16 and limit switches 17. The fixing seat 16 is bolted to the mounting seat, and two sets of limit switches 17 facing the sector-shaped plate 18 are bolted to the fixing seat 16. The first rotating shaft... The first rotating shaft 14 and the second rotating shaft 14.1 rotate to make the two sides of the fan-shaped plate 18 contact the limit switch 17. When the fan-shaped plate 18 contacts the limit switch 17, the first rotating shaft 14 and the second rotating shaft 14.1 rotate in opposite directions, thus realizing the reciprocating swing of the negative pressure adsorption component 8 and the receiving magnetic adsorption component 2090°. A lifting component 19 is installed between the mounting plate 40 and the fan-shaped plate 18. The lifting component 19 is also a cylinder. The two ends of the lifting component 19 are rotatably connected to the mounting plate 40 and the fan-shaped plate 18 through bearings. The lifting component 19 is eccentrically connected to the fan-shaped plate 18. The first rotating shaft 14 and the second rotating shaft 14.1 are rotated by the lifting and retraction of the lifting component 19.
[0036] A rotating rod 41 is fixed to the top of the negative pressure adsorption head 11 by welding. Each rotating rod 41 passes through the lifting seat 12 and is rotatably connected to the lifting seat 12 via bearings. A gear 42 is fitted onto each rotating rod 41 and welded to it. A rack 43 is installed on the lifting seat 12 by sliding engagement. The rack 43 is engaged with the lifting seat 12 and moves horizontally. The gear 42 on each rotating rod 41 meshes with the rack 43. A [missing information - likely a type of interlocking mechanism] is provided between the lifting seat 12 and the rack 43. The translation cylinder 44 has its cylinder body fixed to the lifting seat 12 by bolts. The piston rod of the translation cylinder 44 is fixed to the rack 43 by welding. The translation cylinder 44 realizes the translation of the rack 43, thus realizing the 45° rotation of the inductor. Before passing through the rack, the leads are located on the left and right sides of the inductor, and the pins of the inductor are at a 45° angle to the leads of the inductor. This 45° rotation of the inductor makes the pins of the inductor located on the left and right sides of the inductor, which facilitates subsequent soldering to the leads.
Claims
1. An automatic wire cutting and strip feeding machine for inductors, comprising an automatic cutting mechanism, an automatic strip feeding mechanism, a feeding guide rail and a conveying guide rail, wherein the feeding guide rail and the conveying guide rail are both mounted on a table, characterized in that, Automatic cutting mechanisms are provided on both sides of the feeding guide rail, a pressure fixture assembly is provided above the feeding guide rail, a fixed fixture assembly is installed on the feeding guide rail, a conveying guide rail is provided on one side of the feeding guide rail, and an automatic strip feeding mechanism is provided above the feeding guide rail and the conveying guide rail. The automatic conveying mechanism includes a negative pressure adsorption component, a flipping and contacting component, and a receiving magnetic suction component. An installation plate is provided above the feeding guide rail and the conveying guide rail. The negative pressure adsorption component and the receiving magnetic suction component are arranged opposite to each other and are rotatably connected to the installation plate. The installation plate is provided with flipping and contacting components that are connected to the negative pressure adsorption component and the receiving magnetic suction component respectively. The flipping and contacting components enable the negative pressure adsorption component and the receiving magnetic suction component to rotate 90°, and both the negative pressure adsorption component and the receiving magnetic suction component can be raised and lowered.
2. The automatic cut-and-carried strip paneler of inductance according to claim 1, characterized in that, The negative pressure adsorption assembly includes a first rotating seat, a first lifting assembly, and negative pressure adsorption heads. The first rotating seat is rotatably connected to the mounting plate, and the flipping docking assembly docks with the first rotating seat. The flipping docking assembly enables the first rotating seat to rotate 90°. A lifting seat is provided below the first rotating seat, and multiple adsorption heads are installed side by side on the lifting seat. The first lifting assembly is provided between the lifting seat and the first rotating seat.
3. The automatic wire cutting and strip-passing plate-laying machine for inductors according to claim 2, characterized in that, The continuous receiving assembly includes a second rotating seat, a second lifting assembly, and a magnetic block. The magnetic block is located below the second rotating seat, and the second lifting assembly is located between the magnetic block and the second rotating seat. The second rotating seat is rotatably connected to the mounting plate, and the flipping receiving assembly is connected to the second rotating seat and drives the second rotating seat to rotate.
4. The automatic cut-and-carried strip lopper of the inductance according to claim 3, characterized in that, The flipping assembly includes a rotating shaft, a limiting assembly, and a sector-shaped plate. The sector-shaped plate is fixed on the outer circumference of the rotating shaft. A limiting assembly is provided on one side of the rotating shaft. The limiting assembly includes a fixed base and limit switches. A fixed base is installed on the mounting base, and two sets of limit switches are installed on the fixed base. The rotating shaft rotates to make the two sides of the sector-shaped plate contact the limit switches. When the sector-shaped plate contacts the limit switches, the rotating shaft rotates in the same direction. A lifting assembly is installed between the mounting plate and the sector-shaped plate. The lifting assembly is eccentrically connected to the sector-shaped plate.
5. The automatic cut-and-carried strip lopper of the inductance according to claim 4, characterized in that, A rotating rod is fixed to the top of the negative pressure adsorption head. The rotating rod passes through the lifting seat and is rotatably connected to the lifting seat. A gear is fixed on each rotating rod. A rack is installed on the lifting seat by sliding fit. The gear on each rotating rod meshes with the rack. A translation cylinder is set between the lifting seat and the rack. The translation cylinder realizes the translation of the rack, thus realizing the 45° rotation of the inductor.
6. The automatic cut-and-carried strip lacing machine of inductance according to claim 1, characterized in that, The automatic cutting mechanism includes a thread tail trimming assembly, a thread tail clamping assembly, and a three-axis motion platform. The three-axis motion platform is mounted on the platform, and a thread trimming seat is mounted on the platform. Below the thread trimming seat, two sets of opposing thread tail trimming assemblies are mounted. The thread tail trimming assemblies slide with the thread trimming seat, and a locking assembly is provided between the thread trimming seat and the thread tail trimming assemblies to adjust the distance between the two sets of thread tail trimming assemblies. A thread tail clamping assembly is mounted on the outside of each set of thread tail trimming assemblies to clamp the end of the thread before cutting, thus facilitating the cutting of the thread tail.
7. The automatic cut-and-carried strip lopper of the inductance according to claim 6, characterized in that, The fixture assembly includes a stop block and a clamping block. A retractable stop block is located on one side of the feed guide rail, restricting the fixture's transport when it extends above the feed guide rail. Clamping blocks are located on both sides of the feed guide rail. Cylinders are installed on the clamping blocks and the outer wall of the feed guide rail, allowing the clamping blocks to extend and retract. A slot is formed on the clamping block; when the clamping blocks close, the fixture engages in the slot. A slanted groove is fixed on the clamping block, and a wiring tail groove is installed on the table, extending above the wiring tail groove. The pressure fixture assembly includes a pressure bar, a pressure block, and an elastic telescopic rod. The pressure bar is located directly above the conveying guide rail. A cylinder is located between the pressure bar and the outer wall of the feed guide rail, raising and lowering the pressure bar. Multiple pressing blocks are arranged side-by-side below the pressure bar. An elastic telescopic rod is fixed to the top of each pressing block, passing through the pressure bar. A spring is fitted onto the elastic telescopic rod to press the pressing block down.
8. The automatic wire cutting and strip-passing plate-laying machine for inductors according to claim 7, characterized in that, The conveyor rails consist of two parallel rails with interconnected gaps at both ends. Pushing components are installed at these gaps to switch between the conveyor rails.