Reactor processing winding assembly integrated device with broken wire alarm function

By introducing components such as protective plates, rubber plates, springs, and rollers into the reactor winding equipment, the problem of the winding equipment being unable to protect the winding surface is solved, realizing safe transportation and firm winding of the winding, and improving the service life and installation efficiency of the reactor.

CN114267536BActive Publication Date: 2026-06-19SHANGHAI TIANXIN NANOTECHNOLOGY CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
SHANGHAI TIANXIN NANOTECHNOLOGY CO LTD
Filing Date
2022-01-07
Publication Date
2026-06-19

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    Figure CN114267536B_ABST
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Abstract

This invention relates to the field of reactor processing equipment, specifically disclosing an integrated winding and assembly equipment with a broken wire alarm function for reactor processing. The equipment includes a machine body with a placement hole on its side. A partition is installed on the inner wall of the machine body, and a support plate is installed on the top of the partition. The end of the support plate away from the partition is fixed to the inner top of the machine body. Mounting plates are installed at both ends of the top of the partition. One end of the mounting plate is installed on the side of the support plate, and the other end is installed on the inner wall of the machine body near the placement hole. A feeding hole is formed through the side of the support plate, and a protective mechanism is installed inside the feeding hole. Mounting grooves are formed on both inner walls of the machine body, and adjustment mechanisms are installed within these grooves. This invention provides better protection for the winding and facilitates the installation of the coil frame.
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Description

Technical Field

[0001] This invention relates to the field of reactor processing equipment technology, and in particular to an integrated winding and assembly equipment with a broken wire alarm function for reactor processing. Background Technology

[0002] A reactor, also called an inductor, is an electrical device that generates a magnetic field within a certain space when current flows through it. Therefore, all current-carrying conductors possess inductance in a general sense. However, the inductance of a long, straight current-carrying conductor is relatively small, and the magnetic field it produces is not strong. Therefore, practical reactors are made by winding wire into a solenoid, called air-core reactors. Sometimes, to give this solenoid a larger inductance, an iron core is inserted inside, called an iron-core reactor. Reactance is divided into inductive reactance and capacitive reactance. A more scientific classification is that inductors and capacitors are collectively called reactors. However, because inductors were developed first and were called reactors, the term "capacitor" now refers to a capacitive reactance, while "reactor" specifically refers to an inductor.

[0003] When processing reactors, windings need to be wound and installed on the reactors. However, commonly used reactor winding equipment cannot treat the surface of the windings during use, and the machine body is prone to causing severe friction on the surface of the windings during use, which can lead to breakage of the windings during installation. Furthermore, the reactors pose certain safety hazards during use. Summary of the Invention

[0004] To address the problems in the prior art, this invention provides an integrated winding and assembly equipment with a broken wire alarm function for reactor processing.

[0005] To achieve the above objectives, the present invention adopts the following technical solution:

[0006] An integrated winding and assembly equipment with a broken wire alarm function for reactor processing includes a machine body. A placement hole is provided on the side of the machine body. A partition is installed on the inner wall of the machine body. A support plate is installed on the top of the partition, and the end of the support plate away from the partition is fixed to the inner top of the machine body. Mounting plates are installed at both ends of the top of the partition. One end of the mounting plate is installed on the side of the support plate, and the other end is installed on the inner wall of the machine body near the placement hole. A material conveying hole is provided through the side of the support plate, and a protective mechanism is installed inside the material conveying hole. Mounting grooves are provided on both inner walls of the machine body, and adjustment mechanisms are installed inside the mounting grooves.

[0007] Preferably, the protective mechanism includes an N-shaped protective plate, and a plurality of cylinders are equidistantly installed at the bottom of the protective plate. The end of the cylinder away from the protective plate is installed at the bottom of the feed hole. A placement groove is opened at the top of the protective plate along its length, and a sponge plate is installed in the placement groove. A rubber plate is installed at the top of the feed hole, and a plurality of protective grooves are opened on the side of the rubber plate near the protective plate.

[0008] Preferably, the adjustment mechanism includes a fixed block and a lifting block, with the fixed block located above the lifting block. A spring is installed between the fixed block and the lifting block, and the two ends of the spring are respectively installed on the opposite surfaces of the lifting block and the fixed block. Several matching slots are provided on the inner walls of both sides of the mounting groove. Card blocks are installed on both sides of the fixed block, and the end of the card block away from the fixed block is located in the slot.

[0009] Preferably, a support rod is installed between the two lifting blocks, and the two ends of the support rod are respectively installed on the opposite surfaces of the two lifting blocks. A roller is rotatably installed on the support rod, and a push switch is installed at the bottom of the inner side of each of the two mounting slots.

[0010] Preferably, connecting blocks are installed on the opposite sides of the two mounting plates. An electric telescopic rod is rotatably installed on the side of one connecting block away from the mounting plate, and a motor is installed on the side of the other mounting plate away from the placement hole. The output shaft of the motor passes through the mounting plate, and the other connecting block is rotatably installed on the output shaft of the motor.

[0011] Preferably, the output shaft of the motor and the end of the electric telescopic rod away from the mounting plate are both equipped with clamping plates. The ends of the two clamping plates away from the mounting plate are provided with limit grooves, and the inner walls of the limit grooves are provided with through holes. A reactor is installed between the two clamping plates, and the two ends of the reactor are respectively installed in the two limit grooves.

[0012] Preferably, the support plate has a sliding groove on the side near the placement hole, and the sliding groove is located below the material conveying hole. An electric slider is slidably installed in the sliding groove. A movable plate is installed at the end of the electric slider near the placement hole, and fixed plates are installed at both ends of the movable plate on the side away from the support plate.

[0013] Preferably, a fixing rod is installed at the end of the two fixing plates away from the moving plate, and the other end of the fixing rod is installed on the opposite surface of the two fixing plates respectively. Several rollers are installed on the fixing rod, and several filter holes are opened on the top of the partition between the two mounting plates.

[0014] Preferably, the inner walls on both sides of the placement hole are provided with arc-shaped storage grooves, and a baffle plate is slidably installed in the storage grooves. The top and bottom of the placement hole are provided with sliding grooves, and a slider is slidably installed in each of the two sliding grooves. The end of the slider away from the sliding groove is respectively installed at both ends of the baffle plate.

[0015] Preferably, a connecting hole is provided through the top of the inner wall on the side of the machine body away from the placement hole, and a storage box is installed on the side of the machine body, which communicates with the interior of the machine body through the connecting hole.

[0016] Compared with the prior art, the beneficial effects of the present invention are:

[0017] 1. In this invention, the worker can pour the anti-corrosion liquid onto the sponge board. The sponge board absorbs the anti-corrosion liquid and evenly coats it onto the winding being transported through the conveying hole. Simultaneously, the protective plate protects the winding being transported, preventing severe friction between the inner wall of the conveying hole and the winding surface, which could lead to breakage during transport. The protective plate provides good protection for the winding, making the reactor safer to use and extending its service life. Furthermore, the rubber plate cleans the surface of the winding during transport, keeping it cleaner and preventing dust from falling onto the reactor surface, thus providing better protection for the reactor.

[0018] 2. During the winding and conveying process, the spring drives the roller downwards via the lifting block. Simultaneously, the roller pulls the winding downwards, reducing tension during conveying and making the winding more securely wrapped around the reactor. This also makes it less likely for the coils on the reactor to fall off during use. Furthermore, the winding's movement during conveying, coupled with the reactor's rotation, pulls the roller upwards, preventing the lifting block from moving too far from the fixed block. If the winding breaks during conveying and winding, the spring pushes the lifting block downwards, impacting the push switch located at the bottom of the mounting slot. The push switch, via a computer terminal, activates an air pump, which in turn drives the piston rods of several cylinders to push the protective plate upwards. This causes the protective plate and the rubber plate above to clamp and fix the winding, preventing it from retracting after breakage and facilitating reconnection by the operator.

[0019] 3. The electric telescopic rod can push two clamping plates to clamp and fix the reactor in position. After the reactor is wound, the operator can insert the two ends of the winding frame into the through holes on the clamping plates, so that the two ends of the coil frame are respectively installed with the two ends of the reactor. Then, the electric telescopic rod is started, which drives one of the clamping plates to move, and the operator can then pick up the processed reactor. It is more convenient to use and the coil frame assembly is faster. Attached Figure Description

[0020] Figure 1 This is a perspective view of the integrated winding and assembly equipment with a broken wire alarm function for reactor processing proposed in this invention.

[0021] Figure 2 This is a schematic diagram of the internal structure of the integrated winding and assembly equipment with a broken wire alarm function for reactor processing proposed in this invention.

[0022] Figure 3 This is a cross-sectional view of the integrated winding and assembly equipment with a broken wire alarm function for reactor processing proposed in this invention.

[0023] Figure 4This is a schematic diagram of the roller mounting structure of the integrated winding and assembly equipment with a broken wire alarm function for reactor processing proposed in this invention.

[0024] Figure 5 This is a schematic diagram of the protective plate structure of the integrated winding and assembly equipment with a broken wire alarm function for reactor processing proposed in this invention.

[0025] Figure 6 This is a schematic diagram of the cylinder mounting structure of the integrated winding and assembly equipment with a broken wire alarm function for reactor processing proposed in this invention.

[0026] Figure 7 This is a schematic diagram of the moving plate structure of the integrated winding and assembly equipment with a broken wire alarm function for reactor processing proposed in this invention.

[0027] Figure 8 This is a schematic diagram of the clamping plate structure of the integrated winding assembly equipment with a broken wire alarm function for reactor processing proposed in this invention.

[0028] Figure 9 This is a schematic diagram of the spring mounting structure of the integrated winding assembly equipment with a broken wire alarm function for reactor processing proposed in this invention.

[0029] Figure 10 This is a schematic diagram of the rubber sheet structure of the integrated winding and assembly equipment with a broken wire alarm function for reactor processing proposed in this invention.

[0030] Figure 11 This is a schematic diagram of the shielding plate structure of the integrated winding assembly equipment with a broken wire alarm function for reactor processing proposed in this invention.

[0031] In the diagram: 1. Machine body; 2. Placement hole; 3. Baffle plate; 4. Partition plate; 5. Support plate; 6. Mounting plate; 7. Slide groove; 8. Filter hole; 9. Storage box; 10. Feeding hole; 11. Slide groove; 12. Moving plate; 13. Clamping plate; 14. Rubber plate; 15. Protective plate; 16. Motor; 17. Connecting block; 18. Electric telescopic rod; 19. Fixing plate; 20. Roller; 21. Placement groove; 22. Sponge board; 23. Cylinder; 24. Limit groove; 25. Slider; 26. Mounting groove; 27. Roller; 28. Slot; 29. ​​Fixing block; 30. Spring; 31. Press switch; 32. Support rod; 33. Connecting hole; 34. Locking block; 35. Lifting block. Detailed Implementation

[0032] The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present invention. Obviously, the described embodiments are only some embodiments of the present invention, and not all embodiments.

[0033] Reference Figure 1-11 An integrated winding assembly equipment with a broken wire alarm function for reactor processing includes a body 1. A placement hole 2 is provided on the side of the body 1. A partition 4 is installed on the inner wall of the body 1. A support plate 5 is installed on the top of the partition 4, and the end of the support plate 5 away from the partition 4 is fixed to the inner top of the body 1. Mounting plates 6 are installed on both ends of the top of the partition 4. One end of the mounting plate 6 is installed on the side of the support plate 5, and the other end of the mounting plate 6 is installed on the inner wall of the body 1 near the placement hole 2. A material conveying hole 10 is provided through the side of the support plate 5. A protective mechanism is installed in the material conveying hole 10. Mounting grooves 26 are provided on both inner walls of the body 1, and an adjustment mechanism is installed in the mounting grooves 26.

[0034] As a technical optimization of the present invention, the protective mechanism includes an N-shaped protective plate 15, and a plurality of cylinders 23 are equidistantly installed at the bottom of the protective plate 15. The end of the cylinder 23 away from the protective plate 15 is installed at the bottom of the feed hole 10. The top of the protective plate 15 is provided with a placement groove 21 along the length direction. A sponge plate 22 is installed in the placement groove 21. A rubber plate 14 is installed at the top of the feed hole 10. A plurality of protective grooves are provided on the side of the rubber plate 14 near the protective plate 15. When in use, the operator can pour the anti-corrosion liquid onto the sponge plate 22. When the winding is being transported, the anti-corrosion liquid can be applied to the winding wire. The subsequent winding can apply the anti-corrosion liquid to the surface of the coil below, so that the two adjacent coils are protected by the anti-corrosion liquid. When the wire breaks, the cylinder 23 can drive the protective plate 15 to rise, so that the protective plate 15 and the rubber plate 14 clamp and fix the coil being transported, which is convenient for the operator to connect the winding.

[0035] As a technical optimization of the present invention, the adjustment mechanism includes a fixed block 29 and a lifting block 35, with the fixed block 29 located above the lifting block 35. A spring 30 is installed between the fixed block 29 and the lifting block 35, and the two ends of the spring 30 are respectively installed on the opposite surfaces of the lifting block 35 and the fixed block 29. Several matching slots 28 are provided on the inner walls of both sides of the mounting groove 26. A locking block 34 is installed on both sides of the fixed block 29, and the end of the locking block 34 away from the fixed block 29 is located in the slot 28. The slots 28 and the locking blocks 34 can fix the position of the fixed block 29, and can also adjust the position and height of the fixed block 29 during use.

[0036] As a technical optimization of the present invention, a support rod 32 is installed between the two lifting blocks 35, and the two ends of the support rod 32 are respectively installed on the opposite surfaces of the two lifting blocks 35. A roller 27 is rotatably installed on the support rod 32. A push switch 31 is installed at the bottom of the inner side of the two mounting slots 26. When in use, the roller 27 can drive the conveyed winding to pull downward by the push of the spring 30, so that the winding effect of the winding is better and the winding is not easy to loosen when in use.

[0037] As a technical optimization of the present invention, connecting blocks 17 are installed on the opposite sides of the two mounting plates 6. An electric telescopic rod 18 is rotatably installed on the side of one connecting block 17 away from the mounting plate 6, and a motor 16 is installed on the side of the other mounting plate 6 away from the placement hole 2. The output shaft of the motor 16 passes through the mounting plate 6, and the other connecting block 17 is rotatably installed on the output shaft of the motor 16. When in use, the connecting block 17 can reinforce the electric telescopic rod 18 and the output shaft of the motor 16 to prevent shaking when the reactor is wound.

[0038] As a technical optimization of the present invention, clamping plates 13 are installed on the output shaft of the motor 16 and the end of the electric telescopic rod 18 away from the mounting plate 6. Limiting grooves 24 are opened on the ends of the two clamping plates 13 away from the mounting plate 6, and through holes are opened on the inner walls of the limiting grooves 24. A reactor is installed between the two clamping plates 13, and the two ends of the reactor are respectively installed in the two limiting grooves 24. When in use, the two clamping plates 13 can clamp and fix the two ends of the reactor. At the same time, the electric telescopic rod 18 can drive one of the clamping plates 13 to move, which facilitates the installation and removal of the reactor. After the reactor coil is wound, the operator can install the coil frame on the reactor through the four through holes on the clamping plate 13.

[0039] As a technical optimization of the present invention, a sliding groove 11 is provided on the side of the support plate 5 near the placement hole 2, and the sliding groove 11 is located below the material conveying hole 10. An electric slider is slidably installed in the sliding groove 11. A moving plate 12 is installed on the end of the electric slider near the placement hole 2. Fixed plates 19 are installed on both ends of the side of the moving plate 12 away from the support plate 5. A fixed rod is installed between the two fixed plates 19 at the end away from the moving plate 12. The other end of the fixed rod is respectively installed on the opposite surface of the two fixed plates 19. Several rollers 20 are installed on the fixed rod. Several filter holes 8 are provided on the top of the partition plate 4 between the two mounting plates 6. When in use, the electric slider can drive the rollers 20 to move, so that the position of the winding on the rollers 20 is adjusted for winding the reactor.

[0040] As a technical optimization of the present invention, arc-shaped storage grooves are provided on both inner walls of the placement hole 2. A baffle plate 3 is slidably installed in the storage groove. A sliding groove 7 is provided on the inner top and inner bottom of the placement hole 2. A slider 25 is slidably installed in each of the two sliding grooves 7. The end of the slider 25 away from the sliding groove 7 is respectively installed at both ends of the baffle plate 3. When in use, the operator can pull the baffle plate 3 so that the two baffle plates 3 can block the inside of the machine body 1, preventing dust from the outside from falling on the reactor when the reactor is being wound, thus providing better protection for the reactor.

[0041] As a technical optimization of the present invention, a connecting hole 33 is provided through the top of the inner wall of the machine body 1 away from the placement hole 2. A storage box 9 is installed on the side of the machine body 1. The storage box 9 is connected to the interior of the machine body 1 through the connecting hole 33. When in use, the operator can place the winding wire in the storage box 9, and one end of the winding wire is placed in the machine body 1 through the connecting hole 33. The winding wire passes through the bottom of the roller 27 and is inserted into the feeding hole 10 and the roller 20. Then it is installed at one end of the reactor. When in use, the winding wire can be tensioned and the surface cleaned, so that the winding effect of the reactor is better.

[0042] In use, the operator places the winding wire in the storage box 9 beforehand, and inserts one end of the winding wire into the machine body 1 through the connection hole 33. After entering the machine body 1, the winding wire is wound around the bottom of the roller 27 and passes through the feed hole 10. When the winding wire passes through the feed hole 10, it is located between the rubber plate 14 and the protective plate 15, and the bottom of the winding wire abuts against the sponge plate 22 on the top of the protective plate 15. After passing through the feed hole 10, the winding wire passes again between the roller 20 and the moving plate 12 and is wound on the roller 20. After passing through the roller 20, the winding wire is installed on one end of the reactor. The motor 16 is started, and its output shaft drives one of the clamping plates 13 to rotate. When clamping plate 13 rotates, it drives the reactor and the other clamping plate 13 to rotate. Simultaneously, the electric telescopic rod 18 on the side of the other clamping plate 13, via the connecting block 17, pushes the clamping plate 13 towards the reactor as it rotates on the side of the mounting plate 6, thus clamping and fixing the reactor in position. As the reactor rotates, the winding can be wound and installed on the reactor's surface. The electric slider is started, sliding within the sliding groove 11 and driving the moving plate 12 to move on the side of the support plate 5. As the moving plate 12 moves, it moves via the fixed plate 19 to adjust the position of the winding wound on the reactor.

[0043] During use, the operator can pour the anti-corrosion liquid onto the sponge board 22. The sponge board 22 absorbs the anti-corrosion liquid and evenly coats the windings conveyed within the conveying hole 10. Simultaneously, the protective plate 15 protects the conveyed windings, preventing severe friction between the inner wall of the conveying hole 10 and the winding surface, which could lead to breakage during conveying. The protective plate 15 provides good protection for the windings, making the reactor safer to use and extending its service life. Furthermore, the rubber plate 14 cleans the surface of the windings during conveying, keeping the surface cleaner and preventing dust from falling onto the reactor surface, thus providing good protection for the reactor.

[0044] During the conveying of the winding, the spring 30 pushes the lifting block 35 at the bottom, which in turn drives the roller 27 to move downward. At the same time, the roller 27 pulls the winding downward, making the tension of the winding smaller during the conveying process. The winding is more secure when it is wrapped around the reactor, and the coil on the reactor is less likely to fall off during use. Meanwhile, the winding is pulled upward by the rotation of the reactor during the conveying process, which prevents the lifting block 35 from moving too far away from the fixed block 29.

[0045] When the winding breaks during the conveying and winding process, the spring 30 pushes the lifting block 35 to slide downwards and impacts the push switch 31 located at the bottom of the mounting groove 26. The push switch 31 starts the air pump through the computer terminal, which drives the piston rods of several cylinders 23 to move upwards. The piston rods of the cylinders 23 push the protective plate 15 upwards, so that the protective plate 15 and the rubber plate 14 above clamp and fix the winding, preventing it from retracting after the winding breaks, and at the same time facilitating the workers to connect the winding.

[0046] When the reactor is being wound, the operator can pull the two shielding plates 3 in the storage slots, causing the two shielding plates 3 to slide towards the reactor. As the shielding plates 3 move, the sliders 25 at both ends of the shielding plates 3 can slide within the grooves 7 on the inner wall of the placement hole 2, making the shielding plates 3 more stable during movement. During reactor winding, the two shielding plates 3 can protect the reactor from external dust falling onto its surface, which could easily affect the reactor's processing.

[0047] After the reactor winding is completed, the workers can insert the two ends of the winding frame into the through holes on the clamping plate 13, so that the two ends of the coil frame are respectively installed with the two ends of the reactor. Then, the electric telescopic rod 18 is activated, which drives one of the clamping plates 13 to move, so that the workers can take out the processed reactor. It is more convenient to use and the coil frame assembly is faster.

[0048] The above description is only a preferred embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any equivalent substitutions or modifications made by those skilled in the art within the scope of the technology disclosed in the present invention, based on the technical solution and inventive concept of the present invention, should be covered within the scope of protection of the present invention.

Claims

1. A winding assembly integrated device with a broken wire alarm function for a reactor process, comprising a machine body (1), characterized in that, The machine body (1) has a placement hole (2) on its side. A partition (4) is installed on the inner wall of the machine body (1). A support plate (5) is installed on the top of the partition (4). The end of the support plate (5) away from the partition (4) is fixed to the inner top of the machine body (1). Mounting plates (6) are installed on both ends of the top of the partition (4). One end of the mounting plate (6) is installed on the side of the support plate (5). The other end of the mounting plate (6) is installed on the inner wall of the machine body (1) near the placement hole (2). A feeding hole (10) is opened through the side of the support plate (5). A protective mechanism is installed in the feeding hole (10). Mounting grooves (26) are opened on both sides of the inner wall of the machine body (1). An adjustment mechanism is installed in the mounting grooves (26). The protective mechanism includes an N-shaped protective plate (15), and several cylinders (23) are equidistantly installed at the bottom of the protective plate (15). The end of the cylinder (23) away from the protective plate (15) is installed at the bottom of the feed hole (10). A placement groove (21) is opened at the top of the protective plate (15) along the length direction. A sponge plate (22) is installed in the placement groove (21). A rubber plate (14) is installed at the top of the feed hole (10), and several protective grooves are opened on the side of the rubber plate (14) close to the protective plate (15). The adjustment mechanism includes a fixed block (29) and a lifting block (35), with the fixed block (29) located above the lifting block (35). A spring (30) is installed between the fixed block (29) and the lifting block (35), with the two ends of the spring (30) respectively installed on the opposite surfaces of the lifting block (35) and the fixed block (29). Several matching slots (28) are provided on the inner walls of both sides of the mounting groove (26). A locking block (34) is installed on both sides of the fixed block (29), with the end of the locking block (34) away from the fixed block (29) located in the slot (28). A support rod (32) is installed between the two lifting blocks (35), and the two ends of the support rod (32) are respectively installed on the opposite surfaces of the two lifting blocks (35). A roller (27) is rotatably installed on the support rod (32), and a push switch (31) is installed at the bottom of the two mounting slots (26). When the winding breaks during the conveying and winding process, the spring (30) pushes the lifting block (35) to slide downward and impacts the push switch (31) located at the bottom of the mounting groove (26). The push switch (31) starts the air pump through the computer terminal, and the air pump can drive the piston rod of several cylinders (23) to push the protective plate (15) upward, so that the protective plate (15) and the rubber plate (14) above clamp and fix the winding, preventing the winding from shrinking after it breaks.

2. The winding assembly integrated device for the reactor processing with the broken wire alarm function according to claim 1, characterized in that, Connecting blocks (17) are installed on the opposite sides of the two mounting plates (6). An electric telescopic rod (18) is rotatably installed on the side of one of the connecting blocks (17) away from the mounting plate (6). A motor (16) is installed on the side of the other mounting plate (6) away from the placement hole (2). The output shaft of the motor (16) passes through the mounting plate (6), and the other connecting block (17) is rotatably installed on the output shaft of the motor (16).

3. The winding assembly integrated device for the reactor processing with the broken wire alarm function according to claim 2, characterized in that, The output shaft of the motor (16) and the electric telescopic rod (18) are both equipped with clamping plates (13) at the ends away from the mounting plate (6). Limiting grooves (24) are opened at the ends of the two clamping plates (13) away from the mounting plate (6), and through holes are opened on the inner walls of the limiting grooves (24). A reactor is installed between the two clamping plates (13), and the two ends of the reactor are respectively installed in the two limiting grooves (24).

4. The integrated winding and assembly equipment with a broken wire alarm function for reactor processing according to claim 1, characterized in that, The support plate (5) has a sliding groove (11) on the side near the placement hole (2), and the sliding groove (11) is located below the material conveying hole (10). An electric slider is slidably installed in the sliding groove (11). A moving plate (12) is installed at one end of the electric slider near the placement hole (2). Fixed plates (19) are installed at both ends of the moving plate (12) away from the support plate (5).

5. The winding assembly integrated device for the reactor processing with the broken wire alarm function according to claim 1, characterized in that, A fixing rod is installed at one end of the two fixing plates (19) away from the moving plate (12). The other end of the fixing rod is installed on the opposite surface of the two fixing plates (19). Several rollers (20) are installed on the fixing rod. Several filter holes (8) are opened on the top of the partition (4) between the two mounting plates (6).

6. The winding assembly integrated device for the reactor processing with the broken wire alarm function according to claim 1, characterized in that, The inner walls on both sides of the placement hole (2) are provided with arc-shaped storage grooves. A baffle plate (3) is slidably installed in the storage groove. The top and bottom of the placement hole (2) are provided with sliding grooves (7). A slider (25) is slidably installed in each of the two sliding grooves (7). The end of the slider (25) away from the sliding groove (7) is respectively installed at both ends of the baffle plate (3).

7. The winding assembly integrated device for the reactor processing with the broken wire alarm function according to claim 1, characterized in that, A connecting hole (33) is provided on the top of the inner wall of the body (1) away from the placement hole (2). A storage box (9) is installed on the side of the body (1). The storage box (9) is connected to the interior of the body (1) through the connecting hole (33).