Horizontal inductance sleeve machine

By designing a horizontal inductor bushing machine and adopting structures such as a feeding stripping head, a moving frame, and a fixed frame, the automated production of inductor components has been realized. This has solved the problems of feeding misalignment and bushing offset in inductor bushing machines, thereby improving production efficiency and product quality.

CN224384074UActive Publication Date: 2026-06-19FENYI XINCHANG ELECTRONICS CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
FENYI XINCHANG ELECTRONICS CO LTD
Filing Date
2025-06-24
Publication Date
2026-06-19

AI Technical Summary

Technical Problem

Existing inductor bushing machines are prone to misalignment during material feeding and deviation during bushing, resulting in low yield and low production efficiency.

Method used

A horizontal inductor bushing machine was designed, which adopts a feeding stripping head, a moving frame and a fixed frame to realize automatic feeding, lead straightening, detection and sorting and precise bushing of inductor components. Non-contact inductance value measurement is performed by copper detection clamps. Combined with mechanical transmission and cylinder drive, the machine ensures accurate positioning and stable conveying of inductor components between each station.

Benefits of technology

It has achieved fully automated production of inductor components, which has improved production efficiency, reduced labor costs, ensured product quality stability and yield, and reduced defect rate.

✦ Generated by Eureka AI based on patent content.

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Abstract

The utility model provides a horizontal inductance bushing machine, include: base, the left side fixed mounting of base upper end has the feeding and stripping head, the right side fixed mounting of feeding and stripping head has the detection frame, the right side fixed mounting of detection frame has the removal frame, the front fixed mounting of removal frame has the fixed frame, the front fixed mounting of fixed frame has the bushing frame. This kind of horizontal inductance bushing machine is provided with feeding and stripping head, feeding wheel, moving frame and fixed frame structure, and feeding and stripping head cooperates with feeding wheel, realizes the automatic separation and transportation of the link inductance component, greatly reduces manual intervention, and the staggered layout and collaborative operation of moving frame and fixed frame form accurate step -by -step removal mechanism, ensure inductance component smooth circulation, accurate positioning between each station, these structures cooperate with each other, not only significantly improve the efficiency of bushing processing, but also guarantee the stability of product quality, effectively reduce the rate of defective products.
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Description

Technical Field

[0001] This utility model relates to the field of inductor manufacturing technology, and more specifically, to a horizontal inductor bushing machine. Background Technology

[0002] An inductor is an electronic component that stores electrical energy in the form of a magnetic field. In a circuit, an inductor is usually composed of coils. When current flows through a coil, a magnetic field is generated around it. This magnetic field induces an electromotive force in the coil, thus impeding the change in current. Inductors play an important role in electronic circuits, and their performance and quality directly affect the performance and reliability of electronic devices. Therefore, inductors need to be insulated to prevent short circuits when they come into contact with each other.

[0003] However, existing inductor bushing machines have the following problems during use:

[0004] During feeding, the feeding roller and the stripping head are controlled by the same output source. During unloading, the stripping head and the feeding roller are prone to misalignment. Once misalignment occurs, the inductor is prone to inaccurate positioning during feeding, which will cause misalignment in subsequent processing. Secondly, during sleeve sleeve, multiple inductors are inserted into the sleeve at the same time, which can easily cause problems such as sleeve offset and incomplete wrapping, resulting in low yield and low production efficiency.

[0005] This invention can automate the entire process of inductor component feeding, lead straightening, detection and sorting, precise sleeve and tape packaging through the coordinated use of structures such as feeding and stripping heads and moving frames. This can significantly improve production efficiency, reduce labor costs, ensure product quality stability, and reduce defect rate. Summary of the Invention

[0006] The present invention aims to solve the technical problems mentioned in the background art and provide a horizontal inductor bushing machine.

[0007] To achieve the above objectives, this utility model provides the following technical solution: a horizontal inductor sleeve machine, comprising: a base, a feeding stripping head fixedly installed on the upper left side of the base, a detection frame fixedly installed on the right side of the feeding stripping head, a transfer frame fixedly installed on the right side of the detection frame, a fixed frame fixedly installed on the front of the transfer frame, a sleeve frame fixedly installed on the front of the fixed frame, a movable frame one slidably installed on the upper front of the transfer frame, a plurality of movable clamps fixedly installed on the front of the movable frame one, a movable frame three slidably installed above the front of the fixed frame, a placement frame fixedly installed below the movable frame three, a plurality of fixed clamps fixedly installed on the front of the movable frame three, the fixed clamps and the placement frame forming a complete inductor clamping structure, and staggered between the movable clamps, and a sleeve opening rotatably installed on the front of the sleeve frame, and configured in conjunction with the movable clamps, the placement frame, and the fixed clamps.

[0008] A further preferred embodiment: A feeding chain and a straightening roller are rotatably mounted on the top of the base, and a baking oven and a braiding head are fixedly mounted on the top of the base. The baking oven is located on the right side of the transfer frame, and the braiding head is located on the right side of the baking oven. The straightening roller is located on the left side of the inspection frame. The feeding chain is divided into two sections, one on the left side of the transfer frame and the other on the right side of the transfer frame.

[0009] A further preferred embodiment: A feeding wheel is rotatably mounted on the lower left side of the feeding chain, and a feeding motor is fixedly mounted below the feeding wheel. The output end of the feeding motor is rotatably connected to the feeding wheel via a transmission belt. A feeding stripping head is located at the upper left side of the feeding chain. A motor is fixedly mounted at the rear end of the feeding stripping head, and a receiving wheel is fixedly connected to the output end of the motor. The receiving wheel is located above the feeding wheel.

[0010] A further preferred embodiment: A guide rail is fixedly installed on the upper end of the base, and sliders are slidably installed on both the left and right sides of the upper end of the guide rail. The slider on the left is at the end of the left feeding chain, and the slider on the right is at the beginning of the right feeding chain. A receiving frame is fixedly installed on the upper end of the slider, and the receiving frame is located on the left and right sides of the front of the transfer frame.

[0011] A further preferred embodiment: A fixing plate is fixedly installed at the bottom of the detection frame, a motor is fixedly installed at the rear end of the fixing plate, a driven wheel is rotatably installed below the motor, the driven wheel is connected to the motor via a transmission belt, a rotating rod is fixedly installed at both the driven wheel and the output end of the motor, a connecting block is fixedly installed on the front of the rotating rod, a fixing block is fixedly installed on the other side of the front of the connecting block, a detection clamp is fixedly installed at the bottom of the fixing block, and a waste trough is fixedly installed below the detection clamp.

[0012] A further preferred embodiment: a cylinder is fixedly installed at the left end of the transfer frame, a sliding groove is provided at the upper end of the transfer frame, the sliding groove is slidably connected to the moving frame, and a moving end is fixedly installed at the bottom of the moving frame and is slidably connected to the sliding groove.

[0013] A further preferred embodiment: guide rails 2 are fixedly installed on both the left and right sides of the front of the movable frame 1, and movable frame 2 is slidably installed on the front of the movable frame 1. The guide rails 2 are slidably connected to movable frame 2. Cylinders 2 are fixedly installed on both the left and right sides of the upper end of the movable frame 1, and the output end of cylinders 2 is fixedly connected to the upper end of movable frame 2.

[0014] A further preferred embodiment: The movable frame has several top heads fixedly installed on its front side, all of which are located above the rear end of the movable clamp and fixedly connected thereto. The movable clamp is divided into upper and lower parts, and gears are fixedly installed on the inner side of the rear end of the movable clamp and mesh with each other.

[0015] A further preferred embodiment: guide rails three are fixedly installed on both the left and right sides of the front of the fixed frame, the guide rails three are slidably connected to the movable frame three, and three connecting plates are fixedly installed at equal intervals on the front of the movable frame three, with a heating gun fixedly installed at the bottom of the connecting plates. Beneficial effects

[0016] 1. By incorporating a detection frame and copper contact surface design for the detection clamps, along with a control system, non-contact inductance measurement is achieved, avoiding the subjectivity and inefficiency of manual inspection. The motor-driven rotary sorting mechanism can quickly throw defective products into the waste bin, ensuring that defective products do not flow into subsequent processes, reducing material waste and rework costs caused by defective products. This structure integrates the traditional offline inspection process into the production line, shortening the production cycle and enabling the equipment to achieve full-process automation. In addition, the mechanical transmission design ensures the stability and repeatability of the inspection action, further improving the inspection accuracy and reliability, and providing a guarantee for high-yield large-scale production.

[0017] 2. By setting up a feeding stripper head and a feeding wheel, the feeding stripper head adopts an inclined receiving wheel design. Driven by a motor, it can automatically separate the inductive components in the form of a spring chain from the paper tape, changing the cumbersome traditional manual strip removal method, reducing labor input and time costs. Its surface teeth precisely mesh with the spring chain to prevent the components from shifting or being damaged during the separation process. The feeding wheel works closely with the feeding stripper head. Driven by the feeding motor, it stably transports the separated inductive components to the feeding chain. This combination realizes the continuity and automation of the feeding process and ensures the smoothness of the production process.

[0018] 3. By setting up a transfer frame and a fixed frame, the transfer frame is driven by a cylinder, which drives the moving frame and movable clamp to slide flexibly and accurately receive and transfer inductor components, realizing the rapid flow of components between different workstations and greatly improving the production rhythm. The ingenious design of its cooperation with the fixed frame, using the staggered layout of the placement frame and fixed clamp to form a unique stepping transfer mechanism, allows the components to move to the right in an orderly manner on the fixed frame, ensuring a smooth and continuous processing flow. The fixed frame provides stable positioning support for the components. The placement frame and fixed clamp form a stable clamping structure, which clamps quickly after the components are transferred to the position to avoid displacement during processing. The two work together to ensure the accurate positioning of inductor components during the transfer process and to provide a stable operating basis for processes such as sleeve and heating, effectively improving production efficiency and processing accuracy and reducing the defect rate.

[0019] 4. In summary, this type of horizontal inductor bushing machine, through the configuration of a feeding stripper head, feeding wheels, a moving frame, and a fixed frame, achieves automatic separation and conveying of spring chain inductor components by cooperating with the feeding stripper head and feeding wheels, significantly reducing manual intervention. The staggered layout and coordinated operation of the moving frame and the fixed frame form a precise step-by-step conveying mechanism, ensuring the smooth flow and accurate positioning of inductor components between each station. These structures work together to not only significantly improve the efficiency of bushing processing but also ensure the stability of product quality and effectively reduce the defect rate. Attached Figure Description

[0020] Figure 1 This is a schematic diagram of the overall structure of this utility model.

[0021] Figure 2 This is a schematic diagram of the overall internal structure of this utility model.

[0022] Figure 3 This is a schematic diagram of the feeding structure of this utility model.

[0023] Figure 4 This is a schematic diagram of the testing frame structure of this utility model.

[0024] Figure 5 This is a schematic diagram of the sleeve structure of this utility model.

[0025] Figure 6 This is a schematic diagram of the transfer rack structure of this utility model.

[0026] Figure 7 This is a schematic diagram of the fixing frame structure of this utility model.

[0027] Figure 1-7 In the middle section: 1. Base; 101. Feeding chain; 102. Baking oven; 103. Braiding head; 104. Straightening roller; 105. Feeding wheel; 106. Feeding motor; 107. Guide rail one; 108. Slider; 109. Receiving rack; 2. Feeding stripping head; 201. Motor; 202. Receiving wheel; 3. Detection rack; 301. Fixing plate; 302. Motor; 303. Driven wheel; 304. Rotating rod; 305. Connecting block; 306. Fixing block; 307. Detection clamp; 308. Waste trough; 4. Transfer frame; 401. Cylinder 1; 402. Slide rail; 403. Moving frame 1; 404. Moving end; 405. Guide rail 2; 406. Moving frame 2; 407. Cylinder 2; 408. Top head; 409. Movable clamp; 410. Gear; 5. Fixed frame; 501. Guide rail 3; 502. Moving frame 3; 503. Placement frame; 504. Fixed clamp; 505. Connecting plate; 506. Heating gun; 6. Sleeve rack; 601. Sleeve opening. Detailed Implementation

[0028] The following will refer to the appendix in the embodiments of this utility model. Figures 1-7 The technical solutions in the embodiments of this utility model will be clearly and completely described.

[0029] Please see Figure 1-7In this embodiment of the present invention, a horizontal inductor bushing machine includes: a base 1, a feeding stripping head 2 fixedly installed on the upper left side of the base 1, a detection frame 3 fixedly installed on the right side of the feeding stripping head 2, a transfer frame 4 fixedly installed on the right side of the detection frame 3, a fixed frame 5 fixedly installed on the front of the transfer frame 4, a bushing frame 6 fixedly installed on the front of the fixed frame 5, a movable frame 403 slidably installed on the upper front of the transfer frame 4, a plurality of movable clamps 409 fixedly installed on the front of the movable frame 403, a movable frame 502 slidably installed above the front of the fixed frame 5, a placement frame 503 fixedly installed below the movable frame 502, a plurality of fixed clamps 504 fixedly installed on the front of the movable frame 502, and the fixed clamps 504 and the placement frame 503 are matched to form a complete clamped inductor. The structure is staggered between the movable clamps 409. The sleeve frame 6 has a sleeve opening 601 rotatably mounted on its front side, and is matched with the movable clamps 409, the placement frame 503, and the fixed clamps 504. The feeding chain 101 and the straightening roller 104 are rotatably mounted on the top of the base 1. The baking oven 102 and the braiding head 103 are fixedly mounted on the top of the base 1. The baking oven 102 is located on the right side of the transfer frame 4, and the braiding head 103 is located on the right side of the baking oven 102. The straightening roller 104 is located on the left side of the inspection frame 3. The feeding chain 101 is divided into two sections, one on the left side of the transfer frame 4 and the other on the right side of the transfer frame 4. The upper end of the base 1 is fixedly mounted with a guide rail 107. The upper end of the guide rail 107 has sliders 108 slidably mounted on both the left and right sides. The left slider 108 is positioned with the left slider 108. At the end of the feeding chain 101, the right slider 108 is positioned at the beginning of the right feeding chain 101. A receiving frame 109 is fixedly installed on the upper end of the slider 108. The receiving frames 109 are located on the left and right sides of the front of the transfer frame 4. Three connecting plates 505 are fixedly installed at equal intervals on the front of the moving frame 3 502. A heating gun 506 is fixedly installed at the bottom of the connecting plate 505. First, the inductor is placed on the feeding stripper head 2 in the form of a spring chain. Since the receiving wheel 202 on the feeding stripper head 2, the feeding chain 101, and the feeding wheel 105 are all provided with teeth for limiting, and there are two receiving wheels 202, which are slightly inclined to the outside, forming a shape that is narrow at the top and wide at the bottom, the receiving wheel 202 starts to rotate when driven by the motor 201. Due to the narrow top and wide bottom, Therefore, the inductor in the spring-loaded form separates from the paper tape and falls downwards onto the loading roller 105, which then conveys it to the feeding chain 101. During the feeding process, the feeding chain 101 first passes through the straightening roller 104, where the inductor leads are straightened to prevent bending. The straightened inductor is then sent to the inspection frame 3, which inspects the inductor. Qualified inductors continue to be conveyed to the right. When they reach the rightmost side of the feeding chain 101, the receiving frame 109 receives the inductor. Then, through the sliding connection between the slider 108 and the guide rail 107, the inductor slides a distance to the right and is then clamped by the movable clamp 409 on the far left of the front of the moving frame 403. Since the moving frame 403 is slidably connected to the transfer frame 4...Therefore, the movable frame 403 can slide a certain distance to the right. After sliding to the right, the movable clamp 409 is released, and the inductor is placed on the placement frame 503. Then, it is pressed downward by the fixed clamp 504, which cooperates with the placement frame 503 to clamp it. Then, the movable frame 403 returns to the left, so that the movable clamp 409 adjacent to the leftmost movable clamp 409 of the movable frame 403 can clamp the inductor. This set of operations is then repeated continuously. Since the inductor clamping structure formed by the placement frame 503 and the fixed clamp 504 is staggered with the movable clamp 409, this set of operations allows the inductor to move step by step to the right, until it reaches the placement frame 503. When the inductor is positioned at tube rack 6, the sleeve opening 601 can rotate the sleeve on the inductor pins. Then, as it passes the heating gun 506, the heating gun 506 preheats the sleeve on the inductor pins. Finally, the inductor is sent to the far right of the transfer rack 4 and received by the receiving rack 109 located on the right side of the transfer rack 4. The receiving rack 109 sends the inductor to the feeding chain 101 on the right. The feeding chain 101 sends the inductor to the baking oven 102 for sleeve baking, causing it to shrink tightly around the inductor pins, completing insulation and fixing. Finally, under the transport of the feeding chain 101, it reaches the tape head 103 for tape processing.

[0030] In this embodiment of the utility model, a feeding wheel 105 is rotatably mounted on the lower left side of the feeding chain 101. A feeding motor 106 is fixedly mounted below the feeding wheel 105. The output end of the feeding motor 106 is rotatably connected to the feeding wheel 105 via a transmission belt. A feeding stripping head 2 is located at the upper left side of the feeding chain 101. A motor 201 is fixedly mounted at the rear end of the feeding stripping head 2. A receiving wheel 202 is fixedly connected to the output end of the motor 201. The receiving wheel 202 is located above the feeding wheel 105. Because... The receiving wheel 202 on the feeding stripper head 2, the feeding chain 101, and the feeding wheel 105 are all provided with teeth for limiting. There are two receiving wheels 202, which are set slightly outward, forming a shape that is narrow at the top and wide at the bottom. Therefore, when the receiving wheel 202 is driven by the motor 201, it starts to rotate. Because it is narrow at the top and wide at the bottom, the inductor in the form of a spring chain will separate from the paper tape and then fall down onto the feeding wheel 105, and then be conveyed by the feeding wheel 105 to the feeding chain 101.

[0031] In this embodiment of the utility model, a fixing plate 301 is fixedly installed at the bottom of the detection frame 3, and a motor 302 is fixedly installed at the rear end of the fixing plate 301. A driven wheel 303 is rotatably installed below the motor 302. The driven wheel 303 is connected to the motor 302 by a transmission belt. A rotating rod 304 is fixedly installed at the output end of both the driven wheel 303 and the motor 302. A connecting block 305 is fixedly installed on the front of the rotating rod 304, and a fixing block 306 is fixedly installed on the other side of the front of the connecting block 305. A detection clamp 307 is fixedly installed at the bottom of the fixing block 306, and a waste trough 308 is fixedly installed below the detection clamp 307. When the inductor reaches the detection frame 3, the detection clamp 307 is driven by a cylinder to open and inspect the inductor. Clamping: Since the inner contact surface of the detection clamp 307 is made of copper, and the complete production line is equipped with a control system, the detection clamp 307 can perform inductance detection on inductor components. Then, it drives the motor 302. When the motor 302 rotates, it synchronously drives the driven wheel 303 through the transmission belt. At this time, the rotating rod 304 also rotates synchronously. The rotation of the rotating rod 304 drives the connecting block 305 to rotate. The rotation of the connecting block 305 drives the entire fixed block 306 to move to the right. If the product is qualified, it is directly moved to the right and placed on the feeding chain 101. If the detection is unqualified, the inductor component is put into the waste trough 308. Then, the motor 302 outputs in reverse, moving the fixed block 306 to the left to continue the new inductance detection.

[0032] In this embodiment of the utility model, a cylinder 401 is fixedly installed on the left end of the transfer frame 4. A slide groove 402 is provided on the upper end of the transfer frame 4, and the slide groove 402 is slidably connected to the moving frame 403. A moving end 404 is fixedly installed at the bottom of the moving frame 403 and is slidably connected to the slide groove 402. Guide rails 405 are fixedly installed on both the left and right sides of the front of the moving frame 403. A moving frame 406 is slidably installed on the front of the moving frame 403, and the guide rails 405 are slidably connected to the moving frame 406. Cylinders 407 are fixedly installed on both the left and right sides of the upper end of the moving frame 403. The output end of cylinder 407 is fixedly connected to the upper end of the moving frame 406. Several top heads 408 are fixedly installed on the front of the second frame 406, and are all located above the rear end of the movable clamp 409 and fixedly connected to it. The movable clamp 409 is divided into upper and lower parts. Gears 410 are fixedly installed on the inner side of the rear end of the movable clamp 409 and mesh with each other. Guide rails 501 are fixedly installed on the left and right sides of the front of the fixed frame 5. The guide rails 501 are slidably connected to the movable frame 502. When the inductive element is sent to the left side of the front end of the transfer frame 4 by the receiving frame 109, the second cylinder 407 is driven first. The output end of the second cylinder 407 drives the second movable frame 406 downward, so that the top heads 408 are moved downward to above the movable clamp 409. With continuous output, the top head 408 will contact the movable clamp 409 and apply downward pressure. Since the movable clamp 409 consists of two parts, upper and lower, and meshes with gears 410, with a transmission ratio of 1:1, the pressure on the rear end of the upper part of the movable clamp 409 will cause the lower part of the movable clamp 409 to open synchronously. Then, the receiving frame 109 moves to the left, moving the inductor to the movable clamp 409. Then, the output end of cylinder two 407 retracts, pulling the movable clamp 409 upward. Under the action of gear 410, the movable clamp 409 closes to clamp the inductor. Then, cylinder one 401 outputs, because the moving frame one 403 and... The transfer frame 4 is slidably connected, so the movable frame 403 can slide a certain distance to the right. After sliding to the right, the movable clamp 409 is released, and the inductor is placed on the placement frame 503. Then it is pressed down by the fixed clamp 504, which cooperates with the placement frame 503 to clamp it. Then the movable frame 403 returns to the left, so that the movable clamp 409 adjacent to the leftmost movable clamp 409 of the movable frame 403 can clamp the inductor. Then this set of operations is repeated continuously. Since the inductor clamping structure formed by the placement frame 503 and the fixed clamp 504 is staggered with the movable clamp 409, this set of operations can make the inductor move to the right step by step.

[0033] Working principle: The inductor element in the form of a spring chain is fed into the feeding stripper head 2. A receiving wheel 202 is driven to rotate by the motor 201. The receiving wheel 202 has a "narrower at the top and wider at the bottom" inclined design, and its surface teeth mesh with the spring chain. During rotation, it separates the inductor element from the paper tape and causes it to fall onto the feeding wheel 105. The feeding motor 106 drives the feeding wheel 105 via a belt, conveying the inductor element to the feeding chain 101. The feeding chain 101 conveys the inductor element through the straightening roller 104, which straightens the leads to ensure subsequent processing accuracy. When the inductor element reaches the detection frame 3, the detection clamp 307... Driven by a cylinder, the inductor opens and clamps the component. The detection clamp 307 on the copper contact surface performs electrical performance testing (such as inductance value) on the inductor through the control system. The motor 302 drives the driven wheel 303 via a belt, which in turn drives the rotating rod 304 to rotate. The rotating rod 304 drives the connecting block 305 and the fixing block 306 to move. Qualified products move to the right and are placed on the return feed chain 101. Defective products are put into the waste trough 308 below. The motor 302 rotates in the opposite direction to reset the mechanism, preparing for the next test. After the inductor component is fed to the receiving rack 109 by the feed chain 101, the left receiving rack 109 moves via a slider. 108 slides on guide rail 107, and the received inductor is transferred to the left side of transfer frame 4. Cylinder 2 407 drives moving frame 2 406 to move down, and the top head 408 causes movable clamp 409 to open. After receiving frame 109 moves to the left to release the material, cylinder 2 407 retracts, and movable clamp 409 closes to clamp the component. Cylinder 1 401 drives moving frame 1 403 to move to the right, transferring the component above placement frame 503. Movable clamp 409 is released, and the component is clamped by fixed clamp 504 and placement frame 503. Placement frame 503 / fixed clamp 504 and movable clamp 409 are arranged alternately, and the component is transferred by moving frame 406. The reciprocating motion of 403 enables the step-by-step transfer of components from left to right. When the component reaches the sleeve rack 6, the sleeve opening 601 rotates and inserts the insulating tube into the inductor pin. The component continues to move to the right below the heating gun 506 to preheat the sleeve and enhance the subsequent baking effect. The right receiving rack 109 receives the component at the end of the transfer rack 4 and moves to the right feeding chain 101 via the slider 108. The feeding chain 101 sends the component into the baking oven 102. The sleeve shrinks and tightly wraps the pin at high temperature, completing the insulation fixation. Finally, the component is transported by the feeding chain 101 to the tape head 103 for tape packaging.

Claims

1. A horizontal inductor bushing machine, comprising: A base (1) is provided with a feeding stripper head (2) fixedly installed on the upper left side of the base (1), a testing frame (3) fixedly installed on the right side of the feeding stripper head (2), a transfer frame (4) fixedly installed on the right side of the testing frame (3), a fixing frame (5) fixedly installed on the front of the transfer frame (4), and a sleeve frame (6) fixedly installed on the front of the fixing frame (5). The base (1) is characterized by having a movable frame (403) slidably installed on the upper front of the transfer frame (4), and several movable clamps (409) fixedly installed on the front of the movable frame (403). A movable frame three (502) is slidably installed on the upper front of the frame (5), and a placement frame (503) is fixedly installed below the movable frame three (502). Several fixing clips (504) are fixedly installed on the front of the movable frame three (502). The fixing clips (504) and the placement frame (503) are matched to form a complete clamping inductor structure and are staggered between the movable clips (409). The sleeve frame (6) has a sleeve opening (601) rotatably installed on the front and is matched with the movable clips (409), the placement frame (503), and the fixing clips (504).

2. A horizontal inductor bushing machine according to claim 1, characterized in that: A feeding chain (101) and a straightening roller (104) are rotatably installed on the base (1). A baking oven (102) and a braiding head (103) are fixedly installed on the base (1). The baking oven (102) is located on the right side of the transfer frame (4), and the braiding head (103) is located on the right side of the baking oven (102). The straightening roller (104) is located on the left side of the inspection frame (3). The feeding chain (101) is divided into two sections, one on the left side of the transfer frame (4) and the other on the right side of the transfer frame (4).

3. A horizontal inductor bushing machine according to claim 2, characterized in that: A feeding wheel (105) is rotatably mounted on the lower left side of the feeding chain (101). A feeding motor (106) is fixedly mounted below the feeding wheel (105). The output end of the feeding motor (106) is rotatably connected to the feeding wheel (105) via a transmission belt. A feeding stripping head (2) is located on the upper left side of the feeding chain (101). A motor (201) is fixedly mounted at the rear end of the feeding stripping head (2). A receiving wheel (202) is fixedly connected to the output end of the motor (201). The receiving wheel (202) is located above the feeding wheel (105).

4. A horizontal inductor bushing machine according to claim 2, characterized in that: The base (1) is fixedly mounted with a guide rail (107) on the upper end. Sliders (108) are slidably mounted on the left and right sides of the upper end of the guide rail (107). The left slider (108) is located at the end of the left feeding chain (101), and the right slider (108) is located at the beginning of the right feeding chain (101). A receiving rack (109) is fixedly mounted on the upper end of the slider (108). The receiving rack (109) is located on the left and right sides of the front of the transfer rack (4).

5. A horizontal inductor bushing machine according to claim 1, characterized in that: The bottom of the testing frame (3) is fixedly installed with a fixing plate (301), and a motor (302) is fixedly installed at the rear end of the fixing plate (301). A driven wheel (303) is rotatably installed below the motor (302). The driven wheel (303) and the motor (302) are connected by a transmission belt. A rotating rod (304) is fixedly installed at the output end of both the driven wheel (303) and the motor (302). A connecting block (305) is fixedly installed on the front of the rotating rod (304). A fixing block (306) is fixedly installed on the other side of the front of the connecting block (305). A testing clamp (307) is fixedly installed at the bottom of the fixing block (306). A waste trough (308) is fixedly installed below the testing clamp (307).

6. A horizontal inductor bushing machine according to claim 1, characterized in that: A cylinder (401) is fixedly installed on the left end of the transfer frame (4). A slide groove (402) is provided on the upper end of the transfer frame (4). The slide groove (402) is slidably connected to the moving frame (403). A moving end (404) is fixedly installed at the bottom of the moving frame (403) and is slidably connected to the slide groove (402).

7. A horizontal inductor bushing machine according to claim 6, characterized in that: The first movable frame (403) is fixedly installed with guide rails (405) on both the left and right sides of the front. The second movable frame (406) is slidably installed on the front of the first movable frame (403). The guide rails (405) and the second movable frame (406) are slidably connected. The second cylinder (407) is fixedly installed on both the left and right sides of the upper end of the first movable frame (403). The output end of the second cylinder (407) is fixedly connected to the upper end of the second movable frame (406).

8. A horizontal inductor bushing machine according to claim 7, characterized in that: The movable frame 2 (406) has several top heads (408) fixedly installed on its front side, and all of them are located above the rear end of the movable clamp (409) and fixedly connected to it. The movable clamp (409) is divided into upper and lower parts. Gears (410) are fixedly installed on the inner side of the rear end of the movable clamp (409) and mesh with each other.

9. A horizontal inductor bushing machine according to claim 1, characterized in that: The fixed frame (5) has guide rails (501) fixedly installed on both the left and right sides of the front. The guide rails (501) are slidably connected to the movable frame (502). The movable frame (502) has three connecting plates (505) fixedly installed at equal distances on the front. The heating gun (506) is fixedly installed at the bottom of the connecting plate (505).