CN116153652A - Inductance production equipment - Google Patents

Abstract

The invention provides an inductance production device, which comprises a mounting mechanism, a first connecting piece, a second connecting piece, a third connecting piece and a third connecting piece, wherein the mounting mechanism can mount the bottom piece into a mounting hole formed by two pins of the coil, and the mounting mechanism can mount the center post to the center of the coil; a transfer mechanism that transports the coil to the mounting mechanism; the feeding mechanism can enable the coil, the bottom plate and the center pillar to be transported to the transmission mechanism; the machine is used for bearing the mounting mechanism, the transmission mechanism and the feeding mechanism. The inductance production equipment can achieve the purpose of mass production of the inductance with consistent performance.

Description

Inductance production equipment

Technical Field

The invention relates to the field of new energy equipment production, in particular to inductance production equipment.

Background

In the prior art, an inductor mainly comprises a bottom plate, a middle column and a coil with pins, and the bottom plate, the middle column and the coil are assembled by manpower. This is not only inefficient, but the performance of the produced inductor is often not consistent.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides an inductor production device for realizing high-efficiency production of inductors with consistent performance.

To this end, in one embodiment there is provided an inductance production apparatus comprising:

the inductor comprises a negative film, a center pillar and a coil with pins;

a mounting mechanism capable of mounting the base sheet into mounting holes formed by two of the pins of the coil, the mounting mechanism being capable of mounting the center post to a center of the coil;

a transfer mechanism that transports the coil to the mounting mechanism;

the feeding mechanism can enable the coil, the bottom plate and the center pillar to be transported to the transmission mechanism;

the machine is used for bearing the mounting mechanism, the transmission mechanism and the feeding mechanism.

As a further alternative of the inductance production apparatus, the feeding mechanism includes a vibrating tray and a direct-vibration rail, the vibrating tray vibrates to send the coil, the bottom sheet and the center pillar to the direct-vibration rail, and the direct-vibration rail can move the coil, the bottom sheet and the center pillar along a length direction of the direct-vibration rail; the transmission mechanism can be connected with the direct vibration track for conveying the coil.

As a further alternative of the inductance production device, the coil keeps the pins upward on the direct vibration track, and the inductance production device further includes a turnover mechanism, the turnover mechanism can turn the coil up and down on the transmission mechanism, the turned coil keeps the pins downward on the transmission mechanism, the bottom plate and the coil are assembled before turning, and the coil and the center post are assembled after turning.

As a further alternative of the inductance production apparatus, the turnover mechanism includes a swing arm, a clamping jaw, and a motor, one point of the swing arm is connected with the clamping jaw, the other end of the swing arm is rotationally connected with the motor, and the clamping jaw can clamp the coil.

As a further alternative of the inductance producing apparatus, the mounting mechanism includes a first pushing mechanism capable of pushing the bottom sheet into the mounting hole of the coil when moving, the first pushing mechanism being capable of mounting the center pillar to the center of the coil.

As a further alternative of the inductance production device, the mounting mechanism further comprises an upper turntable and a lower turntable which are stacked, wherein the edges of the upper turntable and the lower turntable are provided with first notches, and the first notches of the lower turntable are arranged right above the transmission mechanism and aligned with the center of the coil; the first notch of the upper turntable can be connected with the direct vibration track and move the center pillar to the first notch of the upper turntable, and the upper turntable rotates to drive the center pillar to move to the first notch of the lower turntable.

As a further alternative of the inductance production device, the mounting mechanism further includes a circular enclosure ring provided on the upper turntable so that the center pillar does not drop out of the upper turntable when the upper turntable drives the center pillar to move.

As a further alternative of the inductance production apparatus, the mounting mechanism further includes a transfer rail, one end of the transfer rail is connected with the direct vibration rail, the other end of the transfer rail is connected with the mounting hole, and the first pushing mechanism can push the bottom plate into the mounting hole along the transfer rail.

As a further alternative of the inductance production apparatus, the direct vibration track is provided with a first pressing piece capable of restricting the bottom sheet and the center pillar from jumping up and down in the direct vibration track.

As a further alternative to the inductance producing device, the transmission mechanism includes a second presser piece capable of restricting the coil from jumping up and down in the transmission mechanism.

As a further alternative of the inductance production apparatus, the material placing mechanism includes a magnetic stripe having a magnetic force capable of adsorbing the inductance and a manipulator capable of placing the inductance onto the magnetic stripe.

As a further alternative scheme of inductance production equipment, pendulum material mechanism still includes magnetic stripe frame and second pushing mechanism, the magnetic stripe frame can the range upon range of sign indicating number the magnetic stripe, the magnetic stripe is put up and is had the second breach, the height of second breach is greater than the height of magnetic stripe, the second breach is dorsad second pushing mechanism sets up, second pushing mechanism will the magnetic stripe is pushed into transport mechanism.

As a further alternative of the inductance production device, the inductance production device further comprises a blanking plate and the third pushing mechanism, the magnetic strip is moved out of the transmission mechanism by the transmission mechanism and then pushed to the blanking plate by the third pushing mechanism, and the blanking plate is provided with a clearance space.

The implementation of the embodiment of the invention has the following beneficial effects:

according to the inductance production apparatus in the above embodiment, the feeding mechanism is responsible for transporting the coil to the transporting mechanism, transporting the bottom sheet and the center pillar to the mounting mechanism, transporting the coil to the mounting mechanism by the transporting mechanism, mounting the bottom sheet into the mounting hole formed by the two pins by the mounting mechanism, and mounting the center pillar to the center of the coil. All the procedures are automatically finished by a machine, so that the production efficiency of the inductor can be greatly improved, and the consistency of the produced inductor performance can be ensured. According to the inductance production equipment in the embodiment, the purpose of mass production of the inductance with consistent performance can be achieved.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Wherein:

FIG. 1 shows a schematic view of a coil, a bottom plate and a center post according to an embodiment of the present invention;

fig. 2 shows a schematic structural diagram of an inductance production apparatus according to an embodiment of the present invention;

fig. 3 shows another angular schematic view of an inductance production apparatus provided according to an embodiment of the present invention;

FIG. 4 shows a partial enlarged view at A in FIG. 2;

FIG. 5 shows a partial enlarged view at B in FIG. 2;

FIG. 6 shows a partial enlarged view at C in FIG. 2;

fig. 7 is a schematic structural diagram of an upper turntable and a lower turntable according to an embodiment of the present invention.

Description of main reference numerals:

inductance-1; a backsheet-11; center pillar-12; a coil-13; pin-14; a mounting hole-15;

a mounting mechanism-10; a first pushing mechanism-110; an upper turntable-120; a lower turntable 130; a first notch-140; a circular enclosure-150; a transfer rail-160;

a transmission mechanism-20; second tabletting-210;

a feeding mechanism-30; a vibrating tray-310; a direct-vibration track-320; first tabletting-3210;

a turnover mechanism-40; swing arm-410; jaw-420; a motor-430;

a material arranging mechanism-50; magnetic stripe-510; manipulator-520; a magnetic stripe rack-530; a second pushing mechanism-540;

blanking plate-550; avoidance of gaps-560; third pushing mechanism-570; second notch-5310;

and a machine table-60.

Detailed Description

In order that the invention may be readily understood, a more complete description of the invention will be rendered by reference to the appended drawings. Preferred embodiments of the present invention are shown in the drawings. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "fixed to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like are used herein for illustrative purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. The term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

In an embodiment of the present invention, please refer to fig. 1-3, an inductance production apparatus is provided, which includes:

the inductor comprises a bottom plate 11, a center pillar 12 and a coil 13 with pins 14;

a mounting mechanism 10, wherein the mounting mechanism 10 can mount the bottom plate 11 into a mounting hole 15 formed by two pins 14 of the coil 13, and the mounting mechanism 10 can mount the center post 12 to the center of the coil 13;

a transfer mechanism 20, the transfer mechanism 20 carrying the coil 13 to the mounting mechanism 10;

the feeding mechanism 30, the feeding mechanism 30 can make the coil 13 transported to the transmission mechanism 20 and transport the bottom plate 11 and the center pillar 12 to the installation mechanism 10;

the machine 60, the machine 60 is used for bearing the installation mechanism 10, the transmission mechanism 20 and the feeding mechanism 30.

According to the inductance producing apparatus in the above embodiment, the feeding mechanism 30 is responsible for transporting the coil 13 to the transporting mechanism 20, transporting the base sheet 11 and the center pillar 12 to the mounting mechanism 10, transporting the coil 13 to the mounting mechanism 10, mounting the base sheet 11 into the mounting hole 15 formed by the two pins 14 by the mounting mechanism 10, and mounting the center pillar 12 to the center of the coil 13. All the procedures are automatically finished by a machine, so that the production efficiency of the inductor can be greatly improved, and the consistency of the produced inductor performance can be ensured. According to the inductance production equipment in the embodiment, the purpose of mass production of the inductance with consistent performance can be achieved.

The transmission mechanism 20 can be a belt transmission, and the width of the transmission mechanism 20 is slightly larger than that of the coil 13, so that the coil 13 can be limited, and the operation of the installation mechanism 10 is convenient.

In some specific embodiments, referring to fig. 2-4, the feeding mechanism 30 includes a vibration plate 310 and a straight vibration rail 320, the vibration plate 310 vibrates to send the coil 13, the bottom plate 11 and the center pillar 12 to the straight vibration rail 320, and the straight vibration rail 320 can move the coil 13, the bottom plate 11 and the center pillar 12 along the length direction of the straight vibration rail 320; the transfer mechanism 20 can be in rail connection with the direct-vibration rail 320 of the conveyor coil 13.

The vibration plate 310 vibrates the coil 13, the base plate 11 and the center pillar 12, and if just the coil 13, the base plate 11 and the center pillar 12 fall into the straight vibration rail 320, the straight vibration rail 320 starts to transport the coil 13, the base plate 11 and the center pillar 12. The bottom plate 11 is rectangular, and two ends of the bottom plate in the length direction are also provided with bosses, and the bosses are upwards when the bottom plate 11 enters the direct vibration rail 320 due to the existence of the bosses during vibration. The width of the direct vibration track 320 is slightly larger than that of the bottom plate 11, so that the bottom plate 11 is ensured to be placed consistently when entering the direct vibration track 320, and the subsequent process is convenient. The shape of the center post 12 is cylindrical, so the width of the straight vibrating rail 320 of the center post 12 is slightly larger than the diameter of the center post 12. The above measures can lead the coil 13, the negative film 11 and the middle column 12 to complete full-automatic feeding, greatly reduce the manual use and improve the production efficiency.

In some specific embodiments, referring to fig. 2-4, the coil 13 is held with the pins on the direct vibration rail 320 upward, and the inductance production apparatus further includes a turnover mechanism 40, where the turnover mechanism 40 can turn the coil 13 up and down on the transmission mechanism 20, the turned coil 13 holds the pins downward on the transmission mechanism 20, the assembly of the bottom plate 11 and the coil 13 is completed before turning, and the assembly of the coil 13 and the center post 12 is completed after turning.

Generally, since the two bosses of the bottom plate 11 are upward during loading, the bosses are required to be connected to the pins of the coil 13 during assembly, and thus the coil 13 needs to be kept upward on the conveying mechanism 20 to facilitate the bottom plate 11 to be inserted into the mounting hole 15, and the bosses face the coil 13. In the center pillar 12 mounting process, since the center pillar 12 needs the bottom sheet 11 to be supported, the coil 13 to which the bottom sheet 11 has been mounted needs to be turned over so that the center pillar 12 falls from the center of the coil 13 and abuts against the bottom sheet 11.

In some specific embodiments, referring to fig. 3 and 4, the turnover mechanism 40 includes a swing arm 410, a clamping jaw 420 and a motor 430, one end of the swing arm 410 is connected to the clamping jaw 420, the other end of the swing arm 410 is rotatably connected to the motor 430, and the clamping jaw 420 can clamp the coil 13.

One end of the swing arm 410 is connected with a clamping jaw 420, the other end is connected with a motor 430, and the motor 430 drives the swing arm 410 to rotate 180 degrees around the motor 430. At this time, the jaw 420 of the coil 13 to which the base sheet 11 is fixedly attached is also turned 180 degrees, and at this time, the turning operation is completed just for the coil 13 to which the base sheet 11 is attached.

In some specific embodiments, referring to fig. 2 and 5, the mounting mechanism 10 includes a first pushing mechanism 110, where the first pushing mechanism 110 can push the bottom plate 11 into a mounting hole 15 formed by two pins of the coil 13 when moving, and the first pushing mechanism 110 can mount the center post 12 to the center of the coil 13.

The first pushing mechanism 110 is an embodiment of the mounting mechanism 10 that is realized by pushing to push the bottom plate 11 into the mounting hole 15 and the center pillar 12 into the center of the coil 13.

The coil 13 is positioned before the bottom plate 11 and the center pillar 12 are assembled. Specifically, a cylinder is inserted below the coil, and the cylinder is pushed by the cylinder. The coil 13 is now held by the cylinder. This will not cause misalignment when the backsheet 11 and the center post 12 are inserted into the coil 13. The cylinder may also be withdrawn upon insertion of the center post 12 to allow insertion of the center post 12.

Typically, the first pushing mechanism 110 is provided with two pushing mechanisms, which are respectively located at the installation position of the bottom plate 11 and the installation position of the middle column 12. The first pushing mechanism 110 may be a telescopic cylinder that pushes the bottom sheet 11 and the center pillar 12 by telescoping. Or, a fixed slide rail and a motor 430 arranged on the slide rail are arranged, and the motor 430 is started so as to realize the movement on the slide rail and realize the pushing of the bottom plate 11 and the center pillar 12 in the moving process. Besides, the screw rod structure can realize pushing effect. In the present embodiment, the structure capable of realizing the pushing function is the protection object of the present invention.

Further, the front end of the first pushing mechanism 110 is provided with a suction head or a clamping jaw 420, so that the first pushing mechanism 110 can ensure that the bottom plate 11 and the middle column 12 cannot be tripped when pushing the bottom plate 11 and the middle column 12.

In some specific embodiments, referring to fig. 3 and 7, the mounting mechanism 10 further includes an upper turntable 120 and a lower turntable 130 that are stacked, wherein edges of the upper turntable 120 and the lower turntable 130 are provided with a first notch 140, and the first notch 140 of the lower turntable 130 is disposed directly above the transmission mechanism 20 and aligned with the center of the coil 13; the first notch 140 of the upper turntable 120 can be connected with the direct vibration rail 320 and move the center pillar 12 to the first notch 140 of the upper turntable 120, and the rotation of the upper turntable 120 drives the center pillar 12 to move to the first notch 140 of the lower turntable 130.

Considering that the direct vibration rail 320 is vibrating all the time, it is not easy to transport the center pillar 12 just above the coil 13. The primary purpose of the upper and lower turntables 120 and 130 is to transport the center pole 12, increasing the success rate of the center pole 12 falling into the center of the coil 13.

Specifically, the center pillar 12 falls from the straight vibration rail 320 to the first notch 140 of the upper turntable 120, the lower turntable 130 remains fixed, and the upper turntable 120 starts to rotate, so that the center pillar 12 moves on the lower turntable 130 until the first notch 140 of the upper turntable 120 and the lower turntable 130 coincide. At this time, the center pillar 12 is located right above the coil 13, so that the first pushing mechanism 110 is just convenient to push the center pillar 12 into the center of the coil 13.

Specifically, at this time, the first pushing mechanism 110 is disposed right above the first notch 140 of the lower turntable 130, and the first pushing mechanism 110 pushes the center post 12 to pass through the first notch 140 and enter the center of the coil 13.

In some embodiments, the mounting mechanism 10 further includes a circular enclosure (not shown) that is disposed around the upper turntable 120 so that the middle pillar 12 does not fall out of the upper turntable 120 when the upper turntable 120 moves the middle pillar 12.

The purpose of the circular enclosure (not shown) is to ensure that the center pillar 12 is not thrown off the upper turntable 120 by centrifugal force during transport.

Typically, the rotation of the upper turntable 120 is also driven by the motor 430. And the first notch 140 of the upper dial 120 may be provided in plurality.

In some specific embodiments, referring to fig. 2 and 4, the mounting mechanism 10 further includes a transfer rail 160, one end of the transfer rail 160 is connected to the direct vibration rail 320, the other end of the transfer rail 160 is connected to the mounting hole 15, and the first pushing mechanism 110 can push the backsheet 11 into the mounting hole 15 along the transfer rail 160.

The transfer rail 160 is to achieve higher mounting accuracy when mounting the backsheet 11, and to avoid vibration interference of the direct vibration rail 320.

Specifically, the transfer rail 160 is connected with the direct vibration rail 320 vertically, after the negative film 11 in the direct vibration rail 320 falls into the transfer rail 160, the negative film 11 is pushed to the vicinity of the mounting hole 15 by the first pushing mechanism 110, and then the negative film 11 is pushed into the mounting hole 15 by the first pushing mechanism 110.

Alternatively, the transfer rail 160 itself can only accommodate one mounting plate 11, and the transfer rail 160 itself is pushed by the first pushing mechanism 110 to the vicinity of the mounting hole 15, and finally the plate 11 is pushed into the mounting hole 15 by the other first pushing mechanism 110.

It should be noted that there may be a plurality of first pushing mechanisms 110 to realize multi-stage pushing.

In some embodiments, the linear vibration rail 320 is provided with a first presser 3210, and the first presser 3210 is capable of limiting the upward and downward runout of the backsheet 11 and the center pillar 12 in the linear vibration rail 320.

The first pressing piece 3210 may cover the straight vibration rail 320 entirely, or may cover the straight vibration rail 320 half, and preferably cover the straight vibration rail 320 half. The semi-covered direct vibration track 320 is convenient to observe and maintain.

In some embodiments, the transfer mechanism 20 includes a second tab 210, the second tab 210 being capable of limiting the coil 13 from bouncing up and down in the transfer mechanism 20.

The principle of the second press 210 and the first press 3210 is the same, except that the mounting positions are different.

In some specific embodiments, please refer to fig. 2 and 6, the device further includes a material placing mechanism 50, the material placing mechanism 50 includes a magnetic strip 510 and a manipulator 520, the magnetic strip 510 has a magnetic force capable of adsorbing the inductor, and the manipulator 520 can place the inductor on the magnetic strip 510.

The assembled inductor 1 is still in a loose connection state, and needs to enter an oven for a period of time to be processed, so the manipulator 520 places the assembled inductor on the magnetic stripe 510, the magnetic stripe 510 has a certain magnetic force, so the negative film 11 and the middle column 12 can be adsorbed, and the negative film 11 is arranged in the mounting hole 15, so the inductor can be fixed together with the coil 13.

In some specific embodiments, the material placing mechanism 50 further includes a magnetic stripe frame 530 and a second pushing mechanism 540, the magnetic stripe frame 530 can stack the magnetic stripe 510, the magnetic stripe frame 530 is provided with a second notch 5310, the height of the second notch 5310 is greater than the height of the magnetic stripe 510, the second notch 5310 is disposed opposite to the second pushing mechanism 540, and the second pushing mechanism 540 pushes the magnetic stripe 510 into the transmission mechanism 20.

The magnetic stripe 510 rack is used for stacking the magnetic stripe 510, the upper end can add the magnetic stripe 510 at any time, the second notch 5310 is positioned at the bottom, and the second pushing mechanism 540 is convenient for pushing the lowest magnetic stripe 510 into the transmission mechanism 20.

In some embodiments, the magnetic strip feeding device further comprises a blanking plate 550 and a third pushing mechanism 570, wherein the magnetic strip 510 is pushed to the blanking plate 550 by the third pushing mechanism 570 after being moved out of the transmission mechanism 20 by the transmission mechanism 20, and the blanking plate 550 is provided with a clearance gap 560.

The third pushing mechanism 570 pushes the magnetic strip 510 with the inductor into the blanking plate 550, since the blanking plate 550 is provided with the clearance space 560. The operator can directly pick up the magnetic strip 510 with the inductor from the avoidance space 560.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The above examples illustrate only a few embodiments of the invention, which are described in detail and are not to be construed as limiting the scope of the claims. It should be noted that it will be apparent to those skilled in the art that several variations and modifications can be made without departing from the spirit of the invention, which are all within the scope of the invention. Accordingly, the scope of protection of the present invention is to be determined by the appended claims.

Claims (13)

1. An inductance production facility, the inductance includes film, center pillar and has the coil of pin, characterized in that includes:

a mounting mechanism capable of mounting the base sheet into mounting holes formed by two of the pins of the coil, the mounting mechanism being capable of mounting the center post to a center of the coil;

a transfer mechanism that transports the coil to the mounting mechanism;

the feeding mechanism can enable the coil to be transported to the transmission mechanism and transport the bottom plate and the center pillar to the installation mechanism;

the machine is used for bearing the mounting mechanism, the transmission mechanism and the feeding mechanism.

2. The inductance production apparatus of claim 1, wherein the feeding mechanism includes a vibrating tray and a direct vibrating rail, the vibrating tray vibrating to feed the coil, the bottom sheet and the center pillar to the direct vibrating rail, the direct vibrating rail being capable of moving the coil, the bottom sheet and the center pillar along a length direction of the direct vibrating rail; the transmission mechanism can be connected with the direct vibration track for conveying the coil.

3. The inductance production apparatus of claim 2, wherein the coil holds the pins upward on the direct vibration rail, the inductance production apparatus further comprising a turnover mechanism capable of turning the coil up and down on the transfer mechanism, the turned coil holding pins downward on the transfer mechanism, the bottom sheet and the coil being assembled before turning, the coil and the center post being assembled after turning.

4. The inductance production apparatus of claim 3, wherein the turnover mechanism includes a swing arm, a jaw, and a motor, one end of the swing arm is connected to the jaw, the other end of the swing arm is rotatably connected to the motor, and the jaw is capable of gripping the coil.

5. The inductance production apparatus according to claim 2, wherein the mounting mechanism includes a first pushing mechanism capable of pushing the bottom sheet into the mounting hole of the coil when moved, the first pushing mechanism being capable of mounting the center pillar to the center of the coil.

6. The inductance production apparatus of claim 5, wherein the mounting mechanism further comprises an upper turntable and a lower turntable arranged in a stacked manner, first notches are provided at edges of the upper turntable and the lower turntable, and the first notches of the lower turntable are provided right above the transmission mechanism and aligned with a center of the coil; the first notch of the upper turntable can be connected with the direct vibration track and move the center pillar to the first notch of the upper turntable, and the upper turntable rotates to drive the center pillar to move to the first notch of the lower turntable.

7. The inductance production apparatus of claim 6, wherein the mounting mechanism further includes a circular enclosure ring disposed on the upper turntable such that the center post does not fall out of the upper turntable when the upper turntable moves the center post.

8. The inductance production apparatus of claim 5, wherein the mounting mechanism further includes a transfer rail, one end of the transfer rail is in contact with the direct vibration rail, the other end of the transfer rail is in contact with the mounting hole, and the first pushing mechanism is capable of pushing the bottom sheet into the mounting hole along the transfer rail.

9. The inductance production apparatus according to claim 2, wherein the direct vibration rail is provided with a first presser piece capable of restricting the bottom sheet and the center pillar from jumping up and down in the direct vibration rail.

10. The inductance production apparatus of claim 2, wherein the transmission mechanism includes a second tab capable of limiting the coil jumping up and down in the transmission mechanism.

11. The inductance production apparatus of claim 1, further comprising a swing mechanism including a magnetic strip having a magnetic force capable of attracting the inductance and a manipulator capable of placing the inductance onto the magnetic strip.

12. The inductance production apparatus of claim 11, wherein the material placing mechanism further comprises a magnetic stripe rack and a second pushing mechanism, the magnetic stripe rack is capable of stacking the magnetic stripes, the magnetic stripe rack is provided with a second notch, the height of the second notch is greater than the height of the magnetic stripes, the second notch is arranged opposite to the second pushing mechanism, and the second pushing mechanism pushes the magnetic stripes into the transmission mechanism.

13. The inductance production apparatus of claim 12, further comprising a blanking plate and a third pushing mechanism, the transfer mechanism moving the magnetic strip out of the transfer mechanism and then pushing the magnetic strip to the blanking plate by the third pushing mechanism, the blanking plate being provided with a clearance space.

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