CN112808887A - Inductor bending device - Google Patents

Abstract

The invention relates to the technical field of inductor processing, and discloses an inductor bending device, which comprises: the pressing assembly comprises a base plate, a guide pillar and a pressing sliding plate, the guide pillar is connected to the base plate, the pressing sliding plate is connected to the guide pillar in a sliding mode, and the pressing sliding plate is connected with a press machine and can slide along the guide pillar in a reciprocating mode under the driving of the press machine; the side sliding component comprises a side sliding plate and a side pushing plate, the side pushing plate is connected to the lower pressing sliding plate, and the side sliding plate is connected to the bottom plate in a sliding mode; the cutting assembly comprises a cutting knife and a cutting jig, the cutting knife is connected to the side sliding plate, and the cutting jig is detachably connected to the bottom plate; including the subassembly of bending of infolding side ejector pad, infolding upward briquetting and infolding tool, infolding side ejector pad is connected on the side slide, and infolding upward briquetting is connected on pushing down the slide, and infolding tool detachably connects on the bottom plate. The inductance bending device is convenient to debug, high in universality, capable of being used for cutting and bending of the inductance pins and suitable for manufacturing inductance sample pieces.

Description

Inductor bending device

Technical Field

The invention relates to the technical field of inductor processing, in particular to an inductor bending device.

Background

The integrally formed inductor is called as an integral inductor, a powder alloy inductor or a die-pressed inductor, and comprises a magnet and a coil winding, wherein the coil winding is embedded in metal magnetic powder by the magnet and is formed by die-casting, and a common Surface Mounted Device (SMD) pin is directly formed on the Surface of a product as a lead-out pin of a coil winding body. With the increasing dominant frequency of Central Processing Units (CPUs) of computers and mobile phones, the requirements on stable power supply and filtering are also increasing, and the integrally formed inductor can stably supply power to the CPUs while working for a long time under the condition of large current. In addition, the good material characteristics of the integrally formed inductor and the special structural design make the inductor structure more stable, lower in impedance, better in anti-seismic performance, and high in conversion efficiency, and begin to be widely applied.

The main processes of manufacturing the integrally formed inductor comprise powder making, winding, spot welding, forming, baking, paint spraying, bending, appearance checking, bag testing and the like. The bending process refers to cutting two pins of the inductor into a specified length and bending the pins to be attached to the pin grooves on the surface of a product. Technical personnel of product research and development often need to make many kinds of samples according to different requirements, and many processes of making samples can be made (such as baking and painting) along with mass production products, and also can be replaced by manual work (such as appearance detection and bag detection), but some processes have certain particularity due to different product models, for example, different moulds are needed in a forming process due to different product sizes, and different jigs are needed in a bending process.

Because inductance product type and specification model are very various, the research and development personnel need frequently switch the model on the mass production line in the process of bending of trial-manufacture sample, debug equipment, still need to reform transform improper equipment sometimes even, not only seriously influence the normal production in batch production workshop, still consume a large amount of time energy, and occupy efficient production facility on the mass production line.

Disclosure of Invention

The invention aims to provide an inductance bending device which is convenient to debug, high in universality, capable of being used for cutting and bending inductance pins and suitable for manufacturing inductance sample pieces.

In order to achieve the purpose, the invention adopts the following technical scheme:

an inductance bending device, comprising: the pressing assembly comprises a bottom plate, a guide pillar and a pressing sliding plate, the guide pillar is connected to the bottom plate, the pressing sliding plate is connected to the guide pillar in a sliding mode, and the pressing sliding plate is connected with a press machine and can slide in a reciprocating mode along the length direction of the guide pillar under the driving of the press machine; the side sliding assembly comprises a side sliding plate and a side pushing plate, the side pushing plate is connected to the lower pressing sliding plate, the side sliding plate is connected to the bottom plate in a sliding mode, and the side pushing plate is used for driving the side sliding plate to move; the cutting assembly comprises a cutting knife and a cutting jig, the cutting knife is connected to the side sliding plate, the cutting jig is detachably connected to the bottom plate, and the cutting knife is used for cutting pins of the inductor on the cutting jig; the bending assembly comprises an inward-bending side push block, an inward-bending upper press block and an inward-bending jig, the inward-bending side push block is connected to the side sliding plate, the inward-bending upper press block is connected to the downward-pressing sliding plate, the inward-bending jig is detachably connected to the bottom plate, and the inward-bending side push block and the inward-bending upper press block are used for bending pins of an inductor on the inward-bending jig.

As an optimal scheme of the inductor bending device, the inductor bending device further comprises a downward bending assembly, the downward bending assembly comprises a pre-pressing mechanism and a downward bending jig, the pre-pressing mechanism is installed on the downward-pressing sliding plate, the downward bending jig is detachably installed on the bottom plate, and the pre-pressing mechanism is used for performing downward bending operation on pins of the inductor.

As an optimal scheme of the inductor bending device, the prepressing mechanism comprises a pressing mechanism, the pressing mechanism comprises an optical axis, a compression spring and a prepressing plate, one end of the optical axis is connected to the lower pressing sliding plate in a sliding mode, the other end of the optical axis is connected to the prepressing plate, the compression spring is sleeved on the optical axis and clamped between the lower pressing sliding plate and the prepressing plate, and the prepressing plate is used for compressing the inductor to the lower bending jig and the cutting jig.

As a preferred scheme of the inductance bending device, the pressing mechanism further includes a fixing ring, the fixing ring is fixedly connected to one end, away from the pre-pressing plate, of the optical axis, and the fixing ring is used for preventing the optical axis from coming off from the press-down sliding plate.

As a preferred scheme of the inductor bending device, the pre-pressing mechanism further comprises a downward bending mechanism, the downward bending mechanism comprises a downward bending mounting seat, a bearing mounting seat and a first bearing, the downward bending mounting seat is connected to the downward pressing sliding plate, the bearing mounting seat is connected to the downward bending mounting seat, the first bearing is mounted on the bearing mounting seat, and the first bearing is used for bending a pin of the inductor.

As a preferred scheme of the inductance bending device, the downward bending mechanism further comprises an adjusting plate and an adjusting screw, the bearing mounting seat is slidably connected to the downward bending mounting seat, the adjusting plate is connected to the bearing mounting seat, one end of the adjusting screw is connected to the downward bending mounting seat, and the thread of the adjusting screw is connected with the adjusting plate through a threaded hole.

As an optimal scheme of the inductor bending device, the inductor bending device further comprises a pre-bending assembly, the pre-bending assembly comprises a pre-bending side pushing block and a pre-bending jig, the pre-bending side pushing block is connected to the side sliding plate, the pre-bending jig is detachably mounted on the bottom plate, and the pre-bending side pushing block is used for pre-bending the pins of the inductor.

As a preferred scheme of the inductance bending device, a follow-up bearing assembly is arranged on the side sliding plate, the follow-up bearing assembly comprises a bearing seat and a second bearing, the bearing seat is mounted on the side sliding plate, the second bearing is mounted on the bearing seat, a side push plate is provided with a side push inclined surface, and the side push inclined surface can drive the side sliding plate to move by pushing the second bearing.

As a preferred scheme of the inductance bending device, a sliding rail is arranged on the bottom plate, a sliding block is arranged on the side sliding plate, and the sliding block is connected to the sliding rail in a sliding manner.

As an inductance bending device's preferred scheme, the side slip subassembly still includes reset spring and slide dog, reset spring follows the direction of slide rail is arranged, reset spring's one end connect in the side slide, reset spring's the other end connect in cut the tool or on the infolding tool, the slide dog connect in on the bottom plate and keep off locate the side slide is kept away from one side of reset spring.

The invention has the beneficial effects that:

the invention provides an inductance bending device which comprises a pressing assembly, a side sliding assembly, a cutting assembly and a bending assembly, wherein a pressing sliding plate of the pressing assembly can drive a side pushing plate to act under the action of a press machine, so that the side sliding plate is driven to move, and a cutting knife is driven to cut pins of an inductance on a cutting jig; meanwhile, the inward-folding side push block and the inward-folding upper press block which moves along with the downward-pressing slide block can be driven to bend pins of the inductor on the inward-folding jig, and the pins of the inductor can be cut and bent. In addition, because the cutting jig and the inward-folding jig in the inductance bending device are both detachably mounted, the bottom plate is convenient to detach, the debugging convenience and the universality of the inductance bending device are greatly improved, and the inductance bending device is suitable for manufacturing inductance samples.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings used in the description of the embodiments of the present invention will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the contents of the embodiments of the present invention and the drawings without creative efforts.

Fig. 1 is a schematic view of an inductive bending apparatus according to an embodiment of the present invention;

fig. 2 is a left side view of an inductance bending apparatus according to an embodiment of the present invention;

FIG. 3 is a cross-sectional view taken at A-A of FIG. 2;

fig. 4 is a schematic view of an inductive bending apparatus according to an embodiment of the present invention.

In the figure:

11. a base plate; 111. a slide rail; 112. a slider; 12. a guide post; 13. pressing the sliding plate downwards; 21. a side slide plate; 211. a bearing seat; 212. a second bearing; 22. a side push plate; 23. a return spring; 24. a slide plate stopper; 31. cutting knife; 32. cutting a jig; 41. inwards folding the side push block; 42. folding the upper pressing block inwards; 43. inward folding jigs; 51. a pre-pressing mechanism; 511. an optical axis; 512. a compression spring; 513. pre-pressing a plate; 514. a fixing ring; 515. a downward bending mounting seat; 516. a bearing mount; 517. a first bearing; 518. an adjustment plate; 519. adjusting the screw; 52. a downward bending jig; 61. pre-bending the side push block; 62. a pre-bending jig.

Detailed Description

In order to make the technical problems solved, technical solutions adopted and technical effects achieved by the present invention clearer, the technical solutions of the embodiments of the present invention will be described in further detail below with reference to the accompanying drawings, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the description of the present invention, unless expressly stated or limited otherwise, the terms "connected," "connected," and "fixed" are to be construed broadly, e.g., as meaning permanently connected, removably connected, or integral to one another; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

In the present invention, unless otherwise expressly stated or limited, "above" or "below" a first feature means that the first and second features are in direct contact, or that the first and second features are not in direct contact but are in contact with each other via another feature therebetween. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.

The technical solution of the inductance bending device provided by the present invention is further described by the specific embodiment with reference to the accompanying drawings.

The embodiment provides an inductance bending device, as shown in fig. 1-4, the inductance bending device includes a pressing assembly, a side sliding assembly, a cutting assembly and a bending assembly, the pressing assembly includes a bottom plate 11, a guide pillar 12 and a push-down sliding plate 13, the guide pillar 12 is fixedly connected to the bottom plate 11, the push-down sliding plate 13 is slidably connected to the guide pillar 12, and the push-down sliding plate 13 is connected to a press and can slide back and forth along the length direction of the guide pillar 12 under the driving of the press. Preferably, the push-down sliding plate 13 is mounted with a linear bearing, and the guide post 12 is slidably disposed through the linear bearing, so that the reciprocating sliding between the push-down sliding plate 13 and the guide post 12 is smooth.

In the present embodiment, as shown in fig. 1, the side sliding assembly includes a side sliding plate 21 and a side pushing plate 22, the side pushing plate 22 is connected to the push-down sliding plate 13, the side sliding plate 21 is slidably connected to the bottom plate 11, and the side pushing plate 22 is used for driving the side sliding plate 21 to move. Preferably, the side sliding plate 21 is provided with a follow-up bearing assembly, the follow-up bearing assembly comprises a bearing seat 211 and a second bearing 212, the bearing seat 211 is mounted on the side sliding plate 21, and the second bearing 212 is rotatably mounted on the bearing seat 211. The side push plate 22 is provided with a side push inclined surface, and the side push inclined surface forms a certain angle with the extending direction of the guide pillar 12, so that when the side push plate 22 approaches the side slide plate 21 along with the push down slide plate 13, the side push inclined surface can contact with the second bearing 212 and push the second bearing 212 to drive the side slide plate 21 to move.

Furthermore, a slide rail 111 is arranged on the bottom plate 11, a slide block 112 is arranged on the side sliding plate 21, and the slide block 112 is slidably connected to the slide rail 111, so that the side sliding plate 21 can slide smoothly relative to the bottom plate 11. Specifically, the side sliding assembly further comprises a return spring 23 and a sliding plate stopper 24, the return spring 23 is arranged along the direction of the slide rail 111, one end of the return spring 23 is connected to the side sliding plate 21, the other end of the return spring 23 is connected to the cutting jig 32 or the inward folding jig 43, and the sliding plate stopper 24 is connected to the bottom plate 11 and is arranged on one side of the side sliding plate 21 away from the return spring 23 in a blocking manner. When the side push plate 22 drives the side slide plate 21 to move, the return spring 23 is compressed and deformed, when the side push plate 22 is separated from the side slide plate 21, the return spring 23 extends to drive the side slide plate 21 to return, and the side slide plate 21 is blocked to a specified position by the slide plate stopper 24.

Preferably, the cutting assembly includes a cutting knife 31 and a cutting jig 32, the cutting knife 31 is connected to the side sliding plate 21 and can move along with the side sliding plate 21, the cutting jig 32 is detachably connected to the bottom plate 11, and the cutting knife 31 is used for cutting the pins of the inductor placed on the cutting jig 32. Because cutting jig 32 detachably connects on bottom plate 11 for it is convenient to cut the dismantlement of jig 32 on bottom plate 11, and cutting jig 32 can change according to the model and the size of inductance, has improved this inductance bending device's debugging convenience and commonality by a wide margin, makes this inductance bending device be suitable for the appearance preparation of inductance.

In this embodiment, the bending assembly includes an inward-folding side pushing block 41, an inward-folding upper pressing block 42 and an inward-folding jig 43, the inward-folding side pushing block 41 is connected to the side sliding plate 21, the inward-folding upper pressing block 42 is connected to the lower pressing sliding plate 13, and the inward-folding jig 43 is detachably connected to the bottom plate 11. When the downward-pressing sliding plate 13 moves under the action of the press machine, the side push plate 22 drives the side sliding plate 21 to move, the inward-folding side push block 41 moves along with the side sliding plate 21, the inward-folding upper press block 42 moves along with the downward-pressing sliding plate 13, and the inward-folding side push block 41 and the inward-folding upper press block 42 are used for bending pins of the inductor on the inward-folding jig 43.

The pressing sliding plate 13 of the pressing assembly can drive the side pushing plate 22 to move under the action of the press machine, so that the side sliding plate 21 is driven to move, and the cutting knife 31 is driven to cut the pins of the inductor on the cutting jig 32; meanwhile, the inward-folding side push block 41 and the inward-folding upper press block 42 which moves along with the downward-pressing slide block 112 can be driven to bend the pins of the inductor on the inward-folding jig 43, so that the pins of the inductor can be cut and bent. In addition, because the cutting jig 32 and the inward folding jig 43 in the inductance bending device are both detachably mounted, the bottom plate 11 is convenient to detach, the debugging convenience and the universality of the inductance bending device are greatly improved, and the inductance bending device is suitable for manufacturing inductance samples.

Preferably, the inductor bending device further comprises a downward bending assembly, the downward bending assembly comprises a prepressing mechanism 51 and a downward bending jig 52, the prepressing mechanism 51 is mounted on the downward pressing sliding plate 13, the downward bending jig 52 is detachably mounted on the bottom plate 11, and the prepressing mechanism 51 is used for performing downward bending operation on the pins of the inductor, so that the pins of the inductor can be bent towards the bottom plate 11. Because the downward bending jig 52 is detachably mounted on the bottom plate 11, the downward bending jig 52 can be replaced according to the model and the size of the inductor, so that the debugging convenience and the universality of the inductor bending device are improved, and the inductor bending device is suitable for manufacturing inductor samples.

In this embodiment, as shown in fig. 3, the pre-pressing mechanism 51 includes a pressing mechanism, the pressing mechanism includes an optical axis 511, a compression spring 512, and a pre-pressing plate 513, one end of the optical axis 511 is slidably connected to the down-pressing sliding plate 13, the other end of the optical axis 511 is connected to the pre-pressing plate 513, the compression spring 512 is sleeved on the optical axis 511 and is sandwiched between the down-pressing sliding plate 13 and the pre-pressing plate 513, and the pre-pressing plate 513 is configured to press the inductor onto the down-bending jig 52 and the cutting jig 32, so that the inductor can be pressed onto the pressing jig by the pre-pressing plate 513 when the down-bending and the. Preferably, the push-down sliding plate 13 is provided with an oilless bushing, and the optical axis 511 is slidably connected in the oilless bushing, so that the optical axis 511 can slide smoothly relative to the push-down sliding plate 13. Further, the pressing mechanism further includes a fixing ring 514, the fixing ring 514 is fixedly connected to an end of the optical axis 511 away from the pre-pressing plate 513, and the fixing ring 514 can block the optical axis 511 to prevent the optical axis 511 from coming out of the oil-free bush of the press-down sliding plate 13.

When the press machine drives the press-down sliding plate 13 to move close to the bottom plate 11, the prepressing plate 513 of the pressing mechanism can press the inductor on the downward bending jig 52 and the cutting jig 32, the compression spring 512 is compressed and provides a certain elastic restoring force, the inductor is tightly pressed on the downward bending jig 52 and the cutting jig 32, and the inductor bending device can be prevented from displacing when pins of the inductor are bent downward and cut.

In this embodiment, as shown in fig. 2 and 4, the pre-pressing mechanism 51 further includes a downward bending mechanism, the downward bending mechanism includes a downward bending mounting seat 515, a bearing mounting seat 516, and a first bearing 517, the downward bending mounting seat 515 is connected to a side of the downward pressing sliding plate 13 close to the bottom plate 11, the bearing mounting seat 516 is connected to the downward bending mounting seat 515, the first bearing 517 is rotatably mounted on the bearing mounting seat 516, and the first bearing 517 is used for bending a lead of the inductor. When the push-down slider 13 moves close to the bottom plate 11, the downward bending mechanism moves along with the push-down slider 13, the first bearing 517 presses the lead pin of the inductor, and the lead pin of the inductor is bent along with the continuous movement of the push-down slider 13 to complete the downward bending operation.

Preferably, the downward bending mechanism further comprises an adjusting plate 518 and an adjusting screw 519, the bearing mounting seat 516 is slidably connected to the downward bending mounting seat 515, the adjusting plate 518 is connected to the bearing mounting seat 516 and provided with a threaded hole, one end of the adjusting screw 519 is connected to the downward bending mounting seat 515, and the threaded hole of the adjusting plate 518 is connected with the threaded hole of the adjusting screw 519, so that when the adjusting screw 519 rotates, the adjusting plate 518 can be driven to move by the threaded hole of the adjusting screw 519, the bearing mounting seat 516 is driven to move, the distance between the bearing mounting seat 516 and the downward bending jig 52 can be adjusted, the inductance bending device can perform downward bending operation on inductances of various sizes and specifications, the debugging convenience and the universality of the inductance bending device are improved, and the inductance bending device is suitable for manufacturing inductance samples.

In this embodiment, the inductor bending device further includes a pre-bending assembly, the pre-bending assembly includes a pre-bending side pushing block 61 and a pre-bending jig 62, the pre-bending side pushing block 61 is connected to the side sliding plate 21, the pre-bending jig 62 is detachably mounted on the bottom plate 11, and the pre-bending side pushing block 61 can perform pre-bending operation on the pins of the inductor under the combined action of the pre-bending jig 62 when moving along with the side sliding plate 21. Because pre-bending jig 62 is detachably mounted on bottom plate 11, pre-bending jig 62 can be replaced according to the model and size of the inductor, so that the debugging convenience and universality of the inductor bending device are improved, and the inductor bending device is suitable for manufacturing inductor samples.

Through the structure, the inductance bending device can complete downward bending, cutting, pre-bending and inward bending of the pins of the inductance, and the down-bending jig 52, the cutting jig 32, the pre-bending jig 62 and the inward bending jig 43 are detachably mounted, so that the inductance bending device can improve the universality through replacing the down-bending jig 52, the cutting jig 32, the pre-bending jig 62 and the inward bending jig 43, and the inductance bending device is suitable for manufacturing inductance samples.

It should be understood that the above-described embodiments of the present invention are merely examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention. Numerous obvious variations, adaptations and substitutions will occur to those skilled in the art without departing from the scope of the invention. And are neither required nor exhaustive of all embodiments. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.

Claims (10)

1. An inductance bending device, comprising:

the pressing assembly comprises a bottom plate (11), a guide post (12) and a pressing sliding plate (13), the guide post (12) is connected to the bottom plate (11), the pressing sliding plate (13) is connected to the guide post (12) in a sliding mode, and the pressing sliding plate (13) is connected with a press machine and can slide in a reciprocating mode along the length direction of the guide post (12) under the driving of the press machine;

the side sliding assembly comprises a side sliding plate (21) and a side pushing plate (22), the side pushing plate (22) is connected to the downward pressing sliding plate (13), the side sliding plate (21) is connected to the bottom plate (11) in a sliding mode, and the side pushing plate (22) is used for driving the side sliding plate (21) to move;

the cutting assembly comprises a cutting knife (31) and a cutting jig (32), the cutting knife (31) is connected to the side sliding plate (21), the cutting jig (32) is detachably connected to the bottom plate (11), and the cutting knife (31) is used for cutting pins of the inductor on the cutting jig (32);

the bending assembly comprises an inward-folding side pushing block (41), an inward-folding upper pressing block (42) and an inward-folding jig (43), the inward-folding side pushing block (41) is connected onto the side sliding plate (21), the inward-folding upper pressing block (42) is connected onto the downward-pressing sliding plate (13), the inward-folding jig (43) is detachably connected onto the bottom plate (11), and the inward-folding side pushing block (41) and the inward-folding upper pressing block (42) are used for bending pins of the inductor on the inward-folding jig (43).

2. The inductance bending device according to claim 1, further comprising a downward bending assembly, wherein the downward bending assembly comprises a pre-pressing mechanism (51) and a downward bending jig (52), the pre-pressing mechanism (51) is mounted on the downward-pressing sliding plate (13), the downward bending jig (52) is detachably mounted on the bottom plate (11), and the pre-pressing mechanism (51) is used for performing downward bending operation on the pins of the inductance.

3. The inductance bending device according to claim 2, wherein the pre-pressing mechanism (51) comprises a pressing mechanism, the pressing mechanism comprises an optical axis (511), a compression spring (512) and a pre-pressing plate (513), one end of the optical axis (511) is connected to the lower pressing sliding plate (13) in a sliding manner, the other end of the optical axis (511) is connected to the pre-pressing plate (513), the compression spring (512) is sleeved on the optical axis (511) and clamped between the lower pressing sliding plate (13) and the pre-pressing plate (513), and the pre-pressing plate (513) is used for pressing the inductance onto the lower bending jig (52) and the cutting jig (32).

4. The inductance bending device according to claim 3, wherein the pressing mechanism further comprises a fixing ring (514), the fixing ring (514) is fixedly connected to an end of the optical axis (511) far away from the pre-pressing plate (513), and the fixing ring (514) is used for preventing the optical axis (511) from being pulled out of the press-down sliding plate (13).

5. The inductance bending device according to claim 2, wherein the pre-pressing mechanism (51) further comprises a downward bending mechanism, the downward bending mechanism comprises a downward bending mounting seat (515), a bearing mounting seat (516) and a first bearing (517), the downward bending mounting seat (515) is connected to the downward pressing sliding plate (13), the bearing mounting seat (516) is connected to the downward bending mounting seat (515), the first bearing (517) is mounted on the bearing mounting seat (516), and the first bearing (517) is used for bending a pin of the inductance.

6. The inductive bending apparatus according to claim 5, wherein the downward bending mechanism further comprises an adjusting plate (518) and an adjusting screw (519), the bearing mount (516) is slidably connected to the downward bending mount (515), the adjusting plate (518) is connected to the bearing mount (516), one end of the adjusting screw (519) is connected to the downward bending mount (515), and a thread of the adjusting screw (519) is connected to the adjusting plate (518) through a threaded hole.

7. The inductance bending device according to claim 1, further comprising a pre-bending assembly, wherein the pre-bending assembly comprises a pre-bending side pushing block (61) and a pre-bending jig (62), the pre-bending side pushing block (61) is connected to the side sliding plate (21), the pre-bending jig (62) is detachably mounted on the bottom plate (11), and the pre-bending side pushing block (61) is used for pre-bending the pins of the inductance.

8. The inductance bending device according to claim 1, wherein a follower bearing assembly is arranged on the side sliding plate (21), the follower bearing assembly comprises a bearing seat (211) and a second bearing (212), the bearing seat (211) is mounted on the side sliding plate (21), the second bearing (212) is mounted on the bearing seat (211), and a side push plate (22) is provided with a side push inclined surface which can drive the side sliding plate (21) to move by pushing the second bearing (212).

9. The inductance bending device according to claim 1, wherein a slide rail (111) is disposed on the bottom plate (11), a slider (112) is disposed on the side sliding plate (21), and the slider (112) is slidably connected to the slide rail (111).

10. The inductance bending device according to claim 9, wherein the side sliding assembly further comprises a return spring (23) and a sliding plate stopper (24), the return spring (23) is arranged along the direction of the slide rail (111), one end of the return spring (23) is connected to the side sliding plate (21), the other end of the return spring (23) is connected to the cutting jig (32) or the inward folding jig (43), and the sliding plate stopper (24) is connected to the bottom plate (11) and is arranged on one side of the side sliding plate (21) away from the return spring (23) in a blocking manner.

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