CN116230397A - Winding and coating device and method for processing inductance element - Google Patents

Abstract

The invention discloses a winding and coating device and method for processing an inductance element. The beneficial effects of the invention are as follows: through setting up initiative hack lever and the driven hack lever that is the cross, can drive inductance element and rotate 90 at every turn, and carry out centre gripping material loading in proper order, brush glue, wind a roll and loosen the clamp blowing operation, realize the processing of the flow of winding preparation to inductance element, in addition, when carrying out the operation of corresponding step to one of them inductance element, the device can also drive other inductance element and carry out the operation of other different steps in step, can improve the operating efficiency, and can coil the winding again after the online brush glue, ensure evenly to brush insulating glue on inductance element, and then improve inductance element's insulativity.

Description

Winding and coating device and method for processing inductance element

Technical Field

The invention relates to an inductance winding and cladding device, in particular to a winding and cladding device and method for processing an inductance element, and belongs to the technical field of inductance production.

Background

The inductor has unique advantages in the fields of consumer electronics, digital products, automobile electronics and the like, mainly comprises a coil, a magnetic core and an electrode, and under the trend of the development of electronic products towards small, light and high performance, higher requirements are put forward on the reliability and integrated design of the patch inductor, and in the preparation process of the inductor element, a winding tape is often wound on the surface of the inductor for protection in order to improve the insulating performance and the service life of the inductor.

For the existing winding and cladding device of the inductance element, for example, the patent number is: the utility model discloses a cladding device is used in inductance component processing, the technical problem that its needs to solve is that the sticky tape in the sticky tape wheel in the cladding device needs to be changed after finishing using, current change mode generally uses the screw to carry out spacingly, often can take place the phenomenon that smooth silk card is dead, inconvenient user uses, but in actual cladding process, because only can carry out the cladding at every turn, cause cladding efficiency lower, secondly, it can only have the function of cladding the winding on inductance component surface, to how to carry the inductance component that waits to process and how to export the inductance component that the cladding is accomplished, and can not realize integrated design, still need the loading and unloading of manual inductance component, can lead to the efficiency of cladding further to drop like, and the condition of winding cladding inaccuracy appears easily.

Disclosure of Invention

The present invention has been made to solve at least one of the above-mentioned problems, and an object of the present invention is to provide a winding and wrapping apparatus and method for manufacturing an inductance element.

The invention realizes the above purpose through the following technical scheme: a winding and coating device for processing an inductance element comprises

The frame body component forms a main body supporting structure of the winding cladding device and comprises a driving frame rod and a driven frame rod which are arranged in parallel, wherein the driving frame rod and the driven frame rod are of a cross-shaped structure, the centers of the driving frame rod and the driven frame rod are connected through a center connecting rod, the outer side of the center of the driving frame rod is fixedly connected with a rotating shaft of a main body driving motor, and a main body of the main body driving motor is fixed on a peripheral device fixing frame;

the clamping assembly is used for clamping and processing and preparing the inductance element to be processed, and comprises clamping pneumatic telescopic cylinders which are respectively and symmetrically arranged at the four ends of the driving hack lever and the driven hack lever in pairs, the clamping pneumatic telescopic cylinders connected with the driving hack lever are synchronously and rotatably connected with the butt joint pneumatic telescopic cylinders which are rotatably arranged on the outer side surface of the hack lever through rotating shafts, the left end of the driving hack lever in the clockwise rotation direction and the outer sides of the two clamping pneumatic telescopic cylinders at the upper end are oppositely provided with single driving motors, and the inductance element clamped by the two clamping pneumatic telescopic cylinders at the upper end of the driving hack lever and the driven hack lever in the clockwise rotation direction is wound and processed with a winding belt held by a worker;

the gluing component is used for conducting insulating glue brushing on the inductance element clamped by the two clamping pneumatic telescopic cylinders positioned at the left side in the rotating direction and comprises a connecting seat fixed on a fixing frame of an external device and a glue brush arranged on one side edge of the connecting seat, which is close to the clamping pneumatic telescopic cylinders, wherein a glue coating pipe is arranged above the glue brush on the connecting seat, and a glue dripping nozzle is communicated with the pipe body of the glue coating pipe;

the conveying component is used for feeding the inductance element to be processed and prepared and outputting the inductance element after the processing and preparation are finished, and comprises a feeding conveying belt arranged between two clamping pneumatic telescopic cylinders positioned at the lower end of the rotating direction and a finished product output belt arranged between two clamping pneumatic telescopic cylinders positioned at the right side of the rotating direction.

As still further aspects of the invention: the central connecting rod is a hollow rod, and the ventilating pipes which are used for being communicated with the clamping pneumatic telescopic cylinders and the butt-joint pneumatic telescopic cylinders penetrate through the inner cavities of the central connecting rod.

As still further aspects of the invention: the telescopic ends of the two opposite clamping pneumatic telescopic cylinders are fixedly connected with clamping jaws, and the clamping jaws are in a cross shape.

As still further aspects of the invention: the inner side surface of the clamping jaw is connected with a plurality of groups of clamping adhesive tapes which are in sharp angles.

As still further aspects of the invention: the rotating shaft of the single driving motor and the telescopic end of the butt joint pneumatic telescopic cylinder are fixedly connected with a butt joint disc.

As still further aspects of the invention: the glue dropping nozzles are uniformly distributed on the glue coating pipe and are connected with a plurality of glue brushes, and the nozzle parts of the glue dropping nozzles are aligned with the glue brushes.

A winding and cladding device for processing an inductance element, and a preparation method of the winding and cladding device comprises the following steps:

step one, conveying an inductance element to be processed to a position between two clamping pneumatic telescopic cylinders at the lower end of a frame body assembly in a clockwise rotation direction through a feeding conveyor belt, enabling the two clamping pneumatic telescopic cylinders to clamp the inductance element and then rotate 90 degrees clockwise, enabling the other group of clamping pneumatic telescopic cylinders to rotate to the lower end at the moment, and clamping a second inductance element;

the second step, the first inductance element is rotated to the gluing component, the telescopic end of the butt joint pneumatic telescopic cylinder at the first step extends outwards to enable the two butt joint discs to be clung together, the clamping pneumatic telescopic cylinder on the inner side of the driving rack rod can be driven to synchronously rotate along with the butt joint pneumatic telescopic cylinder, further the inductance element can be driven to rotate, gluing is achieved, after the gluing is even, the telescopic end of the butt joint pneumatic telescopic cylinder at the first step is contracted inwards to enable the two butt joint discs to be separated, and the butt joint discs are further rotated clockwise for 90 degrees;

the third step, the first inductance element is rotated to the winding position of the upper end, the telescopic end of the butt joint pneumatic telescopic cylinder at the position extends outwards to enable the two butt joint discs to be clung together, the clamping pneumatic telescopic cylinder on the inner side of the driving rack rod can be driven to synchronously rotate along with the butt joint pneumatic telescopic cylinder, further the inductance element can be driven to rotate, a worker places one end of the fixed-length winding belt on the surface of the inductance element, the winding belt is wound on the inductance, winding preparation of the insulating outer layer is completed, at the moment, the telescopic end of the butt joint pneumatic telescopic cylinder at the position is contracted inwards to enable the two butt joint discs to be separated, and the butt joint discs are further rotated clockwise for 90 degrees;

and fourthly, the first inductance element is rotated to the right end, the two clamping pneumatic telescopic cylinders put down the inductance element and drop onto a finished product output belt to be output, and then the operations of clamping, feeding, brushing, winding and loosening the inductance element can be completed.

The beneficial effects of the invention are as follows: through setting up initiative hack lever and the driven hack lever that is the cross, can drive inductance element and rotate 90 at every turn, and carry out centre gripping material loading in proper order, brush glue, wind a roll and loosen the clamp blowing operation, realize the processing of the flow of winding preparation to inductance element, in addition, when carrying out the operation of corresponding step to one of them inductance element, the device can also drive other inductance element and carry out the operation of other different steps in step, can improve the operating efficiency, and can coil the winding again after the online brush glue, ensure evenly to brush insulating glue on inductance element, and then improve inductance element's insulativity.

Drawings

FIG. 1 is a schematic diagram of the overall structure of the present invention;

FIG. 2 is a schematic view of a clamping assembly according to the present invention;

FIG. 3 is a schematic view of a clamping pneumatic telescopic cylinder structure according to the present invention;

fig. 4 is a schematic structural diagram of the glue brushing assembly of the present invention.

In the figure: 1. the automatic glue dispenser comprises a driving hack lever, 2, a driven hack lever, 3, a central connecting rod, 4, a main body driving motor, 5, a clamping pneumatic telescopic cylinder, 6, a single driving motor, 7, a feeding transmission belt, 8, a finished product output belt, 9, clamping jaws, 10, a clamping adhesive tape, 11, a connecting seat, 12, a glue coating pipe, 13, a glue brush, 14, a glue dropping nozzle, 15, a butt joint pneumatic telescopic cylinder, 16 and a butt joint disc.

Description of the embodiments

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Examples

As shown in fig. 1 to 4, a winding and cladding apparatus for processing an inductance element includes

The frame body component forms a main body supporting structure of the winding cladding device and comprises a driving frame rod 1 and a driven frame rod 2 which are arranged in parallel, wherein the driving frame rod 1 and the driven frame rod 2 are of a cross-shaped structure, the centers of the driving frame rod 1 and the driven frame rod 2 are connected through a center connecting rod 3, the outer side of the center of the driving frame rod 1 is fixedly connected with a rotating shaft of a main body driving motor 4, and a machine body of the main body driving motor 4 is fixed on a peripheral device fixing frame;

the clamping assembly is used for clamping and processing and preparing an inductance element to be processed, and comprises clamping pneumatic telescopic cylinders 5 which are respectively and symmetrically arranged at four ends of a driving hack lever 1 and a driven hack lever 2 in pairs, wherein the clamping pneumatic telescopic cylinders 5 connected with the driving hack lever 1 are synchronously and rotatably connected with a butt joint pneumatic telescopic cylinder 15 which is rotatably arranged on the outer side surface of the hack lever through a rotating shaft, a single driving motor 6 is arranged at the left end of the driving hack lever 1 in the clockwise rotation direction and at the outer sides of the two clamping pneumatic telescopic cylinders 5 at the upper end of the driving hack lever 1 in the clockwise rotation direction in an aligned manner, and the inductance element clamped by the two clamping pneumatic telescopic cylinders 5 at the upper ends of the driving hack lever 1 and the driven hack lever 2 in the clockwise rotation direction and a coiled belt held by a worker are wound;

the gluing component is used for conducting insulating glue brushing on the inductance element clamped by the two clamping pneumatic telescopic cylinders 5 positioned at the left side in the rotating direction and comprises a connecting seat 11 fixed on a fixing frame of an external device and a glue brush 13 arranged on one side edge of the connecting seat 11, which is close to the clamping pneumatic telescopic cylinders 5, wherein a glue coating pipe 12 is arranged above the glue brush 13 by the connecting seat 11, and a glue dripping nozzle 14 is communicated with the pipe body of the glue coating pipe 12;

the conveying component is used for feeding the inductance element to be processed and prepared and outputting the inductance element after the processing and preparation are finished, and comprises a feeding conveying belt 7 arranged between the two clamping pneumatic telescopic cylinders 5 positioned at the lower end of the rotating direction and a finished product output belt 8 arranged between the two clamping pneumatic telescopic cylinders 5 positioned at the right side of the rotating direction.

Examples

In addition to all the technical features in the first embodiment, the present embodiment further includes:

the center connecting rod 3 is hollow rod, and is used for all passing the inside cavity of center connecting rod 3 with the pneumatic flexible jar 5 of each centre gripping and the pneumatic flexible jar 15 of butt joint are linked together to ensure that when rotating the body subassembly and carrying out a series of centre gripping material loading, brush glue, winding and loose clamp blowing to inductance element, can not cause a plurality of pipelines winding that pneumatic flexible jar linked together.

The telescopic ends of the two opposite clamping pneumatic telescopic cylinders 5 are fixedly connected with clamping jaws 9, and the clamping jaws 9 are in a cross shape so as to firmly clamp the two ends of the inductance element, and then the two ends of the inductance element cannot fall off in the rotating process of the frame body assembly.

The inner side of the clamping jaw 9 is connected with a plurality of groups of clamping adhesive tapes 10 which are in sharp angles, so that flexible clamping can be formed on the inductance element, and clamping marks or damage can not be caused on two ends of the inductance element.

Examples

In addition to all the technical features in the first embodiment, the present embodiment further includes:

the rotation shaft of the single driving motor 6 and the telescopic end of the butt joint pneumatic telescopic cylinder 15 are fixedly connected with the butt joint disc 16, when the telescopic end of the butt joint pneumatic telescopic cylinder 15 extends outwards to enable the two butt joint discs 16 to be clung together, the clamping pneumatic telescopic cylinder 5 on the inner side of the driving rack bar 1 can be driven to synchronously rotate along with the butt joint pneumatic telescopic cylinder 15, and further the inductor element can be driven to rotate, so that the winding operation of gluing and winding can be realized.

The glue dripping spray heads 14 are uniformly distributed on the glue coating pipe 12 and are connected with a plurality of glue brushes 13, and the nozzle parts of the glue dripping spray heads 14 are aligned with the glue brushes 13 so as to be capable of continuously spraying insulating glue to the glue brushes 13, and then when the clamping pneumatic telescopic cylinder 5 drives the clamped inductance element to rotate, the insulating glue can be uniformly coated on the inductance element, and the insulativity of the inductance element is improved.

Examples

In addition to all the technical features in the first embodiment, the present embodiment further includes:

a winding and cladding device for processing an inductance element, and a preparation method of the winding and cladding device comprises the following steps:

step one, conveying an inductance element to be processed to a position between two clamping pneumatic telescopic cylinders 5 at the lower end of a frame body assembly in a clockwise rotation direction through a feeding conveyor belt 7, enabling the two clamping pneumatic telescopic cylinders 5 to rotate 90 degrees clockwise after clamping the inductance element, and enabling the other group of clamping pneumatic telescopic cylinders 5 to rotate to the lower end at the moment to clamp a second inductance element;

the second step, the first inductance element is rotated to the gluing component, the telescopic end of the butt joint pneumatic telescopic cylinder 15 at the position extends outwards to enable the two butt joint discs 16 to be clung together, then the clamping pneumatic telescopic cylinder 5 on the inner side of the driving rack bar 1 can be driven to synchronously rotate along with the butt joint pneumatic telescopic cylinder 15, further the inductance element can be driven to rotate, so that gluing is achieved, after the gluing is even, the telescopic end of the butt joint pneumatic telescopic cylinder 15 at the position is contracted inwards at the moment to enable the two butt joint discs 16 to be separated, and the butt joint discs are further rotated clockwise by 90 degrees;

step three, the first inductance element is rotated to the winding position of the upper end, the telescopic end of the butt joint pneumatic telescopic cylinder 15 at the position extends outwards to enable the two butt joint discs 16 to be clung together, then the clamping pneumatic telescopic cylinder 5 on the inner side of the driving rack rod 1 can be driven to synchronously rotate along with the butt joint pneumatic telescopic cylinder 15, further the inductance element can be driven to rotate, a worker can place one end of a fixed-length winding belt on the surface of the inductance element, the winding belt is wound on the inductance, winding preparation of an insulating outer layer is completed, at the moment, the telescopic end of the butt joint pneumatic telescopic cylinder 15 at the position is contracted inwards to enable the two butt joint discs 16 to be separated, and the butt joint discs are further rotated clockwise by 90 degrees;

and fourthly, the first inductance element is rotated to the right end, the two clamping pneumatic telescopic cylinders 5 put down the inductance element and drop on the finished product output belt 8 to be output, and then the operations of clamping, feeding, brushing glue, winding and loosening the clamping and discharging of the inductance element can be completed.

Working principle: the inductive element to be processed is conveyed to the frame body assembly through the feeding conveyor belt 7 to be clamped between the two clamping pneumatic telescopic cylinders 5 at the lower end of the clockwise rotating direction, the inductive element is rotated to the gluing assembly, the telescopic ends of the abutting pneumatic telescopic cylinders 15 at the positions extend outwards to enable the two abutting discs 16 to be tightly attached together, the clamping pneumatic telescopic cylinders 5 at the inner sides of the driving hack levers 1 can be driven to synchronously rotate along with the abutting pneumatic telescopic cylinders 15, further, the inductive element can be driven to rotate to achieve gluing, the inductive element is rotated to the winding position at the upper end, the telescopic ends of the abutting pneumatic telescopic cylinders 15 at the positions extend outwards to enable the two abutting discs 16 to be tightly attached together, the clamping pneumatic telescopic cylinders 5 at the inner sides of the driving hack levers 1 can be driven to synchronously rotate along with the abutting pneumatic telescopic cylinders 15, further, workers can be driven to rotate the inductive element, one ends of coiled tapes with fixed lengths are placed on the surfaces of the inductive element, the coiled tapes are enabled to be wound on the inductors, and winding preparation of insulating outer layers is completed; the inductive element is rotated to the right end, and the two clamping pneumatic telescopic cylinders 5 put down the inductive element and drop onto the finished product output belt 8 for output.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (7)

1. Winding cladding device is used in inductance component processing, its characterized in that: comprising

The frame body component forms a main body supporting structure of the winding cladding device and comprises a driving frame rod (1) and a driven frame rod (2) which are arranged in parallel, wherein the driving frame rod (1) and the driven frame rod (2) are of a cross-shaped structure, the centers of the driving frame rod (1) and the driven frame rod (2) are connected through a center connecting rod (3), the outer side of the center of the driving frame rod (1) is fixedly connected with a rotating shaft of a main body driving motor (4), and a machine body of the main body driving motor (4) is fixed on a peripheral device fixing frame;

the clamping assembly is used for clamping and processing and preparing an inductance element to be processed, and comprises clamping pneumatic telescopic cylinders (5) which are respectively connected to four ends of a driving hack lever (1) and a driven hack lever (2) in a rotating mode, the clamping pneumatic telescopic cylinders (5) are symmetrically arranged in pairs, the clamping pneumatic telescopic cylinders (5) connected with the driving hack lever (1) are synchronously connected with a butt joint pneumatic telescopic cylinder (15) which is rotationally arranged on the outer side face of the hack lever through a rotating shaft, a monomer driving motor (6) is arranged at the left end of the driving hack lever (1) in a clockwise rotating direction and outside of the two clamping pneumatic telescopic cylinders (5) at the upper end of the driving hack lever, and the inductance element clamped by the two clamping pneumatic telescopic cylinders (5) at the upper end of the driving hack lever (1) in the clockwise rotating direction is wound with a coiled tape held by a worker;

the gluing component is used for conducting insulating glue brushing on the inductance element clamped by the two clamping pneumatic telescopic cylinders (5) positioned at the left side in the rotating direction and comprises a connecting seat (11) fixed on a fixing frame of an external device and a glue brush (13) arranged on one side edge, close to the clamping pneumatic telescopic cylinders (5), of the connecting seat (11), a glue coating pipe (12) is arranged above the glue brush (13), and a glue dripping nozzle (14) is communicated with the pipe body of the glue coating pipe (12);

the conveying component is used for feeding the inductance element to be processed and prepared and outputting the inductance element after the processing and preparation are finished, and comprises a feeding conveying belt (7) arranged between the two clamping pneumatic telescopic cylinders (5) positioned at the lower end of the rotating direction and a finished product output belt (8) arranged between the two clamping pneumatic telescopic cylinders (5) positioned at the right side of the rotating direction.

2. The winding and cladding apparatus for processing an inductance component according to claim 1, wherein: the central connecting rod (3) is a hollow rod, and the ventilation pipelines which are used for being communicated with the clamping pneumatic telescopic cylinders (5) and the butt joint pneumatic telescopic cylinders (15) penetrate through the inner cavity of the central connecting rod (3).

3. The winding and cladding apparatus for processing an inductance component according to claim 1, wherein: the telescopic ends of the two opposite clamping pneumatic telescopic cylinders (5) are fixedly connected with clamping jaws (9), and the clamping jaws (9) are in a cross shape.

4. A winding and cladding apparatus for processing an inductance component according to claim 3, wherein: the inner side surface of the clamping jaw (9) is connected with a plurality of groups of sharp-angle clamping adhesive tapes (10).

5. The winding and cladding apparatus for processing an inductance component according to claim 1, wherein: the rotating shaft of the single driving motor (6) and the telescopic end of the butt joint pneumatic telescopic cylinder (15) are fixedly connected with a butt joint disc (16).

6. The winding and cladding apparatus for processing an inductance component according to claim 1, wherein: the glue dropping nozzles (14) are uniformly distributed on the glue coating pipe (12) and are connected with a plurality of glue brushes (13), and the nozzle parts of the glue dropping nozzles (14) are aligned with the glue brushes (13).

7. A method for manufacturing a winding and cladding device for processing an inductance component according to claim 1, characterized in that: the preparation method comprises the following steps:

step one, conveying an inductance element to be processed to a position between two clamping pneumatic telescopic cylinders (5) at the lower end of a frame body assembly in a clockwise rotation direction through a feeding conveyor belt (7), enabling the two clamping pneumatic telescopic cylinders (5) to clamp the inductance element and then rotate 90 degrees clockwise, and enabling the other group of clamping pneumatic telescopic cylinders (5) to rotate to the lower end at the moment to clamp a second inductance element;

the second step, the first inductance element is rotated to the gluing component, the telescopic end of the butt joint pneumatic telescopic cylinder (15) at the gluing component stretches outwards to enable the two butt joint discs (16) to be clung together, then the clamping pneumatic telescopic cylinder (5) on the inner side of the driving rack rod (1) can be driven to synchronously rotate along with the butt joint pneumatic telescopic cylinder (15), further the inductance element is driven to rotate, gluing is achieved, and after the gluing is even, the telescopic end of the butt joint pneumatic telescopic cylinder (15) at the gluing component is contracted inwards to enable the two butt joint discs (16) to be separated, and the butt joint discs are further rotated clockwise for 90 degrees;

the third step, the first inductance element is rotated to the winding position of the upper end, the telescopic end of the butt joint pneumatic telescopic cylinder (15) at the position stretches outwards to enable the two butt joint discs (16) to be clung together, then the clamping pneumatic telescopic cylinder (5) on the inner side of the driving rack rod (1) can be driven to synchronously rotate along with the butt joint pneumatic telescopic cylinder (15), further the inductance element is driven to rotate, a worker places one end of the fixed-length coiled tape on the surface of the inductance element, the coiled tape is wound on the inductance, winding preparation of the insulating outer layer is completed, at the moment, the telescopic end of the butt joint pneumatic telescopic cylinder (15) at the position inwards contracts to enable the two butt joint discs (16) to be separated, and the two butt joint discs further rotate clockwise for 90 degrees;

and fourthly, the first inductance element is rotated to the right end, the two clamping pneumatic telescopic cylinders (5) put down the inductance element and drop on the finished product output belt (8) to be output, and then the operations of clamping, feeding, brushing, winding and loosening the inductance element are completed.

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