CN221175970U - Wire twisting mechanism for inductor - Google Patents

Abstract

The utility model relates to the technical field of inductor processing equipment, and particularly discloses a stranded wire mechanism for an inductor, which comprises a base, wherein a displacement assembly, a stranded wire assembly and a positioning assembly are arranged on the base, the displacement assembly comprises a front-back displacement module, a front-back displacement sliding seat and a front-back displacement motor, the front-back displacement module is arranged at the upper end of the base, the stranded wire assembly comprises a first stranded wire clamp, a second stranded wire clamp, a clamping cylinder and a rotating motor, the first stranded wire clamp and the second stranded wire clamp are both connected with the clamping cylinder, a movable rod of the rotating motor is connected with the first stranded wire clamp and the second stranded wire clamp and can drive the first stranded wire clamp and the second stranded wire clamp to rotate, and the positioning assembly comprises a positioning frame and an up-down displacement cylinder. The utility model has high automation degree, and the copper wires at the left end and the right end of the inductor can be positioned through the wire twisting mechanism, so that the copper wires enter the V-shaped groove of the inductor, the accurate position is ensured, the manual work is reduced, the processing steps are saved, and the processing efficiency is improved.

Description

Wire twisting mechanism for inductor

Technical Field

The utility model relates to the technical field of inductor processing equipment, in particular to a wire twisting mechanism for an inductor.

Background

The chip inductor, also called power inductor, high current inductor and surface mount high power inductor, has the characteristics of miniaturization, high quality, high energy storage, low resistance and the like, and the power chip inductor is divided into a magnetic shield and a magnetic shield-free magnetic shield, mainly comprises a magnetic core and a copper wire, and mainly plays roles in filtering and oscillation in a circuit. The patch inductor needs to sequentially pass through the following procedures in the manufacturing process: the winding is used for winding the copper wire on the patch inductor; soldering tin, which is used for welding the copper wire end head on the inductor; cleaning and drying; and the package testing and appearance checking are used for detecting the appearance and packaging the package.

The current inductance is when fixing the V type groove at the inductor with copper line both ends, and most adopt manual operation, fix the inductor on fixed tool, is cliied the copper line by the finger again, fixes it in the V type inslot of inductor, and this mode of operation degree of automation is lower, and required cost of labor and intensity of labour are great, and the operation is comparatively loaded down with trivial details, and work efficiency is lower, can't satisfy industry demand.

Disclosure of utility model

Aiming at the defects in the prior art, the utility model provides the wire twisting mechanism for the inductor, which has the advantages of simple structure, high automation degree and high automation degree, and can position copper wires at the left end and the right end of the inductor through the wire twisting mechanism, so that the copper wires enter the V-shaped groove of the inductor, the position is ensured to be accurate, the labor is reduced, the processing steps are saved, and the processing efficiency is improved.

In order to achieve the above purpose, the technical scheme adopted by the utility model is as follows:

A stranded conductor mechanism for inductor, including the frame, be equipped with displacement subassembly on the frame, displacement subassembly around displacement subassembly includes the back-and-forth displacement module, back-and-forth displacement slide and back-and-forth displacement motor, back-and-forth displacement module sets up in the frame upper end, back-and-forth displacement slide sets up on the back-and-forth displacement module, and the accessible back-and-forth displacement motor drive is along back-and-forth displacement module activity, the stranded conductor subassembly passes through the mounting bracket to be installed on the back-and-forth displacement module, the stranded conductor subassembly includes first stranded conductor clamp, the second stranded conductor clamp, clamping cylinder and rotating electrical machines, the mounting bracket passes through back-and-forth displacement slide and installs on the back-and-forth displacement module, first stranded conductor clamp and second stranded conductor clamp all are connected with the clamping cylinder, and can be driven to open and shut by clamping cylinder drive the movable rod of rotating electrical machines and first stranded conductor clamp and second stranded conductor clamp, the positioning assembly includes locating rack and upper and lower displacement cylinder, the locating rack is arranged in between first stranded conductor clamp and the second stranded conductor clamp, and can be moved from top to bottom by upper and lower displacement cylinder drive.

In the above description, preferably, the movable rod of the front-back displacement motor is connected with a transmission gear, the front-back displacement module is provided with a screw rod, the screw rod is connected with the front-back displacement sliding seat, the screw rod is provided with a driven gear, and the transmission gear is connected with the driven gear through a belt.

In the above description, preferably, the front end of the mounting frame is provided with a positioning plate, the first twisted wire clip and the second twisted wire clip are arranged at the front end of the positioning plate, and the rotating motor is arranged at the rear end of the positioning plate.

In the above description, preferably, the first twisted wire clip and the second twisted wire clip each include a fixing arm and a clamping arm, the clamping arm is disposed at an upper end of the fixing arm and connected to the clamping cylinder, and the fixing arm is connected to a transmission shaft of the rotating electrical machine.

In the above description, preferably, the positioning plate is provided with a yielding opening, and one end of the fixing arm passes through the yielding opening and is connected with the rotating motor.

In the above description, preferably, the clamping cylinder is disposed at the rear end of the mounting frame, the rotating motor is provided with a connecting arm, the front end of the connecting arm passes through the rotating motor to be connected with the clamping arm, and the rear end of the connecting arm passes through the rotating motor to extend to the clamping cylinder.

In the above description, preferably, the bottom of the mounting frame is provided with a photoelectric switch, and the rear end of the connecting arm is provided with an induction disc corresponding to the position of the photoelectric switch.

In the above description, preferably, the upper end of the positioning plate is provided with a mounting plate, the telescopic rod of the vertical displacement cylinder is downward arranged on the mounting plate, the vertical displacement cylinder is provided with a vertical displacement guide rail, the positioning frame is arranged on the vertical displacement guide rail through a vertical displacement slide seat, and the telescopic rod of the vertical driving cylinder is connected with the vertical displacement slide seat through a connecting plate and can drive the vertical displacement slide seat to move along the vertical displacement guide rail.

In the above description, preferably, the positioning frame includes a limiting plate and two extending plates respectively disposed on two sides of the limiting plate, where the two extending plates are arranged in a splayed shape.

The beneficial effects of the utility model are as follows: the displacement assembly and the stranded wire assembly are arranged, the position of the adaptive electric sensor can be automatically adjusted through the displacement mechanism, the stranded wire assembly is used for stranding the electric sensor, the structure is simple, the automation degree is high, and the labor cost and the labor intensity are effectively reduced; through setting up locating rack and displacement cylinder from top to bottom, the locating rack sets up between first hank fastener and second hank fastener to can be by the activity from top to bottom of displacement cylinder drive, when the inductor carried stranded conductor operating position, the position of accessible locating rack location inductor ensures that the position is accurate, after having fixed a position the inductor position, has displacement cylinder drive from top to bottom to move up, stranded conductor subassembly begins stranded conductor work, degree of automation is high, can fix a position the inductor through stranded conductor mechanism and control both ends copper line, make the copper line get into the V type inslot of inductor, ensure that the position is accurate, reduce manual work, save processing step, raise the machining efficiency.

Drawings

Fig. 1: is a schematic structural diagram of an embodiment of the utility model;

Fig. 2: an enlarged schematic view of the portion a in fig. 1 is shown in accordance with an embodiment of the present utility model;

fig. 3: a schematic side view structure of the embodiment of the utility model;

fig. 4: an enlarged schematic view of part B in fig. 3 is shown in accordance with an embodiment of the present utility model;

The attached drawings are used for identifying and describing: the device comprises a 10-base, a 20-front-back displacement module, a 21-front-back displacement slide seat, a 22-front-back displacement motor, a 30-mounting frame, a 31-clamping cylinder, a 32-photoelectric switch, a 33-connecting arm, a 34-first wire clamp, a 35-second wire clamp, a 36-rotating motor, a 37-fixed arm, a 38-clamping arm, a 39-sensing disc, a 40-positioning frame, a 41-up-down displacement cylinder, a 42-mounting plate, a 43-up-down displacement guide rail, a 44-up-down displacement slide seat, a 45-connecting plate, a 46-extending plate, a 47-limiting plate, a 48-positioning plate and a 481-yielding opening.

Detailed Description

For a clearer description of the structural features, technical means, and specific objects and functions achieved by the present utility model, the present utility model will be further described in detail with reference to the accompanying drawings and specific embodiments:

This embodiment: as shown in fig. 1-4, the wire twisting mechanism for the inductor comprises a stand 10, wherein a displacement assembly, a wire twisting assembly and a positioning assembly are arranged on the stand 10;

The displacement assembly comprises a front-back displacement module 20, a front-back displacement sliding seat 21 and a front-back displacement motor 22, wherein the front-back displacement module 20 is arranged at the upper end of the machine base 10, the front-back displacement sliding seat 21 is arranged on the front-back displacement module 20, a movable rod of the front-back displacement motor 22 is connected with a transmission gear, a screw rod is arranged on the front-back displacement module 20, the screw rod is connected with the front-back displacement sliding seat 21, a driven gear is arranged on the screw rod, the transmission gear is in transmission connection with the driven gear through a belt, and the front-back displacement module 20 can be driven to move through the front-back displacement motor 22;

The wire stranding assembly is arranged on the front-back displacement module 20 through a mounting frame 30, the wire stranding assembly comprises a first wire stranding clamp 34, a second wire stranding clamp 35, a clamping cylinder 31 and a rotating motor 36, the mounting frame 30 is arranged on the front-back displacement module 20 through a front-back displacement sliding seat 21, the first wire stranding clamp 34 and the second wire stranding clamp 35 are both connected with the clamping cylinder 31 and can be driven to open and close by the clamping cylinder 31, and a movable rod of the rotating motor 36 is connected with the first wire stranding clamp 34 and the second wire stranding clamp 35 and can drive the first wire stranding clamp 34 and the second wire stranding clamp 35 to rotate;

The positioning assembly comprises a positioning frame 40 and an up-down displacement cylinder 41, wherein the positioning frame 40 is arranged between a first stranding clamp 34 and a second stranding clamp 35 and can be driven to move up and down by the up-down displacement cylinder 41, the front end of the mounting frame 30 is provided with a positioning plate 48, the upper end of the positioning plate 48 is provided with a mounting plate 42, the telescopic rod of the up-down displacement cylinder 41 is downwards arranged on the mounting plate 42, the up-down displacement cylinder 41 is provided with an up-down displacement guide rail 43, the positioning frame 40 is arranged on the up-down displacement guide rail 43 through an up-down displacement slide seat 44, the telescopic rod of the up-down driving cylinder is connected with the up-down displacement slide seat 44 through a connecting plate 45 and can drive the up-down displacement slide seat 44 to move along the up-down displacement guide rail 43, the positioning frame 40 comprises a limiting plate 47 and two extending plates 46 respectively arranged at two sides of the limiting plate 47, the two extending plates 46 are arranged in a splayed shape, the first stranding clamp 34 and the second stranding clamp 35 are arranged at the front end of the positioning plate 48, the rotating motor 36 is arranged at the rear end of the positioning plate 48, when the inductor is conveyed to the stranded wire working position, the positioning frame 40 can be used for positioning the inductor, the position of a copper wire is ensured to be accurate, after the inductor is positioned, the upper and lower displacement cylinders 41 are used for driving the copper wire to move upwards, the stranded wire component starts to stranded wire work, the condition that the two ends of the copper wire are different in length is avoided, the processing steps are saved, is improved in processing efficiency, the first stranded wire clamp 34 and the second stranded wire clamp 35 both comprise a fixed arm 37 and a clamping arm 38, the clamping arm 38 is arranged at the upper end of the fixed arm 37 and connected with the clamping cylinder 31, the fixed arm 37 is connected with a transmission shaft of the rotating motor 36, the positioning plate 48 is provided with a yielding opening 481, one end of the fixed arm 37 passes through the yielding opening 481 and is connected with the rotating motor 36, the clamping cylinder 31 is arranged at the rear end of the mounting frame 30, the rotating motor 36 is provided with a connecting arm 33, the front end of the connecting arm 33 passes through the rotating motor 36 to be connected with the clamping arm 38, the rear end of the connecting arm 33 passes through the rotating motor 36 to extend to the clamping cylinder 31, the bottom of the mounting frame 30 is provided with the photoelectric switch 32, the rear end of the connecting arm 33 is provided with the sensing disc 39 corresponding to the position of the photoelectric switch 32 and used for sensing whether the clamping angles of the first wire clamp 34 and the second wire clamp 35 are aligned or not, and the rotating motor 36 can control the adjustment angles of the first wire clamp 34 and the second wire clamp 35.

The foregoing description is only a preferred embodiment of the present utility model, and is not intended to limit the present utility model, so any modifications, equivalents, improvements, etc. made to the above embodiment according to the technical scheme of the present utility model still fall within the scope of the technical scheme of the present utility model.

Claims (9)

1. A stranded conductor mechanism for inductor, including frame, its characterized in that: the machine seat is provided with a displacement assembly, a stranded wire assembly and a positioning assembly, the displacement assembly comprises a front-back displacement module, a front-back displacement sliding seat and a front-back displacement motor, the front-back displacement module is arranged at the upper end of the machine seat, the front-back displacement sliding seat is arranged on the front-back displacement module and can be driven by the front-back displacement motor to move along the front-back displacement module, the stranded wire assembly is installed on the front-back displacement module through an installation frame and comprises a first stranded wire clamp, a second stranded wire clamp, a clamping cylinder and a rotating motor, the installation frame is installed on the front-back displacement module through the front-back displacement sliding seat, the first stranded wire clamp and the second stranded wire clamp are connected with the clamping cylinder and can be driven by the clamping cylinder to open and close, a movable rod of the rotating motor is connected with the first stranded wire clamp and the second stranded wire clamp and can drive the first stranded wire clamp and the second stranded wire clamp to rotate, and the positioning assembly comprises a positioning frame and an up-down displacement cylinder and a positioning frame arranged between the first stranded wire clamp and the second stranded wire clamp and can be driven by the up-down displacement cylinder to move up and down.

2. The wire stranding mechanism for an inductor of claim 1 wherein: the movable rod of the front-back displacement motor is connected with a transmission gear, the front-back displacement module is provided with a screw rod, the screw rod is connected with the front-back displacement sliding seat, the screw rod is provided with a driven gear, and the transmission gear is connected with the driven gear through belt transmission.

3. The wire stranding mechanism for an inductor of claim 1 wherein: the front end of mounting bracket is equipped with the locating plate, and first strand clamp and second strand clamp set up in the front end of locating plate, and the rotating electrical machines sets up in the rear end of locating plate.

4. A wire stranding mechanism for an inductor according to claim 3, wherein: the first wire clamp and the second wire clamp comprise a fixed arm and a clamping arm, the clamping arm is arranged at the upper end of the fixed arm and is connected with the clamping cylinder, and the fixed arm is connected with a transmission shaft of the rotating motor.

5. The wire stranding mechanism for an inductor of claim 4 wherein: the locating plate is provided with a yielding opening, and one end of the fixed arm penetrates through the yielding opening to be connected with the rotating motor.

6. The wire stranding mechanism for an inductor of claim 4 wherein: the clamping cylinder is arranged at the rear end of the mounting frame, the rotating motor is provided with a connecting arm, the front end of the connecting arm penetrates through the rotating motor to be connected with the clamping arm, and the rear end of the connecting arm penetrates through the rotating motor to extend to the clamping cylinder.

7. The wire stranding mechanism for an inductor of claim 6 wherein: the bottom of mounting bracket is equipped with photoelectric switch, and the rear end of linking arm is equipped with the response disc that corresponds with photoelectric switch position.

8. The wire stranding mechanism for an inductor of claim 1 wherein: the upper end of locating plate is equipped with the mounting panel, and the setting of upper and lower displacement cylinder telescopic link down is on the mounting panel, and is equipped with upper and lower displacement guide rail on the upper and lower displacement cylinder, and the locating rack passes through upper and lower displacement slide and sets up on upper and lower displacement guide rail, and the telescopic link of upper and lower drive cylinder passes through the connecting plate and is connected with upper and lower displacement slide to can drive upper and lower displacement slide along upper and lower displacement guide rail activity.

9. The wire stranding mechanism for an inductor of claim 1 wherein: the locating frame comprises a limiting plate and two extending plates which are respectively arranged at two sides of the limiting plate, and the two extending plates are arranged in a splayed shape.