CN220604494U - Adjustable coil winding machine - Google Patents

Abstract

The utility model provides an adjustable coil winding machine, which comprises a frame, wherein a paying-off assembly is arranged on the frame; the rotating seat is rotatably arranged on the frame and is provided with two cantilever shafts; the die is connected with the cantilever shaft and provided with an annular winding groove; and the wire arranging assembly is used for enabling the wires to be uniformly wound in the annular wire winding groove. The adjustable coil winding machine provided by the utility model is provided with the rack, and a plurality of bobbins can be stored through the paying-off assembly on the rack, so that the wires are supplied uninterruptedly; the rotating seat is arranged, and the two cantilever shafts on the rotating seat can be driven to rotate by the driving assembly on the frame; the die is arranged and can be connected to the two cantilever shafts, and the wires are wound into the annular wire winding grooves on the die; the wire arranging assembly is arranged, the wires led out from the wire arranging assembly can be driven to reciprocate along the length direction of the cantilever shaft, so that the wires are uniformly wound in the annular winding groove, the wound coil is uniform in electromagnetic induction, and meanwhile, breakage of the wires is avoided, so that the practicality is good.

Description

Adjustable coil winding machine

Technical Field

The utility model belongs to the technical field of auxiliary processing of coil windings, and particularly relates to an adjustable coil winding machine.

Background

Coils are generally referred to as windings of wire in the form of loops, the most common coil applications being: motors, inductors, transformers, loop antennas, etc. The coil in the circuit is referred to as an inductor. The wires are wound one by one, the wires are mutually insulated, and the insulating tube can be hollow or can comprise an iron core or a magnetic powder core, namely an inductor. The inductance can be divided into a fixed inductance and a variable inductance, and the fixed inductance coil is called an inductance or a coil for short. The reel is a cylindrical tool for storing the wire.

In the prior art, a winding machine is generally adopted to carry out auxiliary winding when a coil is wound, a mold is firstly arranged on a rotary chuck when the winding machine carries out winding, one end of a wire on a winding drum is connected to the mold, and the mold is driven to rotate through the rotation of the rotary chuck, so that the wire is wound on the mold one by one; however, when the wire is wound on the surface of the die, the wire is wound unevenly, so that the electromagnetic induction of the coil is uneven, the wire is easy to break, and the practicability is poor.

Disclosure of Invention

The embodiment of the utility model provides an adjustable coil winding machine, which aims to realize uniform winding of a wire on a die.

In order to achieve the above purpose, the utility model adopts the following technical scheme: there is provided an adjustable coil winding machine comprising:

the rack is provided with a paying-off assembly for winding the wire;

the rotating seat is rotatably arranged on the frame and connected with the driving assembly arranged on the frame, the rotating axis of the rotating seat is arranged along the horizontal direction, and the rotating seat is provided with two cantilever shafts extending along the horizontal direction, and the two cantilever shafts are annularly arranged at intervals around the rotating axis of the rotating seat;

the mould is connected with the two cantilever shafts and is provided with an annular winding groove; and

and the wire arranging assembly is arranged between the wire arranging assembly and the die and is used for driving the wires led out from the wire arranging assembly to reciprocate along the length direction of the cantilever shaft so as to enable the wires to be uniformly wound in the annular winding groove.

In one possible implementation, the pay-off assembly includes a post, a rotating lever, and a locking member; the two upright posts are arranged at intervals along the extending direction of the cantilever shaft; one end of the rotating rod is rotationally connected with one of the upright posts, the rotating axis is arranged along the vertical direction, and the rotating rod is used for rotationally connecting a wire winding drum for a wire; the locking piece is arranged on the other upright post and is provided with an embedded groove for the other end of the rotating rod to be put in;

the two upright posts are respectively provided with an extension section, and each extension section vertically extends upwards.

In one possible implementation, the wire arranging assembly comprises a guide rod, a guide wheel and a wire arranging structure; the guide rod is horizontally arranged above the rotating rod, and two ends of the guide rod are respectively arranged on the two extension sections; the guide wheel is arranged on the guide rod in a sliding manner and used for guiding the wire transmitted by the paying-off assembly; the wire arranging structure is arranged on the guide rod in a sliding way, is arranged at intervals with the guide wheel and is used for uniformly guiding the wires;

the guide rod is provided with a sliding rail for the wire arranging structure to slide.

In one possible implementation manner, the wire arranging structure comprises a wire arranging slide block, a wire arranging rod, a wire arranging ring and a telescopic unit; the wire arranging slide block is arranged on the slide rail in a sliding manner; the wire arranging rod is provided with a fixed end and a wire arranging end, the fixed end of the wire arranging rod is fixedly arranged on the wire arranging sliding block, and the wire arranging end of the wire arranging rod extends out to the side surface of the rotating axis of the die and is arranged at intervals with the die; the wire arranging ring is arranged on the wire arranging end of the wire arranging rod and is provided with a conical through hole, and the conical through hole is used for the wires to pass through; the fixed end of the telescopic unit is fixedly arranged at the extending end of one of the upright posts, and the telescopic end of the telescopic unit is connected to the wire arranging slide block and used for driving the wire arranging slide block to slide on the slide rail.

In one possible implementation, the telescopic unit is an electric push rod.

In one possible implementation, the guide wheel includes a sliding axle and a rotating wheel; the sliding wheel shaft is arranged on the sliding rail in a sliding way, and the rotating wheel is arranged on the sliding wheel shaft in a rotating way.

In one possible implementation, the sliding axle is a ball bearing.

In one possible implementation, the rotating wheel is provided with a V-shaped groove.

In the implementation mode, compared with the prior art, the machine frame is arranged, and a plurality of bobbins can be stored through the paying-off assembly on the machine frame, so that the wires are supplied uninterruptedly; the rotating seat is rotatably arranged on the frame, and the two cantilever shafts on the rotating seat can be driven to rotate by the driving component on the frame; the die is arranged and can be connected to the two cantilever shafts, and the wires are wound into the annular wire winding grooves on the die; the wire arranging assembly is arranged, the wires led out from the wire arranging assembly can be driven to reciprocate along the length direction of the cantilever shaft, so that the wires are uniformly wound in the annular wire winding groove, the wound coils can be uniformly subjected to electromagnetic induction, and meanwhile, breakage of the wires is avoided, so that the wire arranging assembly is good in practicality.

Drawings

Fig. 1 is a schematic structural diagram of an adjustable coil winding machine according to an embodiment of the present utility model;

fig. 2 is an enlarged schematic view of an adjustable coil winding machine a according to an embodiment of the present utility model;

fig. 3 is a schematic front view of an adjustable coil winding machine according to an embodiment of the present utility model;

fig. 4 is a schematic top view of an adjustable coil winding machine according to an embodiment of the present utility model;

reference numerals illustrate:

100. a frame; 110. paying-off assembly; 111. a column; 1111. an extension section; 112. a rotating lever; 113. a locking member; 200. a rotating seat; 210. a cantilever shaft; 300. a mold; 400. a wire arranging assembly; 410. a guide rod; 420. a guide wheel; 421. a sliding wheel shaft; 422. a rotating wheel; 430. a wire arranging structure; 431. a wire arranging slide block; 432. a wire arranging rod; 433. arranging wire rings; 434. and a telescopic unit.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the utility model is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Referring to fig. 1 to 4 together, an adjustable coil winding machine according to the present utility model will now be described. An adjustable coil winding machine includes a frame 100 with a payout assembly 110 for winding a wire. The rotating base 200 is rotatably arranged on the frame 100 and is connected with a driving assembly arranged on the frame 100, the rotating axis of the rotating base 200 is arranged along the horizontal direction, and the rotating base is provided with two cantilever shafts 210 extending along the horizontal direction, and the two cantilever shafts 210 are annularly arranged at intervals around the rotating axis of the rotating base 200. And a die 300 connected with the two cantilever shafts 210, wherein the die 300 is provided with an annular winding groove. The wire arranging assembly 400 is disposed between the wire releasing assembly 110 and the mold 300, and is used for driving the wires led out from the wire releasing assembly 110 to reciprocate along the length direction of the cantilever shaft 210, so that the wires are uniformly wound in the annular winding grooves.

Compared with the prior art, the adjustable coil winding machine provided by the embodiment is provided with the stand 100, and a plurality of bobbins can be stored through the paying-off assembly 110 on the stand 100, so that the wires are supplied uninterruptedly. The rotating seat 200 is rotatably arranged on the frame 100, and the driving component on the frame 100 can drive the two cantilever shafts 210 on the rotating seat 200 to rotate. A die 300 is provided that can be attached to two cantilever shafts 210 to wind wires into annular wire-wrapping grooves on the die 300. The wire arranging assembly 400 is arranged and can drive the wires led out from the wire arranging assembly 110 to reciprocate along the length direction of the cantilever shaft 210, so that the wires are uniformly wound in the annular wire winding groove, the wound coils can be uniformly subjected to electromagnetic induction, and meanwhile, the wires are prevented from being broken, so that the practicability is good.

In some embodiments, the pay-off assembly 110 may take the configuration shown in fig. 1, 3, and 4. Referring to fig. 1, 3 and 4, the payout assembly 110 includes a post 111, a rotating lever 112 and a locking member 113. The two upright posts 111 are provided, and the two upright posts 111 are arranged at intervals along the extending direction of the cantilever shaft 210. One end of the rotating rod 112 is rotatably connected to one of the upright posts 111, and the rotating axis is arranged in the vertical direction, and the rotating rod 112 is used for rotatably connecting a bobbin for a wire. The locking member 113 is provided on the other column 111 and has an insertion groove into which the other end of the rotation lever 112 is inserted.

Wherein, both upright posts 111 have extension sections 1111, and each extension section 1111 extends vertically upward.

In particular, the drive assembly may be a spin chuck. The upright posts 111 are vertical posts, and two upright posts 111 are vertically disposed on the frame 100. The connection part of the rotating rod 112 and the upright post 111 connected with the rotating rod is provided with a rotating shaft, so that the rotating rod 112 can rotate on a horizontal plane by taking the rotating shaft as a rotating axis. The connection between the locking member 113 and the rotation rod 112 may be provided with an elastic snap ring, and an end of the rotation rod 112 may be fixed. A plurality of bobbins can be placed on the rotating rod 112, so that the wire can be taken out by the wire winding machine conveniently. The part of the upright column 111 above the joint of the rotating rod 112 is an extension section 1111, and the connecting structure is simple and has good practicability.

In some embodiments, the wire management assembly 400 may have a structure as shown in fig. 1, 3, and 4. Referring to fig. 1, 3 and 4, the wire management assembly 400 includes a guide bar 410, a guide wheel 420 and a wire management structure 430. The guide lever 410 is horizontally disposed above the rotation lever 112, and both ends are disposed on the two extension sections 1111, respectively. The guide wheel 420 is slidably disposed on the guide bar 410, and is used for guiding the wire delivered from the payout assembly 110. The wire arranging structure 430 is slidably disposed on the guide bar 410 and spaced from the guide wheel 420, for guiding the wires uniformly.

The guide rod 410 is provided with a sliding rail for sliding the wire arranging structure 430.

Specifically, the guide bar 410 may be a cylindrical bar on which a slide rail is provided. The guide wheel 420 may guide the wire delivered from the payout assembly 110. The wire arranging structure 430 can uniformly guide the wires, and the wires are uniformly wound on the die 300 in a circle, so that the practicability is good.

In some embodiments, the wire management structure 430 may be as shown in fig. 2. Referring to fig. 2, the wire management structure 430 includes a wire management slider 431, a wire management rod 432, a wire management ring 433, and a telescopic unit 434. The wire arranging slide block 431 is arranged on the slide rail in a sliding way. The wire arranging rod 432 has a fixed end and a wire arranging end, the fixed end of the wire arranging rod 432 is fixedly arranged on the wire arranging slide block 431, and the wire arranging end of the wire arranging rod 432 extends to the side surface of the rotation axis of the die 300 and is arranged at a distance from the die 300. The wire arranging ring 433 is disposed on the wire arranging end of the wire arranging rod 432 and has a tapered through hole for the wire to pass through. The fixed end of the telescopic unit 434 is fixed on the extending end of one of the upright posts 111, and the telescopic end of the telescopic unit 434 is connected to the wire arranging slider 431 for driving the wire arranging slider 431 to slide on the slide rail.

Specifically, the wire arranging slider 431 is provided with a sliding groove adapted to the sliding rail, so that the wire arranging slider 431 can slide on the sliding rail. Wire rods 432 are understood to extend obliquely sideways between their spaced guide wheels 420 and the die 300. The wire arranging ring 433 moves along with the wire arranging slider 431, so that the wire arranging ring 433 is always positioned between the guide wheel 420 and the die 300, and the wire passing through can be guided by the tapered through hole. The telescopic unit 434 may drive the wire arranging slider 431 to slide on the slide rail.

In some embodiments, the telescoping unit 434 may take the configuration shown in fig. 2. Referring to fig. 2, the telescoping unit 434 is an electric putter.

Specifically, the electric putter can control the flexible orbit of electric putter through the procedure of writing. The sliding track of the wire arranging slider 431 on the sliding rail can be controlled.

In some embodiments, the guide wheel 420 may have a structure as shown in fig. 2. Referring to fig. 2, the guide wheel 420 includes a sliding wheel shaft 421 and a rotating wheel 422. The sliding wheel shaft 421 is slidably disposed on the sliding rail, and the rotating wheel 422 is rotatably disposed on the sliding wheel shaft 421.

Specifically, the sliding wheel shaft 421 may be slidably disposed on the sliding rail. The rotating wheel 422 can be rotatably arranged on the sliding wheel shaft 421, so that the structure is simple and the practicability is good.

In some embodiments, the axle may take the configuration shown in FIG. 2. Referring to fig. 2, the sliding axle 421 is a ball bearing.

Specifically, the inner ring of the sliding wheel shaft 421 is slidably connected with the guide rod 410, which can be understood that a connecting groove adapted to the sliding rail is provided on the inner ring of the sliding wheel shaft 421, and the ball bearing can rotate the rotating wheel 422 along with the passing of the wire when the inner ring is fixed.

In some embodiments, the rotating wheel 422 may have a structure as shown in fig. 2. Referring to fig. 2, the rotating wheel 422 is provided with V-grooves.

In particular, the V-shaped groove may not shift the wire out of the rotating wheel 422.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (8)

1. An adjustable coil winding machine, comprising:

the rack is provided with a paying-off assembly for winding the wire;

the rotating seat is rotatably arranged on the frame and connected with the driving assembly arranged on the frame, the rotating axis of the rotating seat is arranged along the horizontal direction, and the rotating seat is provided with two cantilever shafts extending along the horizontal direction, and the two cantilever shafts are annularly arranged at intervals around the rotating axis of the rotating seat;

the mould is connected with the two cantilever shafts and is provided with an annular winding groove; and

and the wire arranging assembly is arranged between the wire arranging assembly and the die and is used for driving the wires led out from the wire arranging assembly to reciprocate along the length direction of the cantilever shaft so as to enable the wires to be uniformly wound in the annular winding groove.

2. The adjustable coil winding machine of claim 1 wherein the payout assembly comprises a post, a rotating lever, and a locking member; the two upright posts are arranged at intervals along the extending direction of the cantilever shaft; one end of the rotating rod is rotationally connected with one of the upright posts, the rotating axis is arranged along the vertical direction, and the rotating rod is used for rotationally connecting a wire winding drum for a wire; the locking piece is arranged on the other upright post and is provided with an embedded groove for the other end of the rotating rod to be put in;

the two upright posts are respectively provided with an extension section, and each extension section vertically extends upwards.

3. The adjustable coil winding machine of claim 2 wherein the wire management assembly comprises a guide bar, a guide wheel, a wire management structure; the guide rod is horizontally arranged above the rotating rod, and two ends of the guide rod are respectively arranged on the two extension sections; the guide wheel is arranged on the guide rod in a sliding manner and used for guiding the wire transmitted by the paying-off assembly; the wire arranging structure is arranged on the guide rod in a sliding way, is arranged at intervals with the guide wheel and is used for uniformly guiding the wires;

the guide rod is provided with a sliding rail for the wire arranging structure to slide.

4. The adjustable coil winding machine of claim 3 wherein the wire management structure comprises a wire management slider, a wire management rod, a wire management ring, and a telescoping unit; the wire arranging slide block is arranged on the slide rail in a sliding manner; the wire arranging rod is provided with a fixed end and a wire arranging end, the fixed end of the wire arranging rod is fixedly arranged on the wire arranging sliding block, and the wire arranging end of the wire arranging rod extends out to the side surface of the rotating axis of the die and is arranged at intervals with the die; the wire arranging ring is arranged on the wire arranging end of the wire arranging rod and is provided with a conical through hole, and the conical through hole is used for the wires to pass through; the fixed end of the telescopic unit is fixedly arranged at the extending end of one of the upright posts, and the telescopic end of the telescopic unit is connected to the wire arranging slide block and used for driving the wire arranging slide block to slide on the slide rail.

5. The adjustable coil winding machine of claim 4 wherein the telescoping unit is an electric pushrod.

6. An adjustable coil winding machine according to claim 3, wherein the guide wheel comprises a sliding wheel shaft and a rotating wheel; the sliding wheel shaft is arranged on the sliding rail in a sliding way, and the rotating wheel is arranged on the sliding wheel shaft in a rotating way.

7. The adjustable coil winding machine of claim 6 wherein the sliding axle is a ball bearing.

8. The adjustable coil winding machine of claim 6 wherein the rotating wheel is provided with a V-shaped slot.