CN217361361U - Wire storage mechanism of inductor winding machine - Google Patents

Abstract

The utility model provides an inductance coiling machine deposit line mechanism, inductance coiling machine includes the frame, deposit line mechanism and install in the frame, it includes to deposit line mechanism: the clamp mounting block is mounted on the rack; the clamp is arranged on the clamp mounting block and can rotate relative to the clamp mounting block along a first axis, a wire storage groove is formed in the circumferential surface of one end, far away from the clamp mounting block, of the clamp, and the first axis is horizontally arranged. The wire storage mechanism is provided with a wire winding and storage groove for storing copper wires.

Description

Wire storage mechanism of inductor winding machine

Technical Field

The utility model relates to a production field of inductance especially relates to a wire storing mechanism of inductance coiling machine.

Background

The inductor winding machine is used for winding a copper wire on an inductor body to form an inductor coil required by the inductor. In the winding, both ends of the copper wire are sometimes required to be wound simultaneously, but the wire source of one wire is fixed, and it is necessary to store a part of the copper wire first and to wind the stored copper wire together with the copper wire of the wire source in the winding.

SUMMERY OF THE UTILITY MODEL

The utility model discloses a main aim at provides an inductance coiling machine's line mechanism of depositing can save partly copper line, releases when treating the wire winding.

In order to achieve the above purpose, the utility model adopts the technical scheme that: the utility model provides an inductance coiling machine deposit line mechanism, inductance coiling machine includes the frame, deposit line mechanism and install in the frame, its characterized in that, deposit line mechanism includes:

the clamp mounting block is mounted on the rack;

the clamp is arranged on the clamp mounting block and can rotate relative to the clamp mounting block along a first axis, a wire storage groove is formed in the circumferential surface of one end, far away from the clamp mounting block, of the clamp, and the first axis is horizontally arranged.

Preferably, the jig comprises:

the two clamp mounting plates are oppositely arranged;

the clamping device comprises two clamping plates which are matched with each other, wherein the two clamping plates are arranged between the two clamp mounting plates, the arrangement direction of the two clamp mounting plates is perpendicular to the arrangement direction of the two clamping plates, one clamping plate is rotatably arranged on the two clamp mounting plates along a second axis, the first axis is perpendicular to the second axis, the second axis extends horizontally, the axis of the other clamping plate in the two clamping plates is parallel to the first axis, one end of the two clamping plates, which is far away from the clamp mounting block, extends out from one end of the two clamp mounting plates along the first axis, the extending end is a clamping end, the section of the clamping end of each clamping plate is semicircular, and the opposite side of the clamping ends of the two clamping plates is a plane; the wire storage groove is arranged on the circumferential surface of the clamping ends of the two clamping plates.

Preferably, the method further comprises the following steps:

the first mounting plate is arranged on the rack;

a drive column rotatably disposed on the first mounting plate, the drive column being movable back and forth in the direction of the first axis;

the rotating shaft is rotatably arranged on the clamp mounting block, one end of each clamp mounting plate, which is deviated from the clamping end, is arranged on one end of the rotating shaft, and the other end of the rotating shaft penetrates through the clamp mounting block and can be selectively jointed with or separated from one end of the driving column.

Preferably, a connecting cylinder is arranged at one end of the rotating shaft, which faces the driving column, the inner wall of the connecting cylinder, which faces the end of the driving column, is tapered, one end of the driving column, which faces the connecting cylinder, is tapered, and the tapered end of the driving column can be inserted into the tapered end of the connecting cylinder.

Preferably, the method further comprises the following steps:

the sliding block is slidably arranged on the first mounting plate;

and the driving shaft is rotatably arranged on a sliding block, the sliding block can move back and forth along the direction of the first axis, and the driving column is arranged on one end of the driving shaft close to the clamp.

Preferably, a push rod is further arranged on the first mounting plate and rotatably arranged on the first mounting plate, the rotation axis of the push rod is parallel to the first axis, and an ejector block is arranged on one side of the one clamping plate, which is far away from the other clamping plate, and is located on the side opposite to the clamping end relative to the rotation axis of the one clamping plate.

Compared with the prior art, the utility model discloses following beneficial effect has:

the utility model discloses a module on the coiling machine can be used for saving the copper line of certain length, and then can supply the line with the thread source as an interim line source when the wire winding to two-way when realizing the wire winding supplies the line, provides wire-wound efficiency.

Drawings

Fig. 1 is a perspective view of a preferred embodiment according to the present invention;

FIG. 2 is an enlarged view at A;

FIG. 3 is another angled view of FIG. 2;

FIG. 4 is a top view of FIG. 1;

fig. 5 is a perspective view of a partial structure.

Detailed Description

The following description is presented to disclose the invention so as to enable any person skilled in the art to practice the invention. The preferred embodiments in the following description are given by way of example only, and other obvious variations will occur to those skilled in the art.

As shown in fig. 1 to 5, a wire storing mechanism of an inductance winding machine includes a frame (not shown) on which the wire storing mechanism is mounted.

Deposit line mechanism including rack-mounted anchor clamps installation piece 5, set up anchor clamps 4 on anchor clamps installation piece 5, anchor clamps 4 are rotatable along the primary axis for anchor clamps installation piece 5, anchor clamps 4 include two anchor clamps mounting panel 7 that set up relatively and two splint 41 of mutually supporting, and two splint 41 set up between two anchor clamps mounting panel 7, and one of them splint 41 rotatably sets up two along the secondary axis on the anchor clamps mounting panel 7, can realize through the rotation that the clamp of two splint 41 is tight or loosen and then can realize the clamp tight or loosen to the copper line, primary axis and secondary axis mutually perpendicular, primary axis and secondary axis horizontal extension. The axis of the other clamping plate 41 of the two clamping plates 41 is parallel to the first axis, along the first axis direction, one end of the two clamping plates 41 departing from the clamp mounting block 5 extends out from one end of the two clamp mounting plates 7, the extending end is a clamping end, the cross section of the clamping end of each clamping plate 41 is semicircular, and the opposite side of the clamping end of the two clamping plates 41 is a plane. Preferably, a torsion spring (not shown) is provided at a position where the one clamping plate 41 is connected to the two clamp mounting plates 7, and the torsion spring makes the two clamping plates 41 always have a clamping tendency.

Further, be provided with on the periphery of the one end that stretches out from two anchor clamps mounting panel 7 of two splint 41 and deposit the wire casing 8, when two splint 41 are close to each other, the wire casing 8 of depositing on two splint 41 has formed the annular, can be earlier during copper line winding is deposited the wire casing 8 when the wire winding, because anchor clamps 4 can rotate, when the rotatory wire winding of inductance body, the inductance body is with the copper line from depositing wire casing 8 and pull out and twine on its self and realize the wire winding to the inductance body when rotatory. Before depositing the line groove 8 with the copper winding, press from both sides the end of a thread of copper line between two splint 41 earlier, then move the copper line to the position department that corresponds to depositing the line groove 8, anchor clamps 4 rotate certain number of turns, and the copper winding of certain length is in depositing the line groove 8. In actual production, the coiling machine has the spool of guide copper line, and the copper line that comes out from the line source passes through the spool, and the spool can drive the copper line and remove the position that needs, and when the wire winding, the inductance body is rotatory, and the copper line is from depositing the wire casing inlet wire on one side, and the spool inlet wire is followed to the another side.

Further, the jig mounting plate 7 is rotatably provided on the jig mounting block 5 by the rotating shaft 6.

The clamp installing device is characterized in that an installing block 2 is arranged on the rack, a rotating disc 3 is rotatably arranged on the installing block 2, the rotating axis of the rotating disc 3 is parallel to the first axis, a clamp installing block 5 is arranged on the rotating disc 3, and the rotating disc 3 drives a clamp 4 to rotate as required. The rotary disc 3 is driven by a rotary motor 19.

The wire storage mechanism further comprises a first mounting plate 1 arranged on the rack and a driving column 11 rotatably arranged on the first mounting plate 1, wherein the driving column 11 can move back and forth along the direction of the first axis, and the axis of the driving column 11 is collinear with the axis of the rotating shaft 6. The rotating shaft 6 deviates from one end of the clamping plate 41 is provided with a connecting cylinder 10, the driving column 11 and the connecting cylinder 10 can be selectively jointed or separated, after the jointing, the driving column 11 can drive the clamp 4 to rotate, and then the copper wire is wound in the wire storage groove 8. Preferably, the end of the driving stud 11 facing the connecting cylinder 10 is tapered, and the inner wall of the connecting cylinder 10 facing the end of the driving stud 11 is tapered, and the tapered end of the driving stud 11 can be inserted into the tapered end of the connecting cylinder 10.

Further, the wire storage mechanism further comprises a slide block 12 slidably disposed on the first mounting plate 1, and a driving shaft 13 rotatably disposed on the slide block 12, wherein the slide block 12 can move back and forth along the direction of the first axis, and the driving column 11 is disposed on one end of the driving shaft 13 close to the clamp 4. The sliding block 1 is further provided with a driving motor 14, the driving motor 14 is in transmission connection with the driving shaft 13 through a belt, and the driving motor 14 can drive the clamp 4 to rotate. The sliding block 1 can be driven by a cylinder or a lead screw nut combined with a motor in the prior art.

Further, a push rod 16 is further disposed on the first mounting plate 1, the push rod 16 is rotatably disposed on the first mounting plate 1, and a rotation axis of the push rod 16 is parallel to the first axis. On the side of the one clamping plate 41 facing away from the other clamping plate 41, a top piece 15 is provided, which top piece 15 is located on the side opposite the clamping end with respect to the axis of rotation of the one clamping plate 41. When the ejector rod 16 rotates, the lower end of the ejector rod can push the ejector block 15 to open the clamping end. Preferably, the ram 16 is driven by a push-pull air cylinder 17.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It should be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that all the embodiments and descriptions are provided in the present invention, and that various changes and modifications can be made without departing from the spirit and scope of the present invention, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (6)

1. The utility model provides an inductance coiling machine deposit line mechanism, inductance coiling machine includes the frame, it installs to deposit line mechanism in the frame, its characterized in that, it includes to deposit line mechanism:

the clamp mounting block is mounted on the rack;

the clamp is arranged on the clamp mounting block and can rotate relative to the clamp mounting block along a first axis, a wire storage groove is formed in the circumferential surface of one end, far away from the clamp mounting block, of the clamp, and the first axis is horizontally arranged.

2. The wire storage mechanism of claim 1, wherein the clamp comprises:

the two clamp mounting plates are oppositely arranged;

the clamping device comprises two clamping plates which are matched with each other, wherein the two clamping plates are arranged between the two clamp mounting plates, the arrangement direction of the two clamp mounting plates is perpendicular to the arrangement direction of the two clamping plates, one clamping plate is rotatably arranged on the two clamp mounting plates along a second axis, the first axis is perpendicular to the second axis, the second axis extends horizontally, the axis of the other clamping plate in the two clamping plates is parallel to the first axis, one end of the two clamping plates, which is far away from the clamp mounting block, extends out from one end of the two clamp mounting plates along the first axis, the extending end is a clamping end, the section of the clamping end of each clamping plate is semicircular, and the opposite side of the clamping ends of the two clamping plates is a plane; the wire storage groove is arranged on the circumferential surface of the clamping ends of the two clamping plates.

3. The wire deposit mechanism of claim 2, further comprising:

the first mounting plate is arranged on the rack;

a drive column rotatably disposed on the first mounting plate, the drive column being movable back and forth in the direction of the first axis;

the rotating shaft is rotatably arranged on the clamp mounting block, one end of each clamp mounting plate, which is deviated from the clamping end, is arranged on one end of the rotating shaft, and the other end of the rotating shaft penetrates through the clamp mounting block and can be selectively jointed with or separated from one end of the driving column.

4. The wire storage mechanism according to claim 3, wherein a connecting cylinder is provided at an end of the rotary shaft facing the driving cylinder, an inner wall of the connecting cylinder facing the end of the driving cylinder is tapered, and an end of the driving cylinder facing the connecting cylinder is tapered, and the tapered end of the driving cylinder is insertable into the tapered end of the connecting cylinder.

5. The wire deposit mechanism of claim 4, further comprising:

the sliding block is slidably arranged on the first mounting plate;

and the driving shaft is rotatably arranged on a sliding block, the sliding block can move back and forth along the direction of the first axis, and the driving column is arranged on one end of the driving shaft close to the clamp.

6. The wire storage mechanism of claim 3, wherein a ram is further disposed on the first mounting plate, the ram being rotatably disposed on the first mounting plate, a rotational axis of the ram being parallel to the first axis, and a top block is disposed on a side of the one clamping plate facing away from the other clamping plate, the top block being located on a side opposite to the clamping end with respect to the rotational axis of the one clamping plate.

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