KR100799340B1 - Coil winding devices of noise filter and coil winding method using the same - Google Patents

Abstract

A coil winding device of a noise filter and a coil winding method using the same are provided to remarkably improve a workability according coil winding since the structure of the coil winding device is simple and the coil is stably wound. A coil winding device includes a rotation clamp, a push rod, and a rotating member. The rotation clamp rotates a hollow ferrite core(110) in one direction at a predetermined angle by interposing the hollow ferrite core. The push rod passes through a hollow of the ferrite core to position one portion of a coil by accepting the one portion of the coil formed in one portion of the hollow ferrite core. The rotating member rotates one portion positioned in the other portion of the ferrite core in the one direction with accepting the one portion of the coil positioned in the other portion of the ferrite core to wind the coil to an outer diameter of the ferrite core.

Description

Coil winding device for noise filter and coil winding method for noise filter using same

Figure 1 shows the overall configuration of the noise filter produced by the coil winding device for noise filter according to the present invention,

Figure 2 is a schematic diagram showing the overall configuration of the coil winding device for a noise filter according to the present invention,

3 is a schematic diagram sequentially showing a winding process of the coil through the coil winding device for a noise filter according to the present invention.

**** Explanation of symbols for the main parts of the drawing ****

1. Coil winding device for noise filter

10. Clamp 20. Swivel Clamp

21. Motor 21 '. Axis of rotation

22. Gripping member 23. Connecting arm

30. Push Rod

40, 40 '. Swing member 41. Adhesion rock

50. Pressing means 51, 51 '. roller

100. Noise Filter 110. Core

111.Hollow 120. Coil

P. Center Point

The present invention relates to a coil winding device for a noise filter and a coil winding method for a noise filter using the same, and more particularly, to a coil winding device for a noise filter configured to repeatedly wind a coil on a ring-shaped core constituting the noise filter. A coil winding method for a noise filter used.

In general, home appliances receive commercial AC power and rectify it as necessary to use it as a driving power source.

At this time, since commercial AC power flowing along the power line is a sine wave of low frequency, noise of high frequency is often transmitted through this power signal, and this noise interferes with the normal operation of other products. Therefore, a noise filter is provided to remove this.

Since the noise filter installed on the PCB substrate or the like is made of a ferrite core having a through hole formed at the center thereof, a conventional apparatus or means for winding a coil uniformly is not provided to the ferrite core, and thus the operator can manually The coil is wound around the ferrite core through.

As such, when the winding of the coil is made by hand, workability is remarkably degraded, and the labor cost must be excessively input, thereby causing a problem of an increase in the accompanying cost.

SUMMARY OF THE INVENTION An object of the present invention devised to solve the above problems is a coil winding device for a noise filter which repeatedly winds a coil in a hollow structure in a hollow waste light core constituting a noise filter, and a noise filter using the device. The present invention provides a coil winding method.

The above object is achieved by the following configuration provided in the present invention.

Coil winding device for noise filter according to the present invention,

In the hollow waste light core constituting the noise filter, the coil is repeatedly wound in a radial structure,

A rotary clamp which rotates a predetermined angle in one direction by sandwiching the hollow ferrite core;

A push rod that adheres to one point of the coil formed across one side of the hollow ferrite core and penetrates the hollow of the ferrite core so that one point of the coil is positioned on the other side;

It characterized in that it comprises a pivot member for turning the point of the coil located on the other side of the ferrite core in a state of adhesion through the adhesive arm, so that the coil is wrapped around the outer diameter of the ferrite core.

Preferably, the rotary clamp includes a motor having a rotating shaft disposed concentrically with the center point of the ferrite core; A holding member disposed on one edge of the ferrite core to sandwich the edge of the ferrite core; And a connecting arm connecting the gripping member and the rotating shaft to each other.

More preferably, the other side of the rotary clamp is provided with an auxiliary clamp for assisting and sandwiching the hollow ferrite core.

On the other hand, the coil winding method for a noise filter according to the present invention,

A first step of clamping the edge of the ferrite core by the clamp member of the rotary clamp;

A second step in which the push rod adheres to one point of the coil formed across one side of the ferrite core and pushes the other point to penetrate one point of the coil through the hollow of the ferrite core;

A third step in which the pivot member pivots in one direction on the coil formed on the other side of the ferrite core by the push rod to wind the coil around the outer diameter of the ferrite core;

By rotating the rotational shaft of the rotary clamp in one direction at a predetermined angle, the winding stroke including the fourth step of rotating the ferrite core at a predetermined angle in one direction radiates the coil to the hollow ferrite core constituting the noise filter. It is characterized by repeatedly winding in a structure.

Hereinafter, a coil winding apparatus for a noise filter and a coil winding method for a noise filter using the same will be described in detail with reference to the accompanying drawings.

Figure 1 shows the overall configuration of the noise filter produced by the coil winding device for noise filter according to the present invention, Figure 2 is a schematic diagram showing the overall configuration of the coil winding device for noise filter according to the present invention.

The coil winding device 1 for noise filter proposed in the preferred embodiment of the present invention repeats the coil 120 in a radial structure to the hollow ferrite core 110 constituting the noise filter 100 of FIG. It is a device to wind up.

In this embodiment, the coil winding device (1) for the noise filter, as shown in Figure 2 the rotary clamp 20 for pinching the hollow ferrite core 110 to rotate in one direction; Pushes the one point of the coil 120 formed across one side of the hollow ferrite core 110 to penetrate the hollow 111 of the ferrite core 110 to position one point of the coil 110 on the other side. Rod 30; And a pivot member 40 that the coil 120 wraps around the outer diameter of the ferrite core 110 by pivoting in one direction with one point of the coil 110 positioned on the other side of the ferrite core 110 attached thereto. It is configured.

As shown in FIG. 2A, the coil winding device 1 for the noise filter is provided with one turning member 40, and in FIG. 2B, the coil winding device 1 for the noise filter 1 is shown. Swivel members 40 and 40 'are symmetrically provided.

Even if one turning member 40 is provided as shown in FIG. 2A, the process of winding the coil 120 in the ferrite core 110 may be smoothly performed. However, as shown in FIG. 2B, the pair of turning members 40 and 40 ′ are provided. In this case, while the shoulder arm 41 of the pivot member 40 rotated for winding the coil returns to its original position, the shoulder arm 41 of the other pivot member 40 'is coil 120. It can be wound on the outer diameter of the ferrite core 110 to have the advantage that the operation is implemented more quickly. In addition, a cylinder (not shown) may be provided on the adhesive arm 41 of the pivot members 40 and 40 ', and may be configured to allow a stretch of a predetermined length for attaching the coil.

In this embodiment, the auxiliary clamp 10 for assisting and pinching the edge of the ferrite core 110 is provided on the other side of the rotary clamp 20, so that a more stable pinching state of the ferrite core 10 is realized. .

In addition, the push rod 30 is preferably a solenoid or pneumatic cylinder, the auxiliary clamp 10 and the rotary clamp 20 may be a well-known pneumatic or solenoid may be adopted, the link structure or rack And pinion structures may also be adopted.

Referring to the drawings showing a preferred embodiment the end of the coil 120 formed across one side of the ferrite core 110 is interposed in the pressing means 50 consisting of a pair of rollers 51, respectively, always tense with a constant tension To be pulled out.

In addition, when the coil 120 formed across the ferrite core 110 is pulled one point of the coil 120 through the push rod 30 or the pivot member 40, one or both ends of the coil 120 Is gradually pulled inward and transported.

In the present embodiment, the rotary clamp 20, the motor 21, the rotary shaft 21 'is arranged concentrically with the center point of the ferrite core 120; A holding member 22 installed at one edge of the ferrite core 120 to sandwich the edge of the ferrite core 120; And a connecting arm 23 connecting the holding member 22 and the rotating shaft 21 'to each other.

As in the present embodiment, when the rotation shaft 21 ′ of the motor 21 constituting the rotation clamp 20 forms a concentric structure with the center point P of the ferrite core 110, the ferrite core 110 changes in the trajectory. It will rotate without.

Figure 3 is a schematic diagram showing the winding process of the coil through the coil winding device for a noise filter according to the present invention in sequence, the coil winding device for a noise filter according to this embodiment is repeatedly carried out the winding stroke to be described later, to the ferrite core The coil is wound into a radial structure.

Referring to FIG. 3, the winding stroke is described in detail. The first rotation clamp 20 clamps the edge of the ferrite core 110 as shown in FIG. 3A, and at the same time, the auxiliary clamp 10 installed on the other side also has a ferrite core. The edge of the 110 is sandwiched to maintain a more stable fixed state of the ferrite core 110. At this time, the coil 120 is formed across one side of the ferrite core 110.

Thereafter, as shown in FIGS. 3B and 3C, the push rod 30 moves forward and adheres to one point of the coil 120 formed across one side of the ferrite core 110 to the other side, and thus, one point of the coil 120. To pass through the hollow 111 of the ferrite core 110.

As described above, one point of the coil 120 penetrating the hollow 111 of the ferrite core 110 adheres to the adherent arm 41 of the pivot member 40, as shown in FIG. 3D, to the outer diameter of the ferrite core 110. To this end, the abutment arm 41 of the pivot member 40 is bound to the coil 120 formed on the other side of the ferrite core 110 by the push rod 30, and adheres in one direction to ferrite. The coil 120 is wound around the outer diameter of the core 110.

Thereafter, as shown in FIG. 3E, the auxiliary clamp 10 releases the pinched state of the ferrite core 110, and in this state, the rotation clamp 20 rotates at a predetermined angle in one direction. Therefore, the ferrite core 110 also rotates at a predetermined angle.

At this time, since the rotation axis 21 of the rotary clamp 20 and the center point P of the ferrite core 110 have the same relationship, the trajectory deviation of the ferrite core 110 does not occur.

When going through the winding stroke, the coil 120 is wound once in the outer diameter of the ferrite core 110 and if the winding stroke is repeatedly performed, the hollow waste light core 110 constituting the noise filter 100 The coil 120 is repeatedly wound in a radial structure.

When the coil 120 is wound around the ferrite core 110 through the winding stroke, the operator cuts the end of the coil 120 as illustrated in FIG. 3H, and the coil 120 is wound around the ferrite core 110. The noise filter 100 is discharged.

As described above, the present invention proposes a coil winding device for a noise removing core which automatically winds a coil repeatedly on a ring-shaped core constituting a noise filter.

Since the coil winding device for the noise removing core according to the present invention has the advantage that the structure is relatively simple and the coil is stable, the workability according to the coil winding can be greatly improved when such a device is actually supplied to the field. Could be.

Claims (4)

In the hollow waste light core constituting the noise filter, the coil is repeatedly wound in a radial structure, A rotary clamp which rotates a predetermined angle in one direction by sandwiching the hollow ferrite core; A push rod that adheres to one point of the coil formed across one side of the hollow ferrite core and penetrates the hollow of the ferrite core so that one point of the coil is positioned on the other side; The coil winding device for a noise filter, characterized in that it comprises a swinging member for turning in one direction in a state in which one point of the coil located on the other side of the ferrite core, the coil wrapped around the outer diameter of the ferrite core. The rotary clamp of claim 1, further comprising: a motor having a rotating shaft disposed concentrically with a center point of the ferrite core; A holding member disposed on one edge of the ferrite core to sandwich the edge of the ferrite core; And a connecting arm connecting the gripping member and the rotating shaft to each other. The coil winding device for a noise filter according to claim 1, wherein an auxiliary clamp for assisting and pinching the hollow ferrite core is provided on the other side of the rotary clamp. A first step of clamping the edge of the ferrite core by the clamp member of the rotary clamp; A second step in which the push rod adheres to one point of the coil formed across one side of the ferrite core and pushes the other point to penetrate one point of the coil through the hollow of the ferrite core; A third step in which the pivot member pivots in one direction on the coil formed on the other side of the ferrite core by the push rod to wind the coil around the outer diameter of the ferrite core; By rotating the rotational shaft of the rotary clamp in one direction at a constant angle, the winding stroke including the fourth step of rotating the ferrite core at a predetermined angle in one direction radiates the coil to the hollow wastelight core constituting the noise filter. A coil winding method for a noise filter, which is repeatedly wound in a structure.

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