KR100467843B1 - Apparatus for making deflection coil - Google Patents

Abstract

The present invention relates to a deflection yoke, and more particularly, the coil (C) supplied is guided to the winding die (500) through a plurality of guide rollers via a main tension adjusting unit (200), and a magnetic material inside the main tension adjusting unit. In the apparatus for manufacturing a deflection coil by winding the supplied coil while the winding die rotates, a magnetic force is generated to prevent a coil from being slid when a constant voltage is applied. It is rotatably installed between the guide rollers positioned so as to have a magnetic body 602 that generates magnetic force when power is applied to the inside, and the auxiliary tension adjusting unit for selectively applying power through a separate control unit ( Characterized in that it comprises a 600), the present invention is provided with a supplementary tension adjusting unit ten generated in accordance with the rotation angle of the winding die There is an effect that, because the coil is to be wound with a constant tension force always to improve the difference between the minimum left and right slippage of the deflection coil and the difference to improve the frozen Balance of the screen improves the product quality of the output.

Description

Deflection coil manufacturing apparatus {Apparatus for making deflection coil}

The present invention relates to a deflection yoke, and more specifically, a deflection yoke provided with a sub-tension adjustment unit for controlling the strength of magnetic flux generated in a pair of vertical and horizontal deflection coils used in the deflection yoke to improve the performance of the deflection yoke. It relates to a coil manufacturing apparatus.

In general, a cathode ray tube (CRT) of a TV receiver or a monitor is provided with a deflection yoke, which is one of the most important components of a magnetic device.

The deflection yoke allows the electric signal transmitted in time series to be reproduced as an image on the screen of the cathode ray tube. The direction of the deflection yoke is changed when the electron beam passes through the magnetic field formed through the horizontal and vertical deflection coils. By using this method, the three-color beams scanned from the electron gun are deflected precisely into the fluorescent film applied to the screen surface of the cathode ray tube.

That is, the deflection yoke moves the electron beam scanned by the electron gun in the horizontal direction from left to right and at the same time moves from top to bottom to reproduce the image.

As shown in FIG. 1, the deflection yoke 10 is installed in the RGB electron gun section 3 of the cathode ray tube 1, and the electron beam scanned from the electron gun 3a is directed to the screen surface 2 of the cathode ray tube 1. Deflection to the applied fluorescent film.

2 schematically shows a general deflection yoke.

Referring to this, the conventional deflection yoke 10 is provided with a coil separator 20 and horizontal deflection coils (not shown) which are provided around inner and outer sides of the coil separator 20 to form a horizontal deflection magnetic field and a vertical deflection magnetic field, respectively. And a vertical deflection coil 30 and a ferrite core 40 for enhancing the magnetic fields of the horizontal and vertical deflection coils.

The coil separator 20 is formed to have a substantially conical shape to distinguish the positions of the vertical and horizontal deflection coils and to electrically insulate each other, and the screen portion 22 is provided on the screen surface side of the cathode ray tube. The electron gun portion of the cathode ray tube is provided with a cylindrical neck portion 24 coupled to the electron gun portion, and the screen portion and the neck portion are integrally connected by a fallopian tube-shaped connecting portion.

The inner side of the coil separator 20 is assembled so as to be in close contact with the horizontal deflection coil divided into upper and lower sides, and the outer side is assembled so as to be in close contact with the vertical deflection coil 30 divided into the left and right sides, and the deflection coil is heated and melted. It is fixed so as not to flow through the 50 (hot melt adhesive, etc.).

In addition, a ferrite core 40 for reinforcing the vertical deflection magnetic field is assembled around the outer circumference of the coil separator 20 to surround the vertical deflection coil 30.

In addition, the outer side of the coil separator 20 is provided with a printed circuit board 60 to receive power from the outside while electrically connecting the components, the printed circuit board is configured to be covered by the cover (70).

In the deflection yoke configured as described above, the horizontal and vertical deflection coils are manufactured separately and assembled in the coil separator. FIG. 3 schematically illustrates a configuration of the deflection coil manufacturing apparatus according to the related art.

Referring to this, the conventional deflection coil manufacturing apparatus is basically composed of a bobbin 100, a plurality of guide rollers and a winding die for winding the coil (C).

The coil C supplied from the bobbin 100 is first wound about two times by the main tension adjusting unit 200, and then the tension force is adjusted through the plurality of main guide rollers 300 and the auxiliary guide rollers 400. In the state is guided to the winding mold 500.

Here, the magnetic tension 202 is provided inside the main tension adjusting unit 200, the magnetic force is generated when the power is applied, the sagging of the coil is prevented by the magnetic body 202.

That is, when a constant voltage is applied to the main tension adjusting unit 200, a magnetic force is generated in the magnetic body 202, and the main tension adjusting unit pulls the coil C by the magnetic force, so that the sagging of the coil is prevented.

Winding mold 500 is configured to be rotated by a separate rotating means, and when the winding mold is rotated guided coil (C) is made of a deflection coil while winding in the winding die.

In the conventional deflection coil manufacturing apparatus configured as described above, since a constant voltage is applied to the main tension adjusting unit 200 when the winding die 500 is rotating, the tension amount is always kept constant in the same amount.

However, there is a problem in that the amount of tension applied to the main guide roller 300 located at the end according to the shape of the winding die 500 is different depending on the winding angle.

This is illustrated in detail in FIGS. 4A and 4B, which will be described below. For reference, two separate coils are manufactured in pairs, and FIGS. 4A and 4B illustrate directions in which deflection coils symmetrical to each other are wound.

First, referring to FIG. 4A, when the winding mold 500, which is only partially represented, is rotated in the clockwise direction CW, the coil C is drawn on the S side and wound on the winding mold.

At this time, since the winding die 500 has a trapezoidal shape, the coil C wound on both sides of the winding die has a difference in slip property. That is, as shown in the drawing, due to the difference in tension force depending on the winding angle, the coil wound on the left side (indicated by the pin side in the drawing) is looser than the coil wound on the right side of the mold (in the figure). Winding.

Of course, as shown in Figure 4b, when the winding mold 500 is rotated in the counterclockwise direction (CCW), the coil (C) is drawn in the S side (direction symmetrical to Figure 4a), the winding to the mold, in this case Coils wound on the right side of the mold are more loosely wound than coils wound on the left side of the mold, so that a difference in slip characteristics occurs.

And when the deflection coil symmetrically stacked as shown in Figure 5, it can be seen that the loosely wound portion and the relatively winding portion is clearly divided into left and right.

Therefore, when the power is applied to the deflection coil manufactured as described above, magnetic field difference is generated due to the difference in slip characteristics at the left and right sides, which causes a problem that greatly affects the quality.

That is, due to the unbalance of the magnetic field generated by the deflection coil thus manufactured, miss-convergence occurs on the screen, which is illustrated in FIGS. 6A and 6B.

FIG. 6A shows the vertical misconvergence in which the horizontal line of the red R is shifted from the horizontal line of the blue B, and FIG. 6B shows the horizontal misconvergence in which the vertical line R and the vertical line B intersect.

As a result, one of the important techniques for manufacturing the deflection yoke is to prevent misconvergence on the screen. As described above, the deflection coil manufactured by the conventional manufacturing method has a magnetic field difference between the left and right sides due to the difference in tension force. There is a problem that occurs because the mis-convergence on the screen and lowers the overall quality of the product.

The present invention has been made in order to solve the various problems as described above, the purpose is to add the same tension force to the left and right when manufacturing the deflection coil so that the difference does not occur in the slip properties left and right magnetic field It is to provide a deflection coil manufacturing apparatus that improved the difference.

Bobbin for supplying a coil according to the present invention for achieving the above object; A winding mold installed to rotate and winding the supplied coil in the shape of a designed deflection coil; A main tension adjusting unit rotatably installed between the bobbin and the winding die, the coil being supplied is guided in a state of being wound at least two times, and having a magnetic material generated therein when a power is applied; A plurality of main guide rollers rotatably installed to add a constant tension force while guiding the coil through the main tension adjustment unit; An auxiliary guide roller rotatably installed between the main guide roller and the winding die to guide the coil horizontally; And an auxiliary tension adjusting unit rotatably installed between the main guide roller and the auxiliary guide roller and guided in a state in which the coil is wound at least once, and having a magnetic material generated therein when a power is applied thereto. .

1 is a side view showing an example of a typical cathode ray tube;

2 is a plan view showing the configuration of a general deflection yoke;

Figure 3 is a schematic view showing the configuration of a deflection coil manufacturing apparatus according to the prior art,

4a and 4b is a schematic plan view showing the strength and winding state of the magnetic field according to the rotation direction appearing when the deflection coil is wound through the winding die according to the prior art,

5 is a front view schematically showing a state in which a pair of deflection coils produced according to the prior art are stacked;

6A and 6B are diagrams for explaining misconvergence displayed on a screen according to magnetic field differences.

7 is a schematic view showing the configuration of a deflection coil manufacturing apparatus according to the present invention;

8 is a view showing for explaining an example of the principle of operation of the auxiliary tension adjustment unit in the present invention.

◎ Explanation of symbols for main part of drawing

1: cathode ray tube 2: screen surface

3: electron gun 3a: electron gun

10: deflection yoke 20: coil separator

22: screen portion 24: neck portion

30: vertical deflection coil 40: ferrite core

50: adhesive 60: printed circuit board

70: cover 100: bobbin

200: main tension adjustment unit 202: magnetic material

300: main guide roller 400: auxiliary guide roller

500: winding die 600: auxiliary tension adjustment unit

602: magnetic material C: coil

Hereinafter, the present invention will be described in detail with reference to the accompanying drawings. The same components as in the prior art will be described using the same names and symbols.

Figure 7 is a schematic diagram showing the configuration of a deflection coil manufacturing apparatus according to the present invention.

Referring to this, the deflection coil manufacturing apparatus according to the present invention is provided with a bobbin 100 is wound coil (C).

The coil C supplied from the bobbin 100 is guided to the winding mold 500 through the tension adjusting unit and the plurality of guide rollers.

That is, the coil C supplied from the bobbin 100 is first guided in a state of being wound at least two times by the main tension adjusting unit 200, and then guided to the plurality of main guide rollers 300.

The main tension adjusting unit 200 is rotatably installed, and is provided with a magnetic body 202 that generates magnetic force when a power is applied therein, and pulls the coil C from the magnetic body 202 to prevent the coil from sagging. do.

The plurality of main guide rollers 300 are rotatably installed, and are arranged in a zigzag manner up and down to add a constant tension force to the coil C.

The coil C guided by the main guide roller 300 is wound at least once through the auxiliary tension adjusting unit 600 and then supplied to the winding mold 500 through the auxiliary guide roller 400.

The auxiliary tension adjusting unit 600 is rotatably installed, and a magnetic body 602 is provided inside the main tension adjusting unit, and power may be selectively applied to the magnetic body 602 through a separate controller (not shown). It is configured to be.

That is, the magnetic body 602 of the auxiliary tension adjusting unit 600 is configured to be selectively applied to the power according to the rotation angle of the winding die 500, the rotation angle of the winding die 500 is the coil (C) to the winding die In the winding process, if the position is relatively loosely wound (see FIGS. 4A and 4B), the power is applied to generate magnetic force.

For example, if the supplied coil C is drawn for the first time along an inclined surface that extends outwardly of the winding die 500, the angle of the winding die rotates from 270 ° to 0 ° when this angle is 0 °. It is preferable to allow a voltage to be applied to the auxiliary tension adjusting unit 600 in the range of.

Each of the auxiliary guide rollers 400 is rotatably installed and guides the coil C guided through the auxiliary tension adjusting unit 600 to be substantially horizontal to supply the winding mold 500.

The winding mold 500 is configured to be rotated by a known rotating means, and when the winding mold is rotated, the coil C supplied is manufactured in the shape of a deflection coil designed while winding in the mold.

Now, the operation and operational effects of the present invention thus constructed will be described.

Referring first to the operation relationship, the coil (C) supplied through the bobbin 100 is primarily guided through a plurality of main guide roller 300 via the main tension adjustment unit 200.

In this case, since a constant voltage is applied to the magnetic body 202 of the main tension adjusting unit 200, a constant tension force is always applied to the coil C to be supplied.

Next, the coil C having passed through the plurality of main guide rollers 300 is guided through the auxiliary tension adjusting unit 600 and the auxiliary guide rollers 400 and is supplied to the winding mold 500.

At this time, since the winding die 500 has a trapezoidal shape, the tension force of the coil is generated differently according to the winding angle, and the difference in the tension force is adjusted by the auxiliary tension adjusting unit 600.

That is, in general, in the process of winding the coil C while the winding mold 500 rotates, a phenomenon in which one side of the deflection coil is more loosely wound than the opposite side in which the deflection coil is relatively symmetrical occurs. When the mold rotates to a portion, the tension is applied to the magnetic body 602 of the auxiliary tension adjusting unit 600 so as to pull the coil C to adjust the tension force.

8 is an example of the principle of operation of the auxiliary tension adjustment unit according to the present invention.

Referring to this the operation relationship of the auxiliary tension adjustment unit 600 in more detail, the coil (C) is supplied to the first contact with the inclined surface that extends outward from the winding mold 500, the winding angle at this time is 0 It becomes °.

At this point, no voltage is applied to the auxiliary tension adjusting unit 600, and the coil C supplied is wound around the winding mold 500 only by the tension force applied through the main tension adjusting unit 200.

Subsequently, the voltage is not applied to the auxiliary tension adjusting unit 600 until the winding die 500 is rotated at 270 °. At the time when the winding die 500 passes, the coil C narrows inwardly from the winding die. Due to the winding of the inclined surface, the tension force is loosened due to the shape of the mold, and thus a voltage is applied to the auxiliary tension adjusting unit 600.

In other words, when the winding die 500 passes 270 °, the coil C is pulled more strongly by using the magnetic force generated by applying the voltage to the auxiliary tension adjusting unit 600, and thus, the coil C. When wound on the winding die 500 is given the same tension force as in other angles.

Of course, the voltage applied to the auxiliary tension adjusting unit 600 is cut off when the winding die 500 is rotated to a position of 0 ° again.

As such, since the voltage is selectively applied to the auxiliary tension adjusting unit 600, the coil C wound on the winding mold 500 is always given a constant tension force, and thus, the left and right slip characteristics of the deflection coils that have been manufactured are The difference is minimal.

When the left and right slip characteristics of the deflection coils manufactured as described above are minimized, the magnetic fields flowing to the left and right sides of the deflection coils are kept constant, and the unbalance on the screen is improved to improve the quality of convergence.

In addition, since the quality of the deflection coil is improved, it has an excellent product competitiveness and improves work efficiency.

As described above, the deflection coil manufacturing apparatus according to the present invention is provided with an auxiliary tension adjustment unit to improve the difference in the tension force generated according to the rotation angle of the winding die, so that the coil can be always wound with a constant tension force deflection The left and right slip of the coil minimizes the difference and improves the unbalance of the screen, thereby improving the product quality.

While the invention has been shown and described in connection with specific embodiments as described above, it is well known in the art that various modifications and changes can be made without departing from the spirit and scope of the invention as indicated by the claims. Anyone who owns it can easily find out.

Claims (6)

Bobbins for supplying coils; A winding mold installed to rotate and winding the supplied coil in the shape of a designed deflection coil; A main tension adjusting unit rotatably installed between the bobbin and the winding die, the main coil being guided in a state in which the supplied coil is wound at least twice, and having a magnetic material generated therein when a power is applied; A plurality of main guide rollers rotatably installed to add a constant tension force while guiding the coil through the main tension adjusting unit; An auxiliary guide roller rotatably installed between the main guide roller and the winding die to guide the coil horizontally; And It is rotatably installed between the main guide roller and the auxiliary guide roller is guided in a state in which the coil is wound at least once, and is configured to include an auxiliary tension adjusting unit provided with a magnetic material is generated when the power is applied therein The auxiliary tension adjusting unit may be positioned between the main guide roller located at the end and the auxiliary guide roller at the first position, and the magnetic material of the auxiliary tension adjusting unit may be selectively applied by a separate control unit according to the rotation angle of the winding die. The deflection coil manufacturing apparatus, characterized in that the magnetic force is selectively configured. delete delete According to claim 3, wherein the auxiliary tension adjustment unit is configured to adjust the tension force by generating a magnetic force is applied to only the relatively winding portion of the coil when the coil is wound on the winding die to adjust the tension of the left and right of the deflection coil Deflection coil manufacturing apparatus characterized in that the difference is minimized. The coil to be supplied is guided to the winding die through a plurality of guide rollers through the main tension adjusting unit, and a magnetic material is provided inside the main tension adjusting unit so that when a constant voltage is applied, magnetic force is generated to prevent the coil from sagging. In the device for winding the coil supplied while rotating the deflection coil, It is rotatably installed between the guide roller located in close proximity to the winding die, and the inside is provided with a magnetic material that generates a magnetic force when the power is applied, this magnetic material is selectively according to the rotation angle of the winding die through a separate control unit Deflection coil manufacturing apparatus characterized in that it comprises a secondary tension adjustment unit for applying power. The slip tension of the left and right sides of the deflection coil according to claim 5, wherein the auxiliary tension adjusting unit is configured to adjust the tension force by generating power by applying power only to a portion that is relatively loosely wound when the coil is wound around the winding die. Deflection coil manufacturing apparatus characterized in that the difference is minimized.