KR20040074420A - Fixing structure of ferrite core for deflection yoke - Google Patents

Abstract

PURPOSE: A ferrite core fixing structure of a deflection yoke is provided to fix strongly the ferrite core at a coil separator without using a hot melt. CONSTITUTION: A ferrite core fixing structure of a deflection yoke comprises a coil separator(50) formed with a pair of mixture and having respectively a horizontal deflection coil and a vertical deflection coil at an inner side and an outer side, and a conical shape ferrite core(60) mounted vertically at the coil separator and improving a magnetic efficiency by reducing a magnetic force loss of a vertical deflection magnetic field generated at the vertical deflection coil. A large diameter end part of the ferrite core is press fit to the coil separator.

Description

FIXING STRUCTURE OF FERRITE CORE FOR DEFLECTION YOKE}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a ferrite core fixing structure of a deflection yoke for fixing a ferrite core to a coil separator in a deflection yoke used in a color CRT tube. In particular, the ferrite core is fitted to the coil separator to prevent flow of the ferrite core. It relates to a ferrite core fixing structure of a deflection yoke to solve the instability.

In general, a deflection yoke is used in an image display device using a television receiver or other cathode ray tube to deflect an electron beam generated from an electron gun.

That is, a cathode ray tube such as a color receiver tube uses an in-line electron gun that emits electron beams from three electron guns arranged in a line on the same horizontal plane, and the electron beams emitted from these electron guns converge at one point of the screen. To use deflection yoke.

Since the color cathode ray tube using an inline electron gun is arranged in parallel with the electron guns emitting the red (R), green (G), and blue (B) electron beams, the electron beam emitted from the three electron guns is used as one point of the screen. To converge, the deflection yoke applies self-converging using non-uniform magnetic fields.

When the deflection yoke is applied, the three electron beams emitted from the electron gun of the neck portion are deflected in the horizontal or vertical direction by a pin cushion horizontal deflection magnetic field and a barrel type vertical deflection magnetic field in which the deflection yoke is generated.

Thus, three electron beams emitted from the inline electron gun are landed on the phosphor screen through a shadow mask to implement an image.

As shown in FIG. 1, the colored cathode ray tube is formed of a glass panel 10 formed in a substantially rectangular shape, a funnel-shaped glass funnel 11 formed in succession to the panel 10, and a small diameter of the funnel 11. Cylindrical glass neck portion 12, which is connected to the end of the panel, and a dot or stripe which is provided on the inner surface of the panel 10 and emits red (R), green (G), and blue (B) light. a substantially rectangular phosphor screen 13 coated with a stripe-shaped three-color phosphor layer, a shadow mask 14 provided inside the phosphor screen 13 and having a plurality of fine holes or slit holes, Three in-line electron guns 15 mounted on the neck 12 and positioned on the same horizontal plane to emit red (R), green (G), and blue (B) electron beams, respectively, and the funnels 11 It is installed outside the neck portion 12 and discharged from the in-line electron gun 15 It consists of a deflection yoke 20 for deflecting the beam in a horizontal direction and a vertical direction.

In the color cathode ray tube configured as described above, the electron beam emitted from the inline electron gun collides with the phosphor of the phosphor screen to form a color image.

The three in-line electron guns arranged in a row emit red, green, and blue electron beams, and these electron beams are deflected in the long axis, that is, in the horizontal axis direction by a pin cushion type horizontal magnetic field generated by the deflection yoke. These electron beams are also shortened, i.e., deflected in the vertical axis direction, by the barrel-type vertical magnetic field generated by the deflection yoke.

Three electron beams deflected by the deflection yoke in the horizontal axis direction and the vertical axis direction arrive at the phosphor screen through the fine holes or the slit holes of the shadow mask which performs the color sorting function. The three electron beams are concentrated all over the phosphor screen, i.e., the entire screen, and color images are displayed by horizontal scanning or vertical scanning.

Here, the deflection yoke 20 includes a pair of vertical deflection coils 22 for deflecting the electron beam emitted from the inline electron gun 15 of the neck portion 12 in the vertical direction, as shown in FIG. 2, and the electron beam. A pair of horizontal deflection coils 21 for deflecting them in the horizontal direction, a conical ferrite core 23 for reducing magnetic force loss of the vertical deflection magnetic field generated by the vertical deflection coils 22 to improve magnetic efficiency, and Circular holder 24 for fixing the horizontal deflection coil 21, the vertical deflection coil 22 and the ferrite core 23 to a predetermined position while insulating the horizontal deflection coil 21 and the vertical deflection coil 22. Consists of

The deflection yoke configured as described above flows a current having a frequency of 15.75 kHz or more to a pair of horizontal deflection coils through both ends, and uses a pincushion-type horizontal magnetic field generated therein, so that the inside of the color cathode ray tube Deflect the electron beam in the horizontal direction.

In addition, a pair of vertical deflection coils are supplied with a current having a frequency of 60 kHz, and the electron beam inside the color cathode ray tube is deflected in a vertical direction by using a barrel-type vertical magnetic field generated accordingly.

However, the deflection yoke 20 uses a non-uniform magnetic field by a pair of horizontal deflection coils and a pair of vertical deflection coils so that the three electron beams are displayed on the screen even without a separate additional circuit and an additional device. Magnetically concentrated deflection yoke to achieve convergence.

Magnetically focused deflection yoke adjusts the winding distribution of a pair of horizontal deflection coils and one vertical deflection coil to create a barrel- or pin-cushion type magnetic field for each part, so that three electron beams are deflected differently according to their position. Experience the power. Thus, the electron beam is deflected by different deflection forces in the opening, the middle and the neck, respectively, and can be collected at the same point through different paths from the starting point to the phosphor screen, which is the destination point.

To this end, a pair of horizontal deflection coils use a shade coil to reduce the distribution angle and thicken the width to make the horizontal deflection magnetic field inside the deflection yoke generally fin-shaped, and the pair of vertical deflection coils have a distribution angle in the electron gun. It is preferable to form a magnetic field distribution by forming a magnetic field of a barrel type by increasing the size of the barrel, and then to make a pin cushion type magnetic field with a small distribution angle at the opening of the deflection yoke corresponding to the screen side.

Here, when a current is applied to a pair of horizontal deflection coils and a pair of vertical deflection coils to create a horizontal deflection magnetic field and a vertical deflection magnetic field, the horizontal / vertical by a pair of horizontal deflection coils and a pair of vertical deflection coils. The deflection magnetic field alone is difficult to deflect the electron beam to the front of the screen, and the magnetic permeability is increased by minimizing the loss in the return path of the magnetic field by using a ferrite core of high permeability.

Looking at the relationship between the ferrite core and the coil separator, as shown in FIG. 3 is a view schematically showing a general deflection yoke.

Referring to FIG. 3, when the deflection yoke 30 is manufactured, the ferrite core 31 is vertically coupled to the coil separator 32, and a vertical deflection coil 33 is disposed outside the ferrite core 31. . The ferrite cores 31 are constituted by a pair, and are assembled to each other by the core clamp 34.

The ferrite core 31 is installed after the direction adjustment in the correct state with the vertical deflection coil 33 when installed in the coil separator 32. The coil separator 32 has a space for installing the ferrite core 31, and a large diameter portion of the ferrite core 31 is coupled in a space provided in the coil separator 32.

Of course, the ferrite core 31 is installed perpendicular to the coil separator 32, and is provided with fixing means for fixing the ferrite core 31 so as not to shake after assembly. The fixing means of the ferrite core 31 is hot melt applied to the outside of the ferrite core 31.

That is, a wedge such as a sponge is filled in the space formed in the coil separator 32 so that the ferrite core 31 installed in the coil separator 32 does not flow in the space in which the ferrite core 31 is coupled to the coil separator 32. Hot melt is applied to the ferrite core 31 to fix the ferrite core 31.

However, if the hot melt flows from the ferrite core 31 to the coil separator 32 when the hot melt is applied, the ferrite core 31 may flow due to the hot melt filled in the space formed in the coil separator 32. have. Therefore, the flow prevention part 35 is provided outside the large diameter part of the ferrite core 31 so that the hot melt applied to the ferrite core 31 does not flow to the coil separator 32 so that the hot melt flows to the coil separator 32 side. Do not get off.

However, even when the flow preventing part 35 is provided in the ferrite core 31, most of the flow preventing part 35 has a plate structure, and thus, when the hot melt is applied, the hot melt is accurately accumulated in the flow preventing part 35. If it flows to the outside without it occurs. Accordingly, the ferrite core 31 and the vertical deflection coil 33 may flow with respect to the coil separator 32, and the hot melt may flow even after application, and the hot melt may be easily broken by the impact and the consumption amount of the hot melt may be reduced. It was a lot.

In order to solve this problem, the applicant has devised and applied the flow preventing projection 35` of the hot melt in which the flow preventing projection 35` is installed in the outer axis direction on the central axis of the deflection yoke. There is a bar. Therefore, the above-described problem can be solved by hot melt applied to the ferrite core 31 and accumulated in the flow preventing part 35 of the ferrite core.

In addition, due to the space formed between the coil separator 32 and the ferrite core 31 when the ferrite core 31 is installed in the coil separator 31 in the manufacturing process of the deflection yoke 30, the ferrite core 31 The ferrite core 31 may not be accurately fixed due to the wedge made of hot melt or sponge or the like in a state of being finely struck by the weight thereof.

As a result, the position of the ferrite core 31 relative to the coil separator 32 is different from the design position, resulting in miss convergence. Therefore, there is a need for an apparatus for correcting miss convergence.

In particular, when the ferrite core 31 is fixed in the retracted state, the distortion characteristic of the screen as shown in FIG. 4 appears. That is, when the ferrite core 31 is not firmly fixed to the coil separator 32, the ferrite core 31 moves to the neck portion of the deflection yoke 30 due to the sliding phenomenon of the ferrite core 31. The screen distortion as shown in FIG. 4 is caused by the magnet characteristic due to the formation of a pin magnetic field.

As described above, in the conventional deflection yoke 30, hot melt is applied to the ferrite core 31 so that the ferrite core 31 installed perpendicular to the coil separator 32 does not flow.

However, when the hot melt is applied, an odor caused by the hot melt is generated and adversely affects the environment according to the application of the hot melt. In particular, as the television is enlarged and planarized, hot melt is excessively applied, and as the amount of hot melt is increased, adverse effects on the environment are increasing. However, if the hot melt is not applied, the ferrite core 31 is not firmly fixed to the coil separator 32, and as a result, the characteristics of the screen become unstable and miss convergence occurs.

As a result, there is no means for fixing the ferrite core 31 in the coil separator 32 when the ferrite core 31 is installed in the coil separator 32 to produce the deflection yoke 30 used for color television or the like. Therefore, the ferrite core 31 may flow, and when the ferrite core 31 flows, characteristics of the screen may become unstable, such as distortion. In order to prevent this, when the hot melt is applied to the outside of the ferrite core 31, an odor caused by the application of the hot melt is generated, which adversely affects the environment.

As described above, the conventional ferrite core fixing structure of the deflection yoke has no means for firmly fixing the ferrite core to the coil separator, so that an unstable characteristic of the screen occurs or a hot melt is used to fix the ferrite core. Environmental problems are caused by the smell of.

The present invention has been made to solve the above problems of the prior art, it is possible to firmly fix the ferrite core to the coil separator without using a hot melt on the outside of the ferrite core characteristics of the screen due to the flow of the ferrite core It is an object of the present invention to provide a ferrite core fixing structure of a deflection yoke that prevents the occurrence of instability and also prevents the smell caused by the application of the hot melt.

1 is a cross-sectional view showing a typical cathode ray tube and a deflection yoke;

2 is a perspective view showing a general deflection yoke;

3 is a view showing a ferrite core fixing structure of a conventional deflection yoke,

4 is a reference diagram illustrating a distortion phenomenon of a screen when a conventional deflection yoke fixing structure is applied;

5 is a view showing a ferrite core fixing structure of the deflection yoke according to the present invention;

6 is a detailed view of portion A of FIG. 5;

7 is a view schematically showing a ferrite core fixing structure of the deflection yoke of the present invention;

8 is a view showing the position of the ferrite core fixing portion of the main component of the present invention,

9 is a reference diagram showing a normal screen shape that appears when applying the present invention.

<Explanation of symbols on main parts of the drawings>

50: coil separator 51: hook portion

52: space portion 55: ferrite core fixing portion

60: ferrite core 61: jamming

62: vertical cutout

Ferrite core fixing structure of the deflection yoke according to the present invention for solving the above technical problem; A coil separator consisting of a pair of combinations and having a horizontal deflection coil and a vertical deflection coil installed inside and outside, respectively; In the ferrite core fixing structure of the deflection yoke comprising a conical ferrite core which is installed perpendicular to the coil separator and reduces the magnetic force loss of the vertical deflection magnetic field generated in the vertical deflection coil to improve the magnetic efficiency, the coil separator in the A large diameter end portion of the ferrite core is characterized in that the fitting.

According to a second aspect of the present invention, the coil separator includes a space portion protruding to the ferrite core side to which the large diameter end portion of the ferrite core is fitted and a hook portion fixed to prevent the ferrite core from being separated.

According to a third aspect of the present invention, the ferrite core is formed of a latching projection in which a large diameter end is inserted into a space portion of the coil separator and is engaged with a hook portion of the coil separator.

According to a fourth aspect of the present invention, the ferrite core is a vertical cut portion is formed so that the hook portion of the coil separator is not caught at a position spaced a predetermined distance from the end of the locking projection.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

The ferrite core coupling structure of the deflection coil according to the present invention is composed of a pair of combinations as shown in Figs. 5 to 7 and the coil separator 50 in which the horizontal deflection coil and the vertical deflection coil are installed on the inner and outer sides, respectively. And a conical ferrite core 60 installed perpendicular to the coil separator 50 to reduce magnetic force loss of a vertical deflection magnetic field generated in the vertical deflection coil and improving magnetic efficiency. The ferrite core fixing part 55 protrudes upward of the coil separator 50 along the neck end portion.

Here, the ferrite core fixing part 55 is formed to fit the large diameter end portion of the ferrite core 60, as shown in Figure 8 are respectively formed on the top, bottom, left and right of the coil separator 50 The up, down, left and right flow of the ferrite core 60 is prevented.

In other words, the ferrite core fixing part 55 protrudes from the coil separator 50 toward the ferrite core 60 to form a space portion 52 into which the large diameter end portion of the ferrite core 60 is fitted. It is formed, the upper portion of the space portion 52 is composed of a hook portion 51 for fixing the ferrite core 60 is not separated.

The hook portion 51 has an upper surface inclined toward the center of the ferrite core 60. In addition, the ferrite core fixing portion 55, that is, the hook portion 51 is formed of a material having a predetermined elasticity to facilitate the installation of the ferrite core 60.

In addition, the ferrite core 60 is formed of a locking projection 61 is inserted into the space portion 52 of the coil separator 50, the large diameter end is engaged with the hook portion 51 of the coil separator 50. do. In addition, the ferrite core 60 is a vertical cut portion 62 is formed so that the hook portion 51 of the coil separator 50 is not caught at a position spaced a predetermined distance from the end of the locking projection (60). Accordingly, the hook portion 51 is not caught by the vertical cutting portion 62 of the ferrite core 60 so that the engaging projection 61 of the ferrite core 60 is not separated.

The ferrite core fixing structure of the deflection yoke according to the present invention configured as described above is fixed so that the ferrite core installed in the coil separator does not move so that the characteristic instability of the screen due to the flow of the ferrite core does not occur without applying hot melt.

At least one ferrite core fixing part 55 protruding toward the ferrite core 60 is formed in the coil separator 50 along the large diameter end edge of the ferrite core 60. However, in order to prevent the up, down, left, and right flow of the ferrite core 60, the ferrite core fixing part 55 is preferably formed on the top, bottom, left and right four sides of the coil separator 50, respectively.

The ferrite core fixing part 55 is a space portion 52 formed so that the large diameter end portion of the ferrite core 60 can be fitted and the ferrite core 60 is fitted to the space portion 52. The hook portion 51 is fixed to prevent the large diameter end portion from being separated, and the hook portion 51 forms the upper surface to be inclined toward the center of the ferrite core 60.

Here, the ferrite core fixing portion 55 is preferably formed of an elastic material having a predetermined elastic force. This is to restore the initial shape after the hook portion 51 is deformed when the ferrite core 60 is installed to fix the ferrite core 60. Therefore, the ferrite core 60 may be fixed to the coil separator 50 by simply pushing the ferrite core 60 against the ferrite core fixing part 55.

The ferrite core 60 is formed in a conical shape, but a large protrusion end portion is inserted into the space portion 52 of the coil separator 50 and is caught by the hook portion 51 of the coil separator 50. 61). In addition, the ferrite core 60 is formed with a vertical cut portion 62 to prevent the hook portion 51 of the coil separator 50 from being caught at a position spaced a predetermined distance from the end of the locking projection 61.

When the ferrite core 60 is pushed against the ferrite core fixing part 55 of the coil separator 50 in a state where the engaging projection 61 and the vertical cutout 62 are formed in the ferrite core 60, the ferrite The locking projection 61 of the core 60 is pushed while compressing the hook portion 51 at an instant and inserted into the space portion 52 of the coil separator 50. Of course, after the engaging projection 61 of the ferrite core 60 is inserted, the hook portion 51 is returned to its original shape by elasticity, after which the ferrite core 60 is fixed to move. At this time, due to the vertical cut portion 62 of the ferrite core 60, the hook portion 51 is not caught by the ferrite core 60, but is restored to its initial form, so that the engaging projection 61 of the ferrite core 60 is separated. Do not become.

As the ferrite core 60 is fixed to the coil separator 50 and does not move, the ferrite core 60 may not apply hot melt to the ferrite core 60. Therefore, the problem of environmental pollution due to the smell of the hot melt does not occur.

In addition, if the ferrite core 60 is fixed to the coil separator 50 and is not shaken, the problem of instability of the screen caused by the flow of the ferrite core 60 is also solved, even if no additional device is installed You get a screen.

That is, the hook portion 51 blocks the movement of the ferrite core 60 toward the neck portion so that the ferrite core 60 is in a normal position, and as a result, the distortion characteristics of the screen due to the push of the ferrite core 60. This will not appear so that a clean screen as shown in FIG. 9 can be obtained.

As described above, the ferrite core fixing structure of the deflection yoke according to the present invention prevents the ferrite core from being inserted and coupled to the coil separator so as to prevent movement toward the neck portion. By not using the melt there is an advantage that can solve the environmental problems such as smell.

In addition, since the hot melt is not applied to the ferrite core, there is another advantage of simplifying the casting since there is no need to install a component to block the flow of the hot melt.

In addition, the ferrite core is aligned with the coil separator and then the ferrite core can be pushed into the coil separator to complete the installation, thereby improving productivity.

Claims (7)

A coil separator consisting of a pair of combinations and having a horizontal deflection coil and a vertical deflection coil installed inside and outside, respectively; In the ferrite core fixing structure of the deflection yoke, which is installed perpendicular to the coil separator and comprises a conical ferrite core to reduce the magnetic force loss of the vertical deflection magnetic field generated in the vertical deflection coil to improve the magnetic efficiency, The ferrite core fixing structure of the deflection yoke, characterized in that the large diameter end portion of the ferrite core is fitted to the coil separator. The ferrite core fixing part of claim 1, wherein the coil separator protrudes toward the ferrite core and includes a space portion in which a large diameter end portion of the ferrite core is fitted and a hook portion fixing the ferrite core so that the ferrite core is not separated. The ferrite core fixing structure of the deflection yoke characterized by the above-mentioned. The ferrite core fixing structure of the deflection yoke of claim 2, wherein the hook portion has an upper surface portion formed to be inclined toward the center of the ferrite core. The method according to claim 2 or 3, The hook portion ferrite core fixing structure of the deflection yoke, characterized in that formed of a material having a predetermined elasticity. The method of claim 2, The ferrite core fixing portion is fixed to the ferrite core of the deflection yoke, characterized in that formed on each of the top, bottom, left and right of the coil separator to prevent the up, down, left and right flow of the coil separator. The ferrite core fixing of the deflection yoke according to claim 1 or 2, wherein the ferrite core is formed of a catching protrusion which is inserted into a space portion of the coil separator and is caught by a hook portion of the coil separator. rescue. The ferrite core fixing structure according to claim 5, wherein the ferrite core has a vertical cut portion formed so that the hook portion of the coil separator is not caught at a position spaced a predetermined distance from the end of the locking projection.