KR20050082116A - Deflection yoke for cathode-ray tube - Google Patents

Abstract

The present invention relates to a deflection yoke for a cathode ray tube for deflecting an electron beam emitted from an electron gun in a vertical and horizontal direction.

The present invention as described above in the deflection yoke for the cathode ray tube comprising a horizontal and vertical coil for deflecting the electron beam emitted from the electron gun horizontally or vertically, the vertical coils are connected in parallel as the current is applied is wound on the ferrite core Provided is a deflection yoke for a cathode ray tube including a first vertical coil and a second vertical coil.

Description

Deflection Yoke for Cathode-ray tube

The present invention relates to a deflection yoke for a cathode ray tube, and more particularly, to a deflection yoke for a cathode ray tube capable of correcting a misconvergence of a screen caused by L / R distortion correction without a change in the Q value of a mask.

In general, the CRT screen screens an electron gun 4 that emits three electron beams, a screen 1 that strikes these beams to reproduce light, and a shadow mask 2 that separates the three electron beams, and an electron beam as shown in FIG. And a deflection yoke (3) for deflecting to the predetermined place of (1). The deflection yoke 3 includes a horizontal deflection coil 31 for deflecting the electron beam emitted from the electron gun 4 inside the CRT in the horizontal direction and a vertical deflection coil for deflecting the electron beam in the vertical direction. (33) and the conical ferrite core 34 used to reduce the loss of magnetic force generated in the horizontal deflection coil 31 and the vertical deflection coil 33 to increase the magnetic efficiency, and the vertical deflection coil 31 and the vertical The deflection coil 33 and the conical ferrite core 34 are fixed to a predetermined position, and composed of main components such as a holder 32 for insulating between the horizontal deflection coil 31 and the vertical deflection coil 33.

Figure 2 shows a conventional convergence yoke for the deflection yoke (convergence yoke), 3 to 4 pieces of the c-shaped iron piece (201) to additionally correct the misconvergence due to the manufacturing error of the deflection yoke (3) and the CRT. After stacking by installing a bobbin 206 surrounding the U-shaped iron piece 201 and the convergence yoke (35) winding the correction coils (202 ~ 205) in each bobbin 206 is installed symmetrically, a pair of A ring-shaped permanent magnet 36 is attached to the neck portion of the deflection yoke 3 as shown in FIG.

As described above, the deflection yoke 3 to which the convergence yoke is attached flows a current having a frequency of 15.75 KHz or higher to the horizontal deflection coil 31 and uses the magnetic field generated therein to horizontally move the electron beam inside the CRT. In addition, a current having a frequency of 60 Hz is generally passed through the vertical deflection coil 33 to deflect the electron beam in the vertical direction by using a magnetic field generated accordingly. Self-convergence allows three electron beams to achieve convergence on the screen 1 without using additional circuits and additional devices by using non-uniform magnetic fields by the horizontal deflection coil 31 and the vertical deflection coil 33. Type of deflection yoke 3 is mainly developed. That is, by adjusting the winding distributions of the horizontal deflection coil 31 and the vertical deflection coil 33 to create a barrel or pin cushion type magnetic field for each of the openings, the middle part, and the neck part, the three electron beams have different deflection forces according to their positions. The experience allows them to be gathered at the same point at different distances from the starting point of the electron beam to the screen 1, which is the arrival point. In addition, when a current is applied to the horizontal deflection coil 31 and the vertical deflection coil 33 to generate a magnetic field, only the magnetic field generated by the horizontal deflection coil 31 and the vertical deflection coil 33 causes the electron beam to appear in front of the screen 1. It is difficult to deflect the ferrite core 34 of high permeability to minimize the loss on the return path of the magnetic field to increase the magnetic field efficiency to increase the magnetic force.

On the other hand, the current technology of the cathode ray tube for display is almost saturated, that is, it is almost limited to widen the difference in visible technologies such as the sharpness and image quality, which is the quality characteristic of the cathode ray tube. In addition to reducing the cost of components, research is being focused on implementing cathode ray tubes of similar quality to general cathode ray tubes.

Considering this point, conventionally, a cross arm (32a) is installed in the deflection yoke screen unit without using a correction circuit to correct the minute L / R distortion generated when the cathode ray tube is driven. . That is, as described above, the cross arm 32a installed in the screen portion of the deflection yoke strengthens the 3 o'clock and 9 o'clock directions of the deflection magnetic field generated by the horizontal and vertical deflection coils during the operation of the cathode ray tube to correct the L / R distortion. do. Looking at the L / R distortion correction principle in more detail, as shown in FIG.

4 is a view for explaining the convergence correction according to the trajectory of the electron beam emitted from the electron gun of the conventional cathode ray tube. As shown, first, the electron beam emitted from the electron gun 4 proceeds while maintaining the static convergence. S is an interval between the R beam and the B beam at the center of deflection of the deflection yoke by the convergence yoke 35. The value is changed and the S value is increased by the L / R distortion correction device of the deflection yoke such as the cross arm or the magnet. The horizontal position change of the R beam and the B beam changes the incident angle of the electron beam incident on the shadow mask, thereby adversely affecting the electron beam arrangement characteristics. The electron beam arrangement characteristic that appears according to the change of the incident angle of the electron beam may be represented by a grouping ratio as shown in the following equation.

G / R = 3SQ / PhL

In general, when the incident angle of the electron beam is large according to the S value, the electron beam appears as degrouping that is not focused in one place, and when the electron beam incident angle is small, the focusing characteristic is represented as good grouping. Where S is the distance between the R and B beams from the deflection yoke's center of deflection, Q is the distance from the panel's inner surface to the shadow mask, Ph is the horizontal pitch of the shadow mask, and L is the panel's inner surface at the deflection center of the deflection yoke. It shows the distance to. Looking at the above equation, if the value S, the distance between the R beam and the B beam at the deflection yoke of the deflection yoke increases, the degree of grouping is changed, thereby deteriorating the electron beam arrangement characteristic formed on the screen. Therefore, in order to correct the electron beam arrangement characteristic, it is necessary to reduce the Q value, which is the distance from the inner surface of the panel 1 to the shadow mask 2 shown in FIG. 5. This means that the curvature of the mask is flattened, and the flattened mask has a problem in that the drop characteristic, which is an impact resistance property, is deteriorated.

In addition, the flattened mask causes a problem of deterioration in the howling characteristic caused by the structural change of the mask as well as the dominant characteristic caused by the electron beam impact on the mask during the operation of the cathode ray tube.

Therefore, in order to prevent the deterioration of the conventional electron beam array by correcting the misconvergence of the screen generated during cathode ray tube operation, the deflection yoke for cathode ray tube can improve the mask drop and howling characteristics appearing as the Q value of the mask is inevitably changed. The purpose is to provide.

A first technical solution for achieving the above object is a deflection yoke for a cathode ray tube comprising horizontal and vertical coils for horizontally or vertically deflecting an electron beam emitted from an electron gun. The first vertical coil and the second vertical coil are connected in parallel and applied to the ferrite core as applied.

A more preferable technical solution of the present invention is a convergence yoke using a current direction control unit for controlling the direction of the vertical deflection current input from the first vertical coil and the second vertical coil, and a vertical deflection current input from the current direction control unit. A first misconvergence correction unit configured to form a pole magnetic field in the first and second convergence coils of the display to correct the miss convergence (YBH) of the screen, and winding the ferrite core using current input from the first misconvergence correction unit; The third and fourth vertical deflection coils to correct the misconvergence (YCH) of the screen, and the third and fourth parts of the convergence yoke using the current input from the second misconvergence correction unit. The four convergence coils include a third misconvergence correction unit for correcting the misconvergence of the screen.

In addition, a first diode having a diode cathode connected to the first and second vertical coils of the present invention, a second diode having a diode anode connected to the first and second vertical coils, and the first and second diodes The first misconvergence correction unit may be connected in series to each of the first and second convergence coils.

In addition, one end of the third and fourth vertical coils may be connected in series with the first and second convergence coils, respectively, and the other end may be connected with the third convergence coil of the third misconvergence correction unit. It is characterized by.

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

6 is a view showing the structure of a deflection yoke for a cathode ray tube according to the present invention. As shown, looking at the structure of the deflection yoke according to the present invention, a horizontal deflection coil (not shown) and a vertical deflection coil 33 for horizontally or vertically deflecting the electron beam emitted from the electron gun, and the horizontal deflection coil and the vertical deflection Ferrite core (34) for reducing the magnetic force generated from the coil to increase the magnetic efficiency, the horizontal deflection coil, the vertical deflection coil and the ferrite core is fixed to a predetermined position between the horizontal deflection coil and the vertical deflection coil It includes a holder 32 for insulation, which is the same as a general conventional deflection yoke structure. However, a pair of vertical coils 101 and 102 wound on the ferrite core 34 are connected in parallel as shown in FIG. 7 to vertically deflect the electron beam, and the other pair of vertical coils 301 and 302 are deflected. It is connected in series with the convergence coils 202 and 204 wound around the U-shaped convergence yoke 35 installed in the yoke neck portion to correct the miss convergence of the screen.

7 is a diagram illustrating a correction circuit of a deflection yoke for a cathode ray tube according to the present invention. As shown, the deflection yoke correction circuit for correcting the vertical deflection of the electron beam and the misconvergence of the screen includes a vertical deflection unit 100 and a current direction control unit for greatly deflecting the electron beam emitted from the electron gun in the vertical direction of the screen. 110, first, second, and third misconvergence correction units 200, 300, and 400.

Looking at the structure and operation principle of the correction circuit configured as described above in detail, first, the first and second vertical coils (101, 102) in the vertical deflection portion 100 is connected in parallel to the ferrite core 34 is applied current As a result, the electron beam is deflected in the vertical direction. Thereafter, the current direction control unit 110 controls the direction of the vertical deflection current input from the vertical deflection unit 100 to flow to the first miss convergence correction unit 200 which corrects the miss convergence. In the current direction controller 110, the first diode 111 and the second diode 112 are formed, and the connection structure of each diode is a first diode, the first diode cathode is the first of the vertical deflection portion The first diode anode is connected in series to the first convergence coil 202 of the first misconvergence correction unit. In the case of the second diode, the second diode anode is connected to the first and second vertical coils 101 and 102 of the vertical deflection portion, and the second diode cathode is the second convergence coil 204 of the first misconvergence correction portion. Is connected in series.

In the first misconvergence correction unit 200, a first convergence coil 202 and a second convergence coil 204 are connected in parallel to a convergence yoke, and a vertical deflection current is applied to the first convergence coil and the second convergence coil. In this case, a polar magnetic field is formed in each convergence coil to compensate for the YBH miss convergence in which the R beam and the B beam are bent out with respect to the Y axis of the screen. That is, the polar magnetic field is a four-pole magnetic field. When the vertical deflection current is positive, the second diode 112 is operated and the first diode 111 is not operated. Therefore, the current is applied to the second convergence coil 204. 4 is applied to the converged yoke 35 to generate a four-pole magnetic field. As shown in FIG. 8, the R beam moves in the 9 o'clock direction and the B beam moves in the 3 o'clock direction to correct the misconvergence. In addition, the variable resistor (VR1) for adjusting the current flowing through the first and second convergence coil is provided to correct the YBH miss convergence of the R-beam and B-beam bent out on the Y-axis of the screen. This means that the distance S between the R beam and the B beam becomes smaller at the deflection yoke of the deflection yoke. Therefore, the Q value, which is the distance from the inner surface of the panel to the shadow mask, is reduced to prevent the grouping of the conventional electron beam array. Note can improve the electron beam array characteristics without structural change. In addition, the four-pole magnetic field generated in the convergence coil can reduce the mask Q value to correct the conventional electron beam arrangement, thereby preventing the mask doming, howling and drop characteristics caused by the flattening of the mask.

On the other hand, due to the four-pole magnetic field generated by the convergence coil provided in the deflection yoke neck portion, the vertical line R beam and the B beam intersect with respect to the Y axis of the screen to generate a mismatched YCH misconvergence. This misconvergence has one end of the third and fourth vertical coils 301 and 302 of the second misconvergence corrector 300 connected in series with the first and second convergence coils 202 and 204, respectively, and the other end of the second misconvergence correction unit 300. When the current flows in connection with the three-convergence coil 203, a magnetic field is generated in the opposite direction to the four-pole magnetic field to correct misconvergence of the screen.

In the third misconvergence corrector 400, the third and fourth convergence coils 203 and 204 connected in series form a two-pole magnetic field, and the G beam and the R beam and the B beam are perpendicular to the vertical direction of the screen Y axis as shown in FIG. The mismatched comma is corrected.

As described above, when the deflection yoke correction circuit of the present invention is configured to correct the misconvergence of the screen as described above, it is possible to correct the misconvergence generated by the conventional correction device for L / R distortion correction. In addition, the mask may form a predetermined curvature without changing the Q value of the mask for misconvergence correction, thereby improving the howling, drop, and doming characteristics of the mask.

As such, those skilled in the art will appreciate that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof. Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the appended claims rather than the foregoing description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

As described above, the present invention has an effect of preventing deterioration of electron beam arrangement characteristics generated by a correction device for correcting L / R distortion of a screen. In addition, in order to prevent deterioration of the conventional electron beam arrangement, there is an effect of preventing deterioration of mask howling, drop, and dominant characteristics appearing according to a change in mask Q value.

1 is a view showing a schematic structure of a typical cathode ray tube.

2 is a view showing a conventional convergence yoke for deflection yoke.

3 is a rear view showing a deflection yoke including a conventional cross arm.

4 is a view for explaining the convergence correction according to the trajectory of the electron beam emitted from the electron gun of the conventional cathode ray tube.

5 is a diagram showing Q values of a conventional cathode ray tube panel and mask.

6 is a view showing a deflection yoke for a cathode ray tube of the present invention.

7 is a view showing a correction circuit of a deflection yoke for a cathode ray tube of the present invention.

8 is a view showing a shape in which a four-pole magnetic field is formed in the converged yoke of the present invention.

9 is a view showing a shape in which a bipolar magnetic field is formed in the converged yoke of the present invention.

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

1: Panel 2: Shadow mask

3: deflection yoke 4: electron gun

31: horizontal deflection coil 32: holder

33: vertical deflection coil 34: ferrite core

35: Convergence York 36: Permanent magnet

Claims (4)

In the deflection yoke for cathode ray tubes comprising horizontal and vertical coils for deflecting the electron beam emitted from the electron gun horizontally or vertically, The vertical coil is a deflection yoke for a cathode ray tube including a first vertical coil and a second vertical coil which is connected in parallel and wound on a ferrite core as a current is applied. The method of claim 1, The vertical coil may include a current direction control unit controlling a direction of a vertical deflection current input from the first vertical coil and the second vertical coil; A first misconvergence correction unit for correcting a miss convergence (YBH) of a screen by forming a pole magnetic field in the first and second convergence coils of the converged yoke using the vertical deflection current input from the current direction controller; A second misconvergence correction unit configured to correct misconvergence (YCH) of a screen by the third and fourth vertical deflection coils wound on the ferrite core using a current input from the first misconvergence correction unit; And A third misconvergence correction unit for correcting misconvergence of the screen by the third and fourth convergence coils of the convergence yoke using the current input from the second misconvergence correction unit; Deflection yoke for a cathode-ray tube, characterized in that it comprises a. The method according to claim 1 or 2, A first diode having a diode cathode connected to the first and second vertical coils, a second diode having a diode anode connected to the first and second vertical coils, and a first misconvergence of the first and second diodes Deflection yoke for a cathode ray tube, characterized in that connected to the first and second convergence coil of the correction unit in series. The method of claim 2, One end of the third and fourth vertical deflection coils is connected in series with the first and second convergence coils, and the other end is connected with the third convergence coil of the third misconvergence correction unit. Deflection yoke for cathode ray tubes.