KR20030027223A - Right convergence deflection yoke - Google Patents

Abstract

PURPOSE: A convergence correction device for a deflection yoke is provided to accurately correct vertical mis-convergence by controlling an auxiliary vertical deflection coil. CONSTITUTION: A convergence correction device comprises magnetic field generating coil circuits(CY1 to CY4) for generating N-pole or S-pole, and which are constituted by two pairs of coils connected in serial; a first diode circuit(D1,D2) constituted by two diodes connected in an opposite direction; a second diode circuit(D3,D4) constituted by two diodes connected in an opposite direction; a first variable resistor(VR1) for adjusting convergence in one direction from the center of the screen; a second variable resistor(VR2) connected between the two diodes of the first diode circuit and the two diodes of the second diode circuit, wherein the second variable resistor adjusts convergence in upward or downward direction of the screen; and a damping resistor(R1) connected between the contact between the two pairs of coils and the contact between the operating terminal of the first variable resistor and the operating terminal of the second variable resistor. The magnetic field generating coil circuit, first variable resistor and the first diode circuit are connected in parallel, and the second diode circuit is connected in parallel to the magnetic field generating coil circuit in the direction opposite to the first diode.

Description

Deflection yoke convergence correction device {RIGHT CONVERGENCE DEFLECTION YOKE}

The present invention relates to a convergence correction circuit for controlling a deflection yoke of a CRT, and more particularly, to a circuit for correcting vertical misconvergence by controlling an auxiliary vertical deflection coil.

In the conventional case, when displaying an image on a CRT, misconvergence caused by electrons from each of the R (red), G (green), and B (blue) electron guns not correctly hitting each corresponding dot on the screen, in particular, In order to correct the vertical misconvergence, a circuit as shown in Fig. 1 is typically used.

As shown in FIG. 1, the conventional vertical misconvergence correction circuit includes a first vertical deflection coil 1a, a second vertical deflection coil 1b, damping resistors 2 and 3, and a variable resistor 4. As the variable resistor 4 is moved left and right, the distribution of the current flowing through the vertical deflection coils 1a and 1b is changed to change the vertical deflection angle, thereby causing the R and B dot emission on the CRT screen to move up and down. It is characterized in that it is possible to set the variable resistor (4) in which accurate convergence is achieved.

However, in the vertical misconvergence correction circuit as described above, the amount of current flowing through the first vertical deflection coil 1a and the second vertical deflection coil 1b is fixed by setting the variable resistor 4 to a predetermined value. . For example, assuming that the variable resistor 4 is set to a constant value and a large amount of current flows in the first vertical deflection coil 1a when the current flows in the A direction, even when the current flows in the B direction, 1 A large amount of current flows in the reverse direction to the vertical deflection coil 1a (when the current flows in the A direction, the upper portion is scanned from the center of the CRT screen, and when the current flows in the A direction, the lower portion is scanned from the center of the CRT screen. Is assumed). In this case, the deflection angle by the first vertical deflection coil 1a is always large, and the force applied to the electrons acts in the direction toward the center of the screen, whereby the electron gun located on the side of the first vertical deflection coil 1a (Fig. 3). If 12) is a blue electron gun, convergence adjustment is made only toward the blue dot emission always close to the center. When the current flows in the B direction, due to the opposite phenomenon, the convergence adjustment is performed only outside the center of the blue dot light emission. That is, the misconvergence as shown in FIG. 5 can be adjusted. However, in the case of misconvergence as shown in FIG. 6, the vertical convergence is adjusted only to the upper part of the entire CRT screen or the vertical convergence is adjusted only to the lower part for the blue dot emission. Since this is impossible, when the blue dot light emission is below or above the red dot light emission at both the top and bottom of the CRT screen, there is a disadvantage in that accurate convergence adjustment is not performed.

Thus, instead of controlling the normal vertical deflection coils, using a circuit to control the auxiliary vertical deflection coils, vertical convergence can be done either up or down independently of the center of the CRT screen, whether it is top or bottom. To be able to adjust

1 is a conventional circuit diagram for correcting vertical misconvergence.

2 is a circuit diagram for correcting vertical misconvergence according to an embodiment of the present invention.

3 is a diagram illustrating a magnetic field generated in the deflection yoke when the current direction in FIG. 2 is the A direction and the current of the first coil pair is larger.

4 is a diagram showing a magnetic field generated in the deflection yoke when the current direction in FIG. 2 is the A direction and the current of the second coil pair is larger.

FIG. 5 is a diagram illustrating misconvergence in which B (blue) is gathered into the center of the screen rather than R (red) at the top and bottom when an electron gun of a color CRT (Cathode Ray Tube) is scanned and displayed on the screen.

FIG. 6 is a diagram showing misconvergence in which B is lowered from the top and bottom of R when the electron gun of the color CRT is scanned and displayed on the screen.

In order to achieve this technical problem, a deflection yoke capable of correcting vertical convergence of a color CRT screen according to a feature of the present invention is connected in series to generate the same N pole or S pole up and down within the deflection yoke. Magnetic field generating coil circuits each consisting of two pairs of coils; A first diode circuit in which two diodes are connected in opposite directions; A second diode circuit in which two diodes are connected in opposite directions; A first variable resistor for adjusting convergence in one direction from inside to outside from the center of the screen; A second variable resistor connected between the two diodes in the first diode circuit and between the two diodes in the second diode circuit, the second variable resistor for adjusting the convergence in either direction above or below the screen; And a damping resistor connected between a contact between the two pairs of coils, a contact between a movable terminal of a first variable resistor and a movable terminal of a second variable resistor, wherein the magnetic field generating coil circuit comprises: The variable resistor and the first diode circuit are connected in parallel, and the second diode circuit is connected in parallel to the magnetic field generating coil circuit in the reverse direction to the first diode direction.

The color CRT capable of correcting the vertical convergence of the color CRT screen includes: a magnetic field generating coil circuit composed of two pairs of two coils connected in series to generate the same N pole or S pole up and down in the deflection yoke; A first diode circuit in which two diodes are connected in opposite directions; A second diode circuit in which two diodes are connected in opposite directions; A first variable resistor for adjusting convergence in one direction from inside to outside from the center of the screen; A second variable resistor connected between the two diodes in the first diode circuit and between the two diodes in the second diode circuit, the second variable resistor for adjusting the convergence in either direction above or below the screen; And a damping resistor connected between a contact between the two pairs of coils, a contact between a movable terminal of a first variable resistor and a movable terminal of a second variable resistor, wherein the magnetic field generating coil circuit comprises: The variable resistor and the first diode circuit are connected in parallel, and the second diode circuit is connected in parallel to the magnetic field generating coil circuit in the reverse direction to the first diode direction.

In addition, a color display device capable of correcting vertical convergence of a color CRT screen includes a magnetic field generating coil circuit composed of two pairs of two coils connected in series so as to generate the same N pole or S pole up and down in the deflection yoke. ; A first diode circuit in which two diodes are connected in opposite directions; A second diode circuit in which two diodes are connected in opposite directions; A first variable resistor for adjusting convergence in one direction from inside to outside from the center of the screen; A second variable resistor connected between the two diodes in the first diode circuit and between the two diodes in the second diode circuit, the second variable resistor for adjusting the convergence in either direction above or below the screen; And a damping resistor connected between a contact between the two pairs of coils, a contact between a movable terminal of a first variable resistor and a movable terminal of a second variable resistor, wherein the magnetic field generating coil circuit comprises: The variable resistor and the first diode circuit are connected in parallel, and the second diode circuit is connected in parallel to the magnetic field generating coil circuit in the reverse direction to the first diode direction.

Accordingly, when the dot light emitting line of either R or B is adjusted by convergence in one direction inside or outside the horizontal center of the CRT screen by the first variable resistor VR1, the other dot light emitting line converges in the opposite direction. When the dot light emitting line of any one of R and B is convergent adjusted up and down on the horizontal axis of the CRT screen by the second variable resistor VR2, the other dot light emitting line is in the opposite direction. This can be done by adjusting the convergence.

Hereinafter, with reference to the accompanying drawings a detailed configuration and operation of the deflection yoke convergence correction device according to a preferred embodiment that can be easily implemented by those skilled in the art. do.

2 is a circuit diagram of a deflection yoke convergence correction device according to an embodiment of the present invention.

As shown in FIG. 2, the convergence correction circuit according to the embodiment of the present invention includes the magnetic field generating coil circuits CY1 to CY4, the first diode circuits D1 and D2, and the second diode circuits D3 and D4. , The first variable resistor VR1, the second variable resistor VR2, and the damping resistor R1.

The magnetic field generating coil circuits CY1 to CY4 correspond to normal auxiliary deflection coils, and are composed of two pairs of two coils connected in series to generate the same N pole or S pole up and down in the deflection yoke. .

In the first diode circuits D1 and D2, two diodes are connected in series in opposite directions.

In the second diode circuits D3 and D4, two diodes are connected in series in opposite directions.

The first variable resistor VR1 is a variable resistor for adjusting the convergence in one direction from the center of the screen.

The second variable resistor VR2 is connected between two diodes in the first diode circuits D1 and D2 and between two diodes in the second diode circuits D3 and D4. To adjust the convergence.

The damping resistor R1 has a contact between two pairs of vertical deflection coils in the magnetic field generating coil circuits CY1 to CY4, a movable terminal of the first variable resistor VR1 and a movable terminal of the second variable resistor VR2. It is connected between the connected contacts.

The magnetic field generating coil circuits CY1 to CY4, the first variable resistor VR1, and the first diode circuits D1 and D2 are connected in parallel, and the second diode circuits D3 and D4 are connected to each other. The magnetic field generating coil circuits CY1 to CY4 are connected in parallel in the reverse direction to the directions of the first diode circuits D1 and D2.

The operation of the convergence correction circuit according to the embodiment of the present invention having such a structure will be described in more detail.

As described briefly above, in order to adjust the vertical convergence, in the present invention, the first variable resistor VR1 is used to adjust the convergence from the center of the screen to adjust the convergence in the up and down direction of the entire screen. The second variable resistor VR2 is provided.

At this time, as shown in FIG. 2, while the electron gun scans the upper end of the center on the horizontal axis of the color CRT screen, current flows in the A direction, and the movable terminal of the first variable resistor VR1 is set to the right. In this case, the current flowing through the first coil pairs CY1 and CY3 of the magnetic field generating coil circuits CY1 to CY4 is greater than the current flowing through the second coil pair CY4 and CY2, and the result shown in FIG. Since the magnetic fields 13 and 14 are formed in the deflection yoke, the upward force 15 applied to the electrons from the blue electron gun 12 and the downward force 16 to the electrons from the red electron gun 10 are opposite. As a result, the blue dot emission line appears more upward on the screen. Similarly, when the movable terminal of the first variable resistor VR1 is set to the left side, the current flowing through the second coil pair CY4 and CY2 is greater than the current flowing through the first coil pair CY1 and CY3. Since the magnetic fields 20 and 21 in the deflection yoke are formed as shown in FIG. 4, the upward force 23 applied to the electrons from the red electron gun 10 and the downward force applied to the electrons from the blue electron gun 12. (22) is reversed so that the red dot emitting line appears more upward on the screen.

In the above phenomenon, the current flows in the B direction while the electron gun scans the lower end under the center along the horizontal axis of the color CRT screen, and thus the magnetic field is formed inversely, so that the current flowing in the first coil pair CY1 and CY3 flows in the second direction. When larger than the current flowing through the coil pairs CY4 and CY2, a magnetic field is formed in the deflection yoke as opposed to that shown in FIG. 3, and thus, downward force applied to the electrons emitted from the blue electron gun 12 and emitted from the red electron gun 10. The upward force applied to the electrons is reversed so that the blue dot emission line appears further down the screen, and the current flowing through the second coil pair CY4 and CY2 is greater than the current flowing through the first coil pair CY1 and CY3. When the downward force applied to the electrons from the red electron gun 10 and the upward force applied to the electrons from the blue electron gun 12 are reversed, the red dot emission line appears further downward on the screen. It is.

On the other hand, when the movable terminal of the second variable resistor VR2 is set downward while the electron gun scans the upper end centered on the horizontal axis of the color CRT screen, that is, when the current flows in the A direction, the magnetic field is set downward. The current flowing through the first coil pairs CY1 and CY3 of the generating coil circuits CY1 to CY4 is greater than the current flowing through the second coil pairs CY4 and CY2 so that the magnetic field 13 in the deflection yoke is shown in FIG. 3. 14 is formed, the upward force 15 applied to the electrons emitted from the blue electron gun 12 and the downward force 16 applied to the electrons from the red electron gun 10 are reversed, and the blue dot emission line on the screen is reversed. This will make it appear more up. The above phenomenon occurs when the electron gun is scanning the lower end under the center on the horizontal axis of the color CRT screen, that is, when the current flows in the B direction, even if the second variable resistor VR2 is set downward. Since more current flows in (CY4, CY2) and the magnetic field is formed inversely, the downward force applied to the electrons from the red electron gun 10 and the upward force applied to the electrons from the blue electron gun 12 are reversed. The red dot emission lines appear further down on the screen. As a result, when the second variable resistor VR2 is set downward, the red dot emission line appears further down the entire screen.

By the same principle, when the movable terminal of the second variable resistor VR2 is set upward, the blue dot emission line appears further below the screen as opposed to the case where the movable terminal of the second variable resistor VR2 is set downward.

For example, as shown in FIG. 5, when the blue dot light emitting line appears toward the center of the screen rather than the red dot light emitting line, the movable terminal of the first variable resistor VR1 is positioned to the right to the first coil pair CY1 and CY3. When the flowing current is increased, the blue dot light emitting lines move out of the center, and the red dot light emitting lines move inside the center to overlap each other. In addition, when the blue dot emission line appears below the red dot emission line throughout the screen as shown in FIG. 6, the first coil pair is used when scanning the upper end of the screen by moving the movable terminal of the second variable resistor VR2 downward. The current flowing through CY1 and CY3 is increased so that the blue dot light emitting line goes up and the red dot light emitting line goes down so that they overlap each other, and the second coil pair CY4 and CY2 flows even when scanning the bottom of the screen. The current is increased so that the blue dot light emitting line goes up and the red dot light emitting line goes down so as to overlap each other, thereby making convergence adjustment.

As described above, in the convergence correction circuit according to the embodiment of the present invention, when the dot light emitting line of any one of R and B is adjusted by the first variable resistor VR1 in one direction inside and outside on the horizontal axis of the CRT screen, The other dot light emitting line is adjusted for convergence in the opposite direction, and the second variable resistor VR2 adjusts the convergence of either dot R or B in either direction on the horizontal axis of the CRT screen. If the other dot light emitting line is to adjust the convergence in the opposite direction.

The invention is susceptible to various modifications and implementations without departing from the scope of the claims set out below.

In the deflection yoke convergence correction device according to the embodiment of the present invention as described above, the dot emission line is converged to the center of the horizontal axis of the CRT screen by the first variable resistor for controlling the auxiliary vertical deflection coil, The second variable resistor that controls the vertical deflection coil allows the dot emission line to adjust the convergence in the up and down direction on the horizontal axis of the CRT screen. Therefore, it is possible to precisely finely adjust the convergence of the vertical misconvergence in any state, thereby making it clear and clear. A color CRT screen can be displayed.

Claims (3)

The device which can correct the vertical convergence of the color CRT screen, A magnetic field generating coil circuit comprising two pairs of two coils each connected in series to generate the same N pole or S pole up and down in the deflection yoke; A first diode circuit in which two diodes are connected in opposite directions; A second diode circuit in which two diodes are connected in opposite directions; A first variable resistor for adjusting convergence in one direction from inside to outside from the center of the screen; A second variable resistor connected between the two diodes in the first diode circuit and between the two diodes in the second diode circuit, the second variable resistor for adjusting the convergence in either direction above or below the screen; And A damping resistor connected between the contact between the two pairs of coils and the contact to which the movable terminal of the first variable resistor and the movable terminal of the second variable resistor are connected. The magnetic field generating coil circuit, the first variable resistor, and the first diode circuit are connected in parallel, and the second diode circuit is parallel to the magnetic field generating coil circuit in a direction opposite to the direction of the first diode. Connected Deflection yoke characterized in that. The device which can correct the vertical convergence of the color CRT screen, A magnetic field generating coil circuit comprising two pairs of two coils each connected in series to generate the same N pole or S pole up and down in the deflection yoke; A first diode circuit in which two diodes are connected in opposite directions; A second diode circuit in which two diodes are connected in opposite directions; A first variable resistor for adjusting convergence in one direction from inside to outside from the center of the screen; A second variable resistor connected between the two diodes in the first diode circuit and between the two diodes in the second diode circuit, the second variable resistor for adjusting the convergence in either direction above or below the screen; And A damping resistor connected between the contact between the two pairs of coils and the contact to which the movable terminal of the first variable resistor and the movable terminal of the second variable resistor are connected. The magnetic field generating coil circuit, the first variable resistor, and the first diode circuit are connected in parallel, and the second diode circuit is parallel to the magnetic field generating coil circuit in a direction opposite to the direction of the first diode. Connected Color CRT characterized by. The device which can correct the vertical convergence of the color CRT screen, A magnetic field generating coil circuit comprising two pairs of two coils each connected in series to generate the same N pole or S pole up and down in the deflection yoke; A first diode circuit in which two diodes are connected in opposite directions; A second diode circuit in which two diodes are connected in opposite directions; A first variable resistor for adjusting convergence in one direction from inside to outside from the center of the screen; A second variable resistor connected between the two diodes in the first diode circuit and between the two diodes in the second diode circuit, the second variable resistor for adjusting the convergence in either direction above or below the screen; And A damping resistor connected between the contact between the two pairs of coils and the contact to which the movable terminal of the first variable resistor and the movable terminal of the second variable resistor are connected. The magnetic field generating coil circuit, the first variable resistor, and the first diode circuit are connected in parallel, and the second diode circuit is parallel to the magnetic field generating coil circuit in a direction opposite to the direction of the first diode. Connected Color display device characterized in that.