JP3150387B2 - Deflection device for color picture tube and color picture tube device - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a deflecting device for a color picture tube and a color picture tube device, and more particularly to a deflection current in an electron beam arrangement direction in synchronization with a deflection current in a direction perpendicular to the arrangement direction. The present invention relates to a color picture tube deflecting device and a color picture tube device provided with a saturable reactor for changing.

[0002]

2. Description of the Related Art Generally, as shown in FIG. 9, a color picture tube apparatus has an envelope composed of a panel 1 and a funnel 2 joined together. Shadow mask 3 with through holes
And a phosphor screen 4 made of a three-color phosphor layer that emits blue, green, and red light is formed on the inner surface of the panel 1,
The three electron beams BR, BG, and BB emitted from the electron gun 6 disposed in the neck 5 of the funnel 2 are deflected by the magnetic field generated by the deflection yoke 7 mounted on the outside of the funnel 2 to emit the fluorescent light. The body screen 4 is formed so as to display a color image on the phosphor screen 4 by scanning horizontally and vertically. Electron beam BR, BG, BB
As shown in FIG. 10, the deflection yoke 7 deflects the electron beam in a vertical direction and a pair of saddle-type horizontal deflection coils 8 through which a horizontal deflection current flows for deflecting and scanning the electron beam in the horizontal direction. A pair of vertical deflection coils 9 through which a vertical deflection current for scanning flows;
And a separator 10 between the vertical deflection coil 9 and the vertical deflection coil 9. In FIG. 10, the vertical deflection coil 9
Is a pair of upper and lower toroidal deflection coils,
A deflection yoke composed of a pair of left and right saddle type deflection coils is also used.

In such a color picture tube device, an electron gun is an in-line type electron gun which emits three electron beams consisting of a center beam and a pair of side beams arranged in a row in a horizontal direction. A self-convergence type in-line type color picture tube device which self-concentrates three electron beams by using the generated horizontal deflection magnetic field as a pincushion type and the vertical deflection magnetic field as a barrel type non-uniform magnetic field is widely used. . However, in the self-convergence type in-line type color picture tube device, various screen distortions occur based on tube characteristics and tube assembly errors.

One of them is coma aberration generated because the deflection sensitivity to the center beam becomes relatively stronger than the deflection sensitivity to the pair of side beams. That is,
In the self-convergence type in-line type color picture tube device, the rasters 11B and 11R of the pair of side beams BB and BR can be made coincident over the entire screen as shown in FIG. However, due to the difference in deflection sensitivity between the center beam BG and the pair of side beams BB and BR, the center beam BG raster
It is difficult to match 11G with the rasters 11B and 11R of the pair of side beams BB and BR, and coma aberrations indicated by HCR and VCR occur at the horizontal (X-axis) and vertical (Y-axis) ends of the screen.

In a conventional in-line type color picture tube apparatus, this coma aberration is corrected by magnetically coupling the beam emitting end side electrode of the electron gun with the rear magnetic field of the deflection yoke and relatively deflecting the pair of side beams. The correction is made by arranging a magnetic element called a field controller having an effect of making the sensitivity weaker than the deflection sensitivity of the center beam. However, when the horizontal deflection frequency is increased, a convergence shift occurs due to the AC loss of the magnetic element. Therefore, correction using the magnetic field of the deflection yoke itself without using the magnetic element is increasing. In this case, H
CR can be corrected by the horizontal deflection coil because the shift amount is originally small. However, since the correction amount of the VCR is large and it is difficult to correct by the vertical deflection coil, VC
R remained. Therefore, a coil is wound around a pair of U-shaped cores, and an auxiliary coil in which the coil is connected in series to a vertical deflection coil is vertically symmetrically arranged on the electron gun side end (rear end) of the deflection yoke with a horizontal axis interposed therebetween. In addition, a means for correcting by a deflection device configured to generate a pincushion-type magnetic field corresponding to the barrel-type vertical deflection magnetic field of vertical deflection is employed.
Japanese Patent Application Laid-Open No. 63-225462 discloses means for controlling the operation of the auxiliary coil by using a diode so that the VCR can be corrected efficiently over the entire screen.

As another screen distortion, there is a cross miss convergence pattern as shown in FIG. Regarding the correction of such a cross miss convergence pattern, conventionally, Japanese Patent Application Laid-Open No. 57-206184 and Japanese Patent Application Laid-Open No. 2-94791 disclose that a current flowing through a pair of horizontal deflection coils is synchronized with a vertical deflection current. A color picture tube apparatus provided with a saturable reactor that corrects misconvergence by changing the shape of the horizontal deflection magnetic field over time by changing the shape of the horizontal deflection magnetic field over time.

Normally, this saturable reactor is connected to an upper horizontal deflection coil of a pair of upper and lower horizontal deflection coils and is wound around a saturable core.
It comprises an impedance control coil connected to a lower horizontal deflection coil and wound around a saturable core, and a saturation control coil connected to a vertical deflection coil. The magnetic field generated by the saturation control coil over the wound saturable core of the impedance control coil is configured such that one impedance control coil is in the opposite direction to the other,
A static magnetic field is applied to these impedance control coils in advance. FIG. 13 shows the operation principle of the saturable reactor. In FIG. 13A,
H is the external field applied to the saturable core, L is the inductance of the impedance control coil, and the solid line 12 and the broken line 13
Represents the L-H characteristics of the two impedance control coils. Further, Hmag is a static magnetic field, and Hvm is a magnetic field generated by a saturation control coil. Here, the curve 12 shown by a solid line and the curve 13 shown by a broken line are symmetrical about the static magnetic field Hmag because
This is because the magnetic field generated by the saturation control coil applied to the set of impedance control coils is in the opposite direction. The saturation control coil generates a magnetic field Hvm when a vertical deflection current flows, and changes the inductances Lu and Ld of the impedance control coil in synchronization with the vertical deflection by the sum of the static magnetic field Hmag and the magnetic field Hvm. FIG. 13B shows changes in the inductances Lu and Ld on the horizontal axis as vertical deflection currents. Since the amount of cross-misconvergence correction by such a saturable reactor is substantially proportional to the difference between the inductances Lu and Ld of the two impedance control coils, the correction pattern becomes a curve 16 shown in FIG.

A cross miss convergence pattern in a conventional color picture tube apparatus has a pattern represented by FIGS. 12 (a) and 12 (b). However, in recent years, flattening and complicated convergence of a color picture tube device, and addition of a distortion correction mechanism, etc.
A pattern in which the cross-misconvergence amount at the upper and lower ends of the screen is smaller than the cross-misconvergence amount in the upper and lower middle portions as shown in FIG.
There are many patterns in which the polarity of the cross miss convergence at the upper and lower ends of the screen is reversed from the polarity of the upper and lower middle portions.

In the case of the conventional saturable reactor, the amount of correction monotonically increases with respect to the vertical deflection current, so that the cross miss convergence pattern shown in FIGS. 12A and 12B can be corrected, but FIG. ) And (d), the cross-misconvergence patterns were difficult to correct. For this reason, in a color picture tube device equipped with a conventional saturable reactor, improvement in quality cannot be obtained.

[0010]

As described above, some correction can be made to the case where the screen distortion increases from the middle to the upper and lower ends of the screen. However, there is a problem that sufficient correction cannot be performed when the screen distortion in the upper and lower middle portions of the screen is larger than that in the upper and lower ends.

Therefore, Japanese Patent Application Laid-Open No. 63-195935 and
JP-A 1-175150 and JP-A 1-183042 disclose means for configuring a saturation control coil with two coils and controlling one of the coils with a diode, but having a sufficient correction effect. However, there is still a practical problem such as an increase in impedance.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problems, and it is possible to effectively correct the screen distortion at the upper and lower middle portions and the upper and lower ends of the screen, and to design the correction amount with a high degree of freedom. An object of the present invention is to provide a color picture tube deflection device and a color picture tube device.

[0013]

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, the present invention provides a method for generating a magnetic field for deflecting a plurality of electron beams arranged in a line in a first direction in the same direction as the first direction. A first deflecting coil and a second deflecting coil for generating a magnetic field for deflecting in a direction orthogonal to the first direction;
An impedance control coil connected to the deflection coil;
A saturable control coil connected to allow a deflection current flowing through the second deflection coil to flow, and a saturable core around which the impedance control coil is wound. A color picture tube deflector having a saturable reactor that changes differentially in synchronization with a current flowing through the saturable reactor, wherein the saturation control coil of the saturable reactor includes a first saturation control coil and the first saturation control coil.
To generate a magnetic field of opposite polarity to the saturation control coil
The first saturation control coil has at least a resistor connected in series to form a first deflection current system, and the first saturation control coil has a configuration opposite to that of the second saturation control coil with respect to the first deflection current system. A second deflection current system configured with a diode pair connected to the polarity is connected in parallel, so that the deflection current flowing through the second deflection coil can be divided into the first deflection current system and the second deflection current system. And a diode for controlling the generation of a magnetic field of opposite polarity.

Further, an in-line type electron gun for generating three electron beams consisting of a center beam and a pair of side beams arranged in a line in a first direction, and deflecting the three electron beams in the same direction as the first direction. A deflection yoke including a first deflection coil for generating a magnetic field to generate a magnetic field to be deflected and a second deflection coil for generating a magnetic field to be deflected in a direction orthogonal to the first direction; an impedance control coil connected to the first deflection coil; A saturation control coil connected to allow a deflection current flowing through the second deflection coil to flow, and a saturable core around which the impedance control coil is wound, wherein the current flowing through the first deflection coil is changed to the second deflection current. In a color picture tube device provided with a saturable reactor that changes differentially in synchronization with the saturable reactor, the saturation control coil of the saturable reactor has a first saturation. The first saturation control coil comprises a control coil and a second saturation control coil for generating a magnetic field of a polarity opposite to that of the first saturation control coil. Form a system,
The first deflection current system is connected in parallel with a second deflection current system configured with a diode pair connected to the second saturation control coil and having a polarity opposite to that of the second saturation control coil. A color picture tube device characterized in that the current can be divided into a first deflection current system and a second deflection current system, and the generation of a magnetic field of opposite polarity is controlled by a diode.

A first deflection coil for generating a magnetic field for deflecting a plurality of electron beams arranged in a line in the first direction in the same direction as the first direction; and a deflection coil in a direction orthogonal to the first direction. A second deflection coil for generating a magnetic field to be generated, an impedance control coil connected to the first deflection coil, a saturation control coil connected so that a deflection current flowing through the second deflection coil flows, and the impedance control coil. A saturable reactor that is wound and that differentially changes a current flowing through the first deflection coil in synchronization with a current flowing through the second deflection coil; and a saturable reactor that flows through the second deflection coil. The saturable reactor includes two sets of sub-coils for generating an auxiliary magnetic field in synchronization with a current, and further includes a first saturation control coil and a first saturation control coil. And a second saturation control coil for generating a magnetic field of the opposite polarity to the first deflection current system, wherein the first saturation control coil has at least a resistor connected in series to form a first deflection current system. For the system, the second
, And a second deflection current system configured with a pair of diodes connected in reverse polarity to one of the two sets of sub-coils and the one of the two sub-coils, to connect a deflection current flowing through the second deflection coil A deflecting device for a color picture tube, characterized in that a current can be divided into a first deflecting current system and a second deflecting current system, and the generation of a magnetic field of opposite polarity is controlled by a diode.

Further, an in-line type electron gun for generating three electron beams consisting of a center beam and a pair of side beams arranged in a line in a first direction, and deflecting the three electron beams in the same direction as the first direction. A color deflection picture tube including a deflection yoke including a first deflection coil for generating a magnetic field to generate a magnetic field and a second deflection coil for generating a magnetic field to be deflected in a direction orthogonal to the first direction.
An impedance control coil connected to the deflection coil;
A saturation control coil connected to allow a deflection current flowing through the second deflection coil to flow, and a saturable core around which the impedance control coil is wound, wherein the current flowing through the first deflection coil is changed to the second deflection current. A saturable reactor that changes differentially in synchronization with the second deflecting coil, and two sets of sub-coils that generate an auxiliary magnetic field in synchronization with a current flowing through the second deflection coil, and further includes a saturation control coil of the saturable reactor. Comprises a first saturation control coil and a second saturation control coil for generating a magnetic field of opposite polarity to the first saturation control coil, wherein the first saturation control coil has at least a resistor connected in series. To form a first deflection current system, and to the first deflection current system, a coil connected to the second saturation control coil and one of the two sub-coils in a polarity opposite to that of one of the two sub-coils. A second deflecting current system configured with an ode pair is connected in parallel so that the deflecting current flowing in the second deflecting coil can be divided into the first deflecting current system and the second deflecting current system, and have opposite polarities by diodes. A color picture tube device characterized by controlling generation of a magnetic field.

[0017]

The present invention is basically intended for correcting the cross-misconvergence of a pair of side beams among screen distortions, and is connected to a pair of first deflection coils for deflecting an electron beam in the arrangement direction. The inductance of the impedance control coil is changed in synchronization with the deflection in the second direction by the magnetic field generated by the saturation control coil in which the deflection current flowing in the second deflection coil flows, and the differential current is applied between the pair of first deflection coils. Is performed.

At this time, the saturation control coil comprises a first saturation control coil and a second saturation control coil.
Of the saturation control coil is connected at least with a resistor in series to form a first deflection current system.
The second deflection current system configured with the saturation control coil and the diode pair connected in the opposite polarity is in a parallel relationship, and forms a shunt path for the deflection current. Therefore, the deflection current flows through the first deflection current system and does not flow through the second deflection current system until the diode rises. When the diode rises, a deflection current is shunted to the second deflection current system. Also,
Since the second saturation control coil generates a magnetic field having a polarity opposite to that of the magnetic field generated by the first saturation control coil, the saturable core in which the impedance control coil of the saturable reactor is unwound is used. , A magnetic field in the opposite direction to the magnetic field generated by the first saturation control coil is also applied. That is,
The saturable reactor is operated by the first saturation control coil up to the upper and lower middle portion of the screen, and after the diode rises, the shunt ratio and the amount of magnetic field generation as the whole saturation control coil are adjusted by the second saturation control coil. . Therefore, the amount of magnetic field generated by the saturation control coil is appropriately set in synchronization with the deflection current, and a desired cross-misconvergence correction pattern is obtained. Further, according to the present invention, the VCR, which is the coma aberration between the center beam and the side beam at the top and bottom of the screen, is simultaneously corrected based on the following principle.

That is, the VCR is corrected by synchronizing an auxiliary magnetic field in synchronization with a current flowing through a second deflection coil for generating a deflection magnetic field for deflecting a row of electron beams in a second direction perpendicular to the arrangement direction. The correction of the cross-misconvergence of the pair of side beams is performed by the inductance of the impedance control coil connected to the pair of first deflection coils for deflecting the electron beam in the arrangement direction. This is performed by causing a deflection current flowing through the two deflection coils to change in synchronization with the deflection in the second direction with a magnetic field generated by a saturation control coil, thereby generating a differential current between the pair of first deflection coils.

In this case, according to the present invention, the saturation control coil comprises a first saturation control coil and a second saturation control coil, and one of the two sub-coils is provided with a second saturation control coil. And a second deflection current system configured with a diode connected in reverse polarity, and a first deflection current system including a series circuit of a first saturation control coil and a resistor with respect to the second deflection current system. Are connected in parallel. Therefore, almost no current flows in the second deflection current system until the diode rises, so that one of the two subcoils is controlled by the diode in synchronization with the deflection in the direction perpendicular to the electron beam arrangement direction. By that, VC
The correction amount of R can be set freely. Further, since the first deflection current system and the second deflection current system are in a parallel relationship, the deflection current is shunted to the second deflection current system by the rise of the diode, and the current flowing to the first deflection current system reaches a plateau. Become. Since the second saturation control coil is wound so as to generate a magnetic field in a direction opposite to that of the first saturation control coil, when the diode rises, the impedance control coil generates the first saturation control coil. A magnetic field in the opposite direction to the generated magnetic field is also generated. Therefore, since the generated magnetic field is controlled by the rise of the diode as a whole in the saturation control coil of the saturable reactor by the rise of the diode, the correction amount of the cross miss convergence also changes in conjunction with the magnetic field. Thus, by controlling the rise of the diode, the correction of the VCR and the cross-misconvergence is synchronized with the deflection to obtain a desired correction pattern.

[0021]

Embodiments of the present invention will be described below with reference to the drawings.

(Embodiment 1) FIG. 1 is a diagram showing a circuit configuration of a color picture tube deflector according to the present invention. As shown in FIG. 1, the horizontal deflection circuit 20 includes a pair of upper and lower horizontal deflection coils 21, 22 and impedance control coils 24a, 24 connected to the upper horizontal deflection coil 21 and wound around a saturable core 23.
b and the impedance control coils 26a and 26b connected to the lower horizontal deflection coil 22 and wound around the saturable core 25 are connected. The vertical deflection circuit 30 is connected to vertical deflection coils 31 and 32 and two saturation control coils 35a and 35b. Impedance control coils 24a, 24b, 26
a and 26b are wound around the saturable cores 23 and 25, and saturable to differentially change the current flowing through the pair of horizontal deflection coils 21 and 22 in synchronization with the vertical deflection current together with the saturation control coils 35a and 35b. It constitutes a reactor.

As described above, the saturable reactor changes the horizontal deflection current differentially in synchronization with the vertical deflection current, and has one impedance control coil 24a, 24b.
Saturation control coil 35a on the wound saturable core of
The magnetic field generated by 35b is the other impedance control coil
The impedance control coils 24a, 24b, 26b are configured so as to be in opposite directions to 26a, 26b.
A static magnetic field is applied to a and 26b in advance. In addition, 2
The two saturation control coils 35a and 35b have opposite polarities, that is, the magnetic field generated by the second saturation control coil 35b has the opposite polarity to the magnetic field generated by the first saturation control coil 35a. . As an example, the second saturation control coil 35b may be wound coaxially with the first saturation control coil 35a in the opposite direction.

A resistor 40 and a choke coil 41 are connected in series to the first saturation control coil 35a to form a first deflection current system, and a diode pair connected to the second saturation control coil 35b with the polarity reversed. 42 and 43 are connected in series to form a second deflection current system. The first and second deflection current systems are in a parallel relationship, and are configured to split the vertical deflection current. Next, the operation of the present embodiment will be described.

FIG. 2 shows a circuit configuration on the side of the vertical deflection circuit 30 in FIG. In this embodiment, the deflection device is:
Mainly comprising a saturable reactor, a vertical deflection current Iv flowing through the vertical deflection coil is divided into a current I ₂ flowing current I ₁ flowing through the first deflection current system and the second deflection current system, flowing through the second series circuit the current I ₂ is to control the diode pair 42, 43.

The relationship between the vertical deflection current Iv and the correction amount will be described with reference to FIG. FIG. 3A shows the vertical deflection current Iv and the currents I ₁ and I ₁ flowing through the first and second deflection current systems.
It shows the relationship of I ₂ . Diode current I ₂ does not flow until the rise, suddenly increases after rises. At this time, since the first deflection current system and the second deflection current system are in a parallel relationship, the current I ₁ flowing through the first deflection current system decreases by the amount of the deflection current divided into the second deflection current system.

Further, since the second saturation control coil 35b of the second series circuit is configured to generate a magnetic field of the opposite polarity to the first saturation control coil 35a, after the diode rises, as shown in FIG. 3 (b), the magnetic field H ₂ generated by the second saturation control coil increases rapidly. At this time current flowing through the first deflection current system is reduced, so that the magnetic field H ₁ in which the first saturation control coil for generating a plateau. As a result, the magnetic field of the saturation control coil as a whole decreases as compared with the magnetic field of only the first saturation control coil when the diode rises, and the external field applied to the impedance control coil tends to decrease. As described above, the saturable reactor controls the horizontal deflection current by changing the inductance of the impedance control coil by the magnetic field generated by the saturation control coil. Therefore, by controlling the magnetic field generated by the saturation control coil, the correction amount of the cross miss convergence can be changed between the middle portion of the screen and the upper and lower ends.

The cross miss convergence correction pattern can be variously selected by adjusting the magnetic field generated by the first and second saturation control coils and the rising point of the diode. That is, the slope of the correction amount curve as shown in FIG. 12C is determined by the magnitude of the magnetic field generated by the first saturation control coil, the screen position for obtaining the maximum correction amount is determined by the rising position of the diode, and The inclination of the correction amount curve can be adjusted by the shunt ratio of the first and second deflection current systems or the magnetic field generated by the second saturation control coil. The generated magnetic field can be adjusted by adjusting the shunt ratio and the number of turns of the saturation control coil.

In this embodiment, the choke coil is provided.
It adjusts the induced electromotive force generated in the closed circuit formed by the deflection current system. That is, by using the induced electromotive force generated by the choke coil, the total sum of the induced electromotive forces generated by the other coils in the closed circuit is adjusted, and the transient induced current at the start of scanning is reduced.

In this embodiment, although the configuration of the saturable reactor, particularly the horizontal deflection circuit side, is not described in detail, the configuration of the saturation control coil connected to the vertical deflection coil may be as shown in this embodiment. Any conventional type can be used.

In FIGS. 1 and 2, the saturation control coils 35a and 35b are connected to the vertical deflection coils 31 and 32, but the vertical deflection current may flow directly without being connected to the vertical deflection coils. .

As described above, according to the present embodiment,
Set the saturation control coil of the saturable reactor to
By dividing these into a parallel relationship and controlling the saturation control coil in the opposite direction with a diode, various mis-convergence misalignment patterns can be corrected, and the design thereof can be easily performed. It has an excellent effect.

(Embodiment 2) Embodiment 1 is concerned with a color picture tube deflecting device. Next, an embodiment of a color picture tube device according to the present invention will be described. The overall configuration of the color picture tube device is the same as that shown in FIG. 6 and has an envelope composed of a panel 1 and a funnel 2 joined together. A phosphor screen 4 made of a three-color phosphor layer that emits blue, green, and red light is formed on the inner surface of the panel 1 so as to face the shadow mask 3 in which the through holes are formed, and is disposed in the neck 5 of the funnel 2. The three electron beams BR, BG, and BB emitted from the provided electron gun 6 are deflected by a magnetic field generated by a deflection yoke 7 mounted outside the funnel 2 so that the phosphor screen 4 is horizontally and vertically. The phosphor screen 4 is formed into a structure for displaying a color image by scanning. As described above, the electron beams BR, BG, BB
As shown in FIG. 7, the deflection yoke 7 for deflecting
A pair of saddle-type horizontal deflection coils 8 through which a horizontal deflection current flows to deflect and scan the electron beam in the horizontal direction; and a pair of vertical deflection coils 9 through which a vertical deflection current flows to deflect and scan the electron beam in the vertical direction. It mainly comprises a separator 10 between the horizontal deflection coil 8 and the vertical deflection coil 9. In FIG. 7, the vertical deflection coil 9 is a pair of upper and lower toroidal deflection coils, but a deflection yoke composed of a pair of left and right saddle type deflection coils is also used. In general, the electron gun is an in-line type electron gun that emits three electron beams consisting of a center beam and a pair of side beams arranged in a line in the horizontal direction. On the other hand, the horizontal deflection magnetic field generated by the deflection yoke is pin-cushioned. A self-convergence type in-line type color picture tube device in which three electron beams are self-concentrated by the non-uniform magnetic field having a vertical deflection magnetic field as a barrel type. The deflecting device in the present embodiment is shown in FIG.
Has the same configuration as that shown in FIG. 1 and is in circuit form as shown in FIG.

In the embodiment of FIG. 1, the second deflection current system including the second saturation control coil and the diode pair is connected in parallel to the first deflection current system including the first saturation control coil. . This is because the current flowing in the first saturation control coil shunts to the diode side and reaches a plateau, and the second saturation control coil generates a magnetic field in the opposite direction to the magnetic field generated by the first saturation control coil. This is for effectively performing the reversing action.

(Embodiment 3) In addition to the cross-misconvergence, the above-mentioned coma represented by the VCR also appears depending on the color picture tube device. Therefore, an embodiment for solving this will be described next.

FIG. 4 is a perspective view showing another embodiment of the color picture tube deflector according to the present invention. The deflection device 50
As shown in FIG. 4, a first deflecting coil (not shown) mainly deflects the electron beams arranged in a row in the arrangement direction, and a second deflection coil deflects the electron beams in a direction perpendicular to the arrangement direction. A coil 51, a separator 52 located between the deflection coils, and two sets of sub-coils 54a, 54b, 55a,
55b. The sub-coils 54a and 54b are wound around a pair of U-shaped cores 56a and 56b arranged substantially symmetrically with respect to the arrangement axis (X-axis) of the electron beams.
b is wound around a pair of rod-shaped cores 57a and 57b arranged on the arrangement axis (X-axis) of the electron beam. Although not shown, the first deflection coil and the second deflection coil are:
It is connected to a saturable reactor that changes the current on the output side differentially in synchronization with the current on the input side using the change in inductance of the coil due to the magnetic field. Normally, the electron beams are arranged in a row in the horizontal direction, the first deflection coil is a horizontal deflection coil, and the second deflection coil is a vertical deflection coil.

The circuit configuration of the deflection device shown in FIG. 4 will be described with reference to FIG. As shown in FIG. 5, the horizontal deflection circuit 60 includes a pair of upper and lower horizontal deflection coils 61, 62, and impedance control coils 64a, 64b connected to the upper horizontal deflection coil 61 and wound around a saturable core 63. Lower horizontal deflection coil 62
And the impedance control coils 66a and 66b wound around the saturable core 35. The vertical deflection circuit 70 includes vertical deflection coils 71 and 72 and a first sub coil 73 connected in series to the vertical deflection coils 71 and 72.
a, 73b and the second sub-coils 74a, 74b are connected, and two more saturation control coils 75a, 75
b is connected. Impedance control coil 64a,
64b, 66a, 66b are wound around the saturable cores 63, 65, and together with the saturation control coils 75a, 75b, differentially change the current flowing through the pair of horizontal deflection coils 61, 62 in synchronization with the vertical deflection current. To form a saturable reactor.

As described above, the saturable reactor changes the horizontal deflection current differentially in synchronization with the vertical deflection current, and has one impedance control coil 64a, 64b.
Saturation control coil 75 on the wound saturable core 63
The magnetic field generated by the impedance control coils 64a, 64b, and 66a is configured so that the magnetic field generated by the impedance control coils 64a, 64b, and 66a is opposite to that of the wound saturable core 65 of the other impedance control coils 66a and 66b. , 66b are preliminarily applied with a static magnetic field. Further, the two saturation control coils 75a and 75b have opposite polarities, that is, the magnetic field generated by the second saturation control coil 75b has the opposite polarity to the magnetic field generated by the first saturation control coil 75a. Has become. As an example, the second saturation control coil 47b may be coaxially wound around the first saturation control coil 75a in the opposite direction.

A resistor 80 and a choke coil 81 are connected in series to the first saturation control coil 75a to form a first deflection current system.
a, 73b, 74a, 74b, one set of sub-coils 74a,
A second deflection current system including a pair of diodes 91 and 92 connected in reverse polarity to the second saturation control coil 75b and the second saturation control coil 75b is connected in parallel. Next, the operation of the present invention will be described.

FIG. 6 shows a circuit configuration on the side of the vertical deflection circuit 70 in FIG. In this embodiment, the deflecting device mainly includes a saturable reactor and a sub coil, and the vertical deflection coils 71 and 72 and one set 73 of the two sets of sub coils are provided.
a, the vertical deflection current Iv flowing through the 73b, the current I ₁₀ flowing through the first deflection current system DC1 comprising a series circuit of a first saturation control coil 75a and the resistor 80, a pair of the two pairs of sub-coils 74a, divided into 74b and the current I ₂₀ flowing through the second deflection current system DC2 configured with a second saturation control coil 75b and the polarity opposite to the to connected diodes pair 91 and 92,
The current flowing through the second deflection current system DC2 is supplied to diodes 91 and 92.
It is controlled by

The relationship between the vertical deflection current and the correction amount will be described with reference to FIG. FIG. 7A shows the vertical deflection current Iv.
And the currents I ₁₀ and I ₂₀ flowing through the first and second deflection current systems. Diode until rises, the current I ₂₀ does not flow, it is rapidly increased after rises.
Since one set of sub-coils of the two sets of sub-coils is connected to the first deflection current system, as shown in FIG. 7B, after the diode rises, correction B by the sub-coils is applied. The VCR can be corrected so that the shift amount increases toward the upper end of the screen. That is, the deflection current Iv flows through the first deflection current system DC1 to the point where the diode rises, for example, to the middle of the screen, due to the pincushion-type magnetic field generated by the sub-coils 73a and 73b wound around the pair of U-shaped cores. Only VCR correction A. The VCR correction operation by the pincushion magnetic field is based on the same principle as the conventional one. The diode rises from the screen middle to the upper and lower ends, and the second deflection current system D
When the deflection current is also diverted to C2, correction B due to the barrel-type magnetic field generated by the sub-coils 74a and 74b wound around the pair of rod-shaped cores is also applied. The principle of the VCR correction using the barrel magnetic field is the same as that of the conventional one.

Since the first deflecting current system DC1 and the second deflecting current system DC2 are in a parallel relationship, the current I ₂ of the first deflecting current system peaks or decreases with the shunt to the second deflecting current system due to the rise of the diode. Decrease. Since the second saturation control coil 75b is configured to generate a magnetic field of opposite polarity to the first saturation control coil 75a, after the diode rises, as shown in FIG. The magnetic field Hv2 generated by the second saturation control coil 75b sharply increases. Therefore, when the diode rises, the deflection current becomes the second
The current is shunted to the deflection current system, and the second saturation control coil generates a magnetic field of the opposite polarity. Further, since the current flowing through the first deflection current system decreases, the magnetic field generated by the first saturation control coil reaches a plateau. As a result, the magnetic field of the saturation control coil as a whole decreases as compared with the magnetic field of only the first saturation control coil when the diode rises, and the external field applied to the impedance control coil tends to decrease. The saturable reactor uses the change in inductance due to an external field applied to the impedance control coil, and the magnetic field generated by the saturation control coil is applied to a pair of upper and lower horizontal deflection coils with the static magnetic field applied beforehand as the center. This is a magnetic field for increasing or decreasing the inductance of the connected impedance control coil. Therefore,
The correction amount of the cross miss convergence can be changed between the middle part of the screen and the upper and lower ends.

The correction pattern of the cross miss convergence can be variously selected by adjusting the magnetic field generated by the first and second saturation control coils and the rising point of the diode. That is, the slope of the correction amount curve as shown in FIG. 13C is determined by the magnitude of the magnetic field generated by the first saturation control coil, the screen position for obtaining the maximum correction amount is determined by the rising position of the diode, and The inclination of the correction amount curve can be adjusted by the shunt ratio of the first and second deflection current systems or the magnetic field generated by the second saturation control coil. The generated magnetic field can be adjusted by adjusting the shunt ratio and the number of turns of the saturation control coil.

In this embodiment, the choke coil is provided.
It adjusts the induced electromotive force generated in the closed circuit formed by the deflection current system. That is, by using the induced electromotive force generated by the choke coil, the total sum of the induced electromotive forces generated by the other coils in the closed circuit is adjusted, and the transient induced current at the start of scanning is reduced.

In this embodiment, although the configuration of the saturable reactor, especially the horizontal deflection circuit side, is not described in detail, the configuration of the saturation control coil connected to the vertical deflection coil is as shown in this embodiment. If it is
Any conventional type can be used.

Further, in this embodiment, with respect to the VCR correction, a positive correction is performed by one set of subcoils up to the middle of the screen among the two sets of subcoils, and another set of the other set from the middle to the upper and lower ends. Although the description has been given of the case where the positive correction by the sub-coil is applied, the magnetic field generated by the two sets of sub-coils may be set according to the VCR pattern. It can also be used to reduce the volume.

In FIGS. 5 and 6, the saturation control coil and the sub-coil are connected to the vertical deflection coil. However, the deflection current may flow directly without being connected to the vertical deflection coil.

As described above, according to the present embodiment,
The sub-coil for performing VCR correction is composed of two sets of sub-coils, and the saturation control coil of the saturable reactor is divided into two.
By controlling one set of sub-coils of the set of sub-coils and one of two of the saturation control coils by a diode, it is possible to simultaneously correct various misalignment patterns of VCR and cross-misconvergence. It has an excellent effect that it can be easily performed.

(Embodiment 4) Next, another embodiment of the present invention will be described. In the above-described third embodiment, the configuration in which the two sets of sub-coils are wound around different cores is shown.
It is also possible to wind around the same core. FIG. 8 shows a circuit configuration when wound around the same core. In the figure, the same numbers represent the same as in FIG. In this embodiment, two sets of sub-coils are wound around a pair of U-shaped cores, VCR correction is performed by a pincushion magnetic field generated by one set of sub-coils before the diode rises, and another set of coils is made after the diode rises. The configuration is such that a pincushion magnetic field is applied by a sub coil. The connection states of the sub coil, the saturation control coil, the diode, the resistor, and the like connected to the vertical deflection circuit are the same as those shown in FIG.
The operating principle is also as described in the third embodiment.

(Embodiment 5) The above Embodiments 4 and 5
Are both about a color picture tube deflection device, and then
An embodiment of a color picture tube device according to the present invention will be described. The overall configuration of the color picture tube device is the same as that shown in FIG. 6 and has an envelope composed of a panel 1 and a funnel 2 joined together. A phosphor screen 4 made of a three-color phosphor layer that emits blue, green, and red light is formed on the inner surface of the panel 1 so as to face the shadow mask 3 in which the through holes are formed, and is disposed in the neck 5 of the funnel 2. The three electron beams BR, BG, and BB emitted from the electron gun 6 are
Is deflected by a magnetic field generated by a deflection yoke 7 mounted on the outside of the device, and scans the phosphor screen 4 horizontally and vertically to form a structure for displaying a color image on the phosphor screen 4. I have. As described above, the deflection yoke 7 for deflecting the electron beams BR, BG, and BB usually has a pair of saddle-type horizontal halves in which a horizontal deflection current for deflecting and scanning the electron beam in the horizontal direction flows, as shown in FIG. A deflection coil 8, a pair of vertical deflection coils 9 through which a vertical deflection current for deflecting and scanning an electron beam in a vertical direction flows, and a separator between the horizontal deflection coil 8 and the vertical deflection coil 9.
It mainly consists of ten. In FIG. 7, the vertical deflection coil 9 is a pair of upper and lower toroidal deflection coils, but a deflection yoke composed of a pair of left and right saddle type deflection coils is also used. In general, the electron gun is an in-line type electron gun that emits three electron beams consisting of a center beam and a pair of side beams arranged in a line in the horizontal direction. On the other hand, the horizontal deflection magnetic field generated by the deflection yoke is pin-cushioned. A self-convergence type in-line type color picture tube device in which three electron beams are self-concentrated by the non-uniform magnetic field having a vertical deflection magnetic field as a barrel type.

Further, the deflecting device in this embodiment is shown in FIG.
And the circuit is as shown in FIG. 5 or FIG. Therefore, the detailed configuration and operation are the same as those of the above-described embodiment, and the VCR and the cross miss convergence can be corrected at the same time. At this time, the correction pattern is set by the rising point of the diode and the first and second deflection current systems. It can be adjusted by the split ratio, the number of turns of the first and second saturation control coils, and the like.

[0052]

As described above, according to the present invention,
The saturation control coil that constitutes the saturable reactor is composed of two coils in the forward and reverse directions that are in a parallel relationship, and by controlling the saturation control coil in the opposite direction with a diode, the screen distortion in the upper and lower middle part of the screen is reduced. Even in the case where the screen distortion is larger than the upper and lower ends, it can be effectively corrected. Further, a desired correction pattern can be obtained by controlling the rising of the diode and the shunt ratio of the deflection current.

[Brief description of the drawings]

FIG. 1 is a circuit diagram showing an embodiment of the present invention.

FIG. 2 is a diagram showing a main part of a circuit configuration of the present invention.

FIG. 3 is a diagram illustrating an operation in the circuit configuration of FIG. 2;

FIG. 4 is a schematic perspective view showing another embodiment of the present invention.

FIG. 5 is a schematic circuit diagram showing a circuit configuration of the embodiment shown in FIG.

FIG. 6 is a diagram showing a main part of the circuit configuration shown in FIG. 5;

FIG. 7 is a diagram illustrating an operation in the circuit configuration of FIG. 6;

FIG. 8 is a schematic circuit diagram showing a circuit configuration of another embodiment of the present invention.

FIG. 9 is a cross-sectional view illustrating a configuration of a color picture tube device.

FIG. 10 is a schematic diagram illustrating a configuration of a deflection device in FIG. 10;

FIG. 11 is a diagram showing coma aberration appearing on a screen of a conventional color picture tube device.

FIG. 12 is a diagram illustrating a cross-misconvergence state of a pair of side beams appearing on a screen in a conventional color picture tube device.

FIG. 13 is a diagram illustrating the operation principle of a saturable reactor used in a conventional deflection device or color picture tube device.

[Explanation of symbols]

20, 60 horizontal deflection circuit 30, 70 vertical deflection circuit 21, 22, 61, 62 horizontal deflection coil 31, 32, 71, 72 vertical deflection coil 24a, 24b, 26a, 26b, 64a, 64b, 66a, 66b Impedance control coil 35a, 75a First saturation control coil 35b, 75b Second saturation control coil 23, 25, 63, 65 Saturable core 40, 80 Resistance 41, 42, 91, 92 Diode 73a, 73b, 74a, 74b ... sub coil

──────────────────────────────────────────────────続 き Continued on the front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) H01J 29/76 H01J 29/96 H04N 9/28

Claims (4)

(57) [Claims] 1. A first deflection coil for generating a magnetic field for deflecting a plurality of electron beams arranged in a line in a first direction in the same direction as the first direction, and deflecting in a direction orthogonal to the first direction. A second deflecting coil for generating a magnetic field to be generated, an impedance control coil connected to at least the first deflecting coil, a saturation control coil connected so that a deflecting current flowing in the second deflecting coil flows, and the impedance control coil And a saturable core around which the current flowing through the first deflection coil is differentially changed in synchronization with the current flowing through the second deflection coil. The saturation control coil of the saturable reactor includes a first saturation control coil and a second saturation control coil that generates a magnetic field of opposite polarity to the first saturation control coil. And a first saturation control coil having at least a resistor connected in series to form a first deflection current system, and connected to the first deflection current system in a polarity opposite to that of the second saturation control coil. And a second deflection current system configured together with the pair of diodes is connected in parallel. 2. An in-line type electron gun for generating three electron beams consisting of a center beam and a pair of side beams arranged in a line in a first direction, and deflecting the three electron beams in the same direction as the first direction. A deflection yoke including a first deflection coil for generating a magnetic field that generates a deflection magnetic field and a second deflection coil for generating a magnetic field that deflects in a direction orthogonal to the first direction; and an impedance control coil connected to at least the first deflection coil. A saturation control coil connected to allow a deflection current flowing through the second deflection coil to flow, and a saturable core around which the impedance control coil is wound. In a color picture tube device provided with a saturable reactor that changes differentially in synchronization with a current, the saturation control coil of the saturable reactor includes And a second saturation control coil for generating a magnetic field having a polarity opposite to that of the first saturation control coil. The first saturation control coil has at least a resistor connected in series to the first saturation control coil. A deflection current system is provided, and a second deflection current system configured with a diode pair connected to the second saturation control coil and having the opposite polarity is connected in parallel to the first deflection current system. Color picture tube device. 3. A first deflection coil for generating a magnetic field for deflecting a plurality of electron beams arranged in a line in a first direction in the same direction as the first direction, and deflecting in a direction orthogonal to the first direction. A second deflecting coil for generating a magnetic field to be generated, an impedance control coil connected to at least the first deflecting coil, a saturation control coil connected so that a deflecting current flowing in the second deflecting coil flows, and the impedance control coil And a saturable reactor that is wound around the first deflecting coil and changes the current flowing through the first deflecting coil differentially in synchronization with the current flowing through the second deflecting coil. The saturable reactor further includes two sets of sub-coils that generate an auxiliary magnetic field in synchronization with a flowing current.
And a second saturation control coil for generating a magnetic field having a polarity opposite to that of the first saturation control coil. The first saturation control coil has at least a resistor connected in series to the first saturation control coil. A second deflection control system is provided with a second saturation control coil and a pair of sub-coils of the two sets of sub-coils and a diode pair connected to the opposite polarity with respect to the first deflection current system. A deflection device for a color picture tube, wherein deflection current systems are connected in parallel. 4. An in-line type electron gun for generating three electron beams consisting of a center beam and a pair of side beams arranged in a line in a first direction, and deflecting the three electron beams in the same direction as the first direction. A color picture tube device comprising: a deflection yoke including a first deflection coil for generating a magnetic field to generate a magnetic field and a second deflection coil for generating a magnetic field to be deflected in a direction orthogonal to the first direction; Impedance control coil, a saturation control coil connected so that a deflection current flowing through the second deflection coil flows, and a saturable core around which the impedance control coil is wound, and flows into the first deflection coil. A saturable reactor for changing a current differentially in synchronization with the second deflection current; and a saturable reactor for synchronizing with a current flowing through the second deflection coil. It has two sets of sub-coils for generating a magnetic field, further, saturation control coil of the saturable reactor, first
And a second saturation control coil for generating a magnetic field having a polarity opposite to that of the first saturation control coil. The first saturation control coil has at least a resistor connected in series to the first saturation control coil. A second deflection control system is provided with a second saturation control coil and a pair of sub-coils of the two sets of sub-coils and a diode pair connected to the opposite polarity with respect to the first deflection current system. A color picture tube device comprising a deflection current system connected in parallel.