JP2714058B2 - Deflection device for color picture tube - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Field of Industrial Application) The present invention relates to a deflection device for a color picture tube.

(Prior Art) In an in-line type color picture tube having an in-line type electron gun in which electron guns for emitting electron beams in a horizontal direction of a screen are arranged, particularly in an in-line type color display tube, a horizontal deflection magnetic field is pincushioned. It is well known that by using a magnetic field and a vertical deflection magnetic field as barrel magnetic fields, self-convergence in which three electron beams from an electron gun are concentrated on a screen is possible. However, in practice, complete self-convergence cannot be realized because of inversion cross-misconvergence. The reversal cross miss convergence means that red (R), green (G),
An array of electron guns for emitting electron beams for emitting respective colors of blue (B) is arranged from the right side as viewed from the screen side, from R, G,
In the case of B, as shown in FIG. 8, it means that a misconvergence of a positive cross occurs in a middle portion in the vertical direction (V axis) and a reverse cross occurs in a peripheral portion. When the cross-misconvergence amount in FIG. 8 is viewed in the vertical direction, the misconvergence is inverted at the peripheral portion of the screen as shown in FIG. This phenomenon is mainly due to the deviation of the position of the deflection center between the horizontal deflection coil and the vertical deflection coil, and cannot be corrected even by changing the characteristics of the pincushion magnetic field and the barrel magnetic field. , Reference [SST deflection yoke for in-line high-definition color tube] (Iwasaki et al. Television Society Technical Report ED619). This reversal cross-misconvergence amount is a so-called flat face in which the screen is flat, and the larger the screen size is, the larger it becomes.

This inversion cross-misconvergence is difficult to correct even in a deflection device in which the horizontal deflection coil is composed of a saddle-type coil and the vertical deflection coil is connected in series with each other. It is one of the problems.

On the other hand, recent color display tube deflection devices often add a modulator that dynamically adjusts the cross miss convergence according to the deflection angle in order to correct the above-mentioned inverted cross miss convergence. Adding this modulator results in impedance loss of the vertical deflection coil, that is, deflection power loss, and is not practical. In particular, in the case of a recent coma-free deflecting device, a sub-coil for generating a coma-free magnetic field is added in series with the vertical deflection coil, so that the impedance loss is further increased, which is further disadvantageous.

In addition to the above-mentioned inverted cross-misconvergence, there is an inverted vertical coma error (referred to as VCR) which is a higher-order convergence error. This is because the green raster (G) is wider (the VCR is positive) than the red and blue rasters (R) and (B) in the middle part in the vertical direction (V axis) as shown in FIG. At the peripheral portion in the vertical direction, misconvergence of narrow (negative VCR) occurs in the green raster (G) compared to the red and blue rasters (R) and (B). This convergence pattern is called an inverted VCR. When the VCR in FIG. 10 is viewed in the vertical direction, it becomes as shown in FIG. This inverted VCR is
The same 15-inch flat face tube as above, 0.1mm ~
It is about 0.15 mm. Similar to the above-described inverted cross-misconvergence, the inverted VCR is difficult to correct even in a deflection device having a vertical deflection coil composed of a saddle type and a toroidal type coil connected in series.

(Problems to be Solved by the Invention) As described above, the horizontal deflection coil including the conventional saddle type coil and the vertical deflection coil including the saddle type vertical deflection coil and the toroidal type vertical deflection coil connected in series with each other. In the color picture tube deflector thus constructed, inversion cross-misconvergence and inversion VCR occur, and complete convergence cannot be obtained, and the modulator that corrects these misconvergence involves a disadvantage that power loss is involved.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a color picture tube deflecting device capable of correcting an inverted cross-misconvergence and an inverted VCR without using a modulator without inconvenience such as deflection power loss, and obtaining good convergence characteristics.

[Means for Solving the Problems] The present invention relates to a horizontal deflection coil composed of a saddle type coil, and a vertical deflection coil composed of a saddle type vertical deflection coil and a toroidal type vertical deflection coil connected in series with each other. Wherein the intensity of the barrel magnetic field generated from the toroidal type vertical deflection coil is greater than the intensity of the barrel magnetic field generated from the saddle type vertical deflection coil, and the magnetic field of the barrel magnetic field from both vertical deflection coils is provided. A non-linear current control element connected in parallel and antiparallel to the toroidal vertical deflection coil in the same direction is connected to the toroidal type vertical deflection coil.

The present invention also provides a color picture tube deflector having a horizontal deflection coil comprising a saddle type coil and a vertical deflection coil comprising a saddle type vertical deflection coil and a toroidal type vertical deflection coil connected in series with each other. The strength of the barrel magnetic field generated from the vertical deflection coil is larger than the strength of the barrel magnetic field generated from the saddle type vertical deflection coil, and the directions of the magnetic fields of the barrel magnetic fields from both vertical deflection coils are reversed. A non-linear current control element connected in series and anti-parallel is connected in series, and a resistor is connected in parallel to the toroidal vertical deflection coil and the non-linear current control element. This is a deflection device for a color picture tube.

Further, the present invention provides a deflection apparatus for a color picture tube having a horizontal deflection coil composed of a saddle type coil and a vertical deflection coil composed of a saddle type vertical deflection coil and a toroidal type vertical deflection coil connected in series with each other.
The toroidal vertical deflection coil generates a pincushion magnetic field, the saddle type vertical deflection coil generates a barrel magnetic field, and sets the magnetic field directions of the magnetic fields from both vertical deflection coils in the same direction, and is connected in series with the toroidal type vertical deflection coil. A non-linear current control element connected in anti-parallel to the toroidal vertical deflection coil and a non-linear current control element, and a resistor connected in parallel to the non-linear current control element. This is a tube deflection device.

(Operation) In the color picture tube deflecting device of the present invention, the deflection magnetic field from the vertical deflection coil as a whole has a strong barrel magnetic field strength in the vertical middle part of the screen.
Alternatively, by changing the magnetic field generated by the toroidal type vertical deflection coil constituting the vertical deflection coil in a non-linear manner so that the strength of the barrel becomes weaker at the peripheral portion of the screen, that is, the strength of the pincushion magnetic field becomes stronger. , The inverted cross-misconvergence and the inverted VCR can be corrected simultaneously.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 2 is a perspective view showing a deflection device for a color picture tube according to the present invention. The deflecting device (1) is made of a plastic separator (2), incorporated inside the separator (2), and arranged outside a horizontal deflecting coil (not shown) composed of a saddle type coil (not shown) and the separator (2). A vertical deflection coil (3). This vertical deflection coil (3) is incorporated between the core (4) and the toroidal vertical deflection coil (5) wound directly around the core (4) of the deflection device (1). It is composed of a saddle type vertical deflection coil (6). The toroidal type vertical deflection coil (5) and the saddle type vertical deflection coil (6) are connected in series so that the directions of the generated magnetic fields are the same as shown in the connection diagram of FIG. At the same time, a diode (7) in which the toroidal vertical deflection coil (5) is connected in anti-parallel with the parallel is connected.

In this vertical deflection coil (3), the main deflection coil for generating a magnetic field for deflecting the electron beam in the vertical direction is a saddle type vertical deflection coil (6), and the toroidal type vertical deflection coil (5) serves as an auxiliary coil. Fulfill. That is, as shown in FIG. 3, the magnetic field strength H ₂ on the tube axis (Z) is the magnetic field strength H ₀ of the saddle type vertical deflection coil shown by the curve (A) and the toroidal vertical deflection coil shown by the curve (B). greater than the magnetic field strength H _0. Further, the magnetic fields generated by these toroidal type and saddle type vertical deflection coils are both barrel magnetic fields, and as shown in FIG. 4, the barrel magnetic field strength by the toroidal type coil (5) of the curve (C) is changed to the curve ( D)
Larger than that of the saddle type vertical deflection coil (6). When the relationship between FIG. 3 and FIG. 4 is expressed by equations, the equations (1) and (2) are obtained. That is, assuming that the vertical deflection magnetic field is H _X = H ₀ + H ₂ · Z ² (Z is the distance on the tube axis), H ₀ (saddle)> H ₀ (toroidal)... (1) H ₂ (toroidal) < H ₂ (saddle) <0 (2)

The operation of the deflection device (1) will be described. First,
The principle of the correction of the inverted cross-misconvergence in the present invention will be described. The cause of the reversal misconvergence shown in FIGS. 8 and 9 is that, when considering the vertical deflection magnetic field, the barrel magnetic field is weak at the vertical middle portion of the screen and the barrel magnetic field is too strong at the peripheral portion of the screen. . That is, in order to correct the reversal cross miss convergence, the strength of the barrel magnetic field is increased at the vertical middle portion of the screen or the strength of the barrel magnetic field at the peripheral portion of the screen is reduced. That is, the pincushion magnetic field may be increased. Also, the correction of the inverted VCR shown in FIGS. 10 and 11 can be performed with the exactly same magnetic field as in the case of correcting the inverted cross-misconvergence.

Based on such a principle, in the present embodiment, when the electron beam scans the middle part of the screen in the vertical direction, the diode (7) becomes inactive and the vertical deflection current is reduced. From the vertical deflection coil (6) to the toroidal vertical deflection coil (5). But,
In the vertical peripheral portion of the screen, the diode (7) is activated, so that no vertical deflection current flows through the toroidal vertical deflection coil (5). For this reason, the strong barrel magnetic field generated from the toroidal type vertical deflection coil (5) disappears in the peripheral portion in the vertical direction, and as a result, the pincushion magnetic field is strengthened. Therefore, as described in the principle description, the inverted cross-misconvergence and the inverted VCR can be corrected. Inversion cross miss convergence, which was 0.2 to 0.3 mm when using the conventional deflection device, is now 0.05 mm, and 0.1 to 0.15 mm inversion VCR.
Has been improved to 0.05 mm.

Next, another embodiment of the present invention will be described. Fifth
The figure is a connection diagram showing a vertical deflection coil according to another embodiment. This vertical deflection coil (11) is connected in series with the saddle type vertical deflection coil (12) so that the direction of the generated magnetic field is opposite to that of the saddle type vertical deflection coil (12). Connected toroidal vertical deflection coil (13), this toroidal vertical deflection coil (13)
Anti-parallel connected diodes connected in series with (14)
And a resistor (15) connected in parallel to a series circuit of a toroidal type vertical deflection coil (13) and a diode (14). The resistor (15) also controls the rising characteristics of the diode (14).

In the vertical deflection coil (11) having such a configuration, in the vertical middle portion where the diode (14) is in a non-operating state, the vertical deflection current passes through the resistor (15) from the saddle type vertical deflection coil (12). Flows. However, in the peripheral portion in the vertical direction, since the diode (14) is in the operating state, the vertical deflection current also flows through the toroidal vertical deflection coil (13). For this reason, a barrel magnetic field in the direction opposite to the barrel magnetic field generated from the saddle type vertical deflection coil (12) is generated in the peripheral portion in the vertical direction, and as a result, the pincushion magnetic field is strengthened, and the inverted cross-misconvergence is achieved. And inverted VCR can be corrected.

Further, another embodiment will be described with reference to FIGS. 6 and 7. FIG. Vertical deflection coil of this embodiment (21)
Is a saddle-type vertical deflection coil (22), a toroidal-type vertical deflection coil (22) connected in series with the saddle-type vertical deflection coil (22) so that the direction of the generated magnetic field is the same as that of the saddle-type vertical deflection coil (22). A vertical deflection coil (23), an anti-parallel connected diode (24) connected in series with the toroidal vertical deflection coil (23), and a series circuit of the toroidal vertical deflection coil (23) and the diode (24). On the other hand, a resistor (25) is connected in parallel. In the vertical deflection coil (21), as shown in FIG. 7, the saddle type vertical deflection coil (22) generates a barrel magnetic field as shown by a curve (E), but the toroidal type vertical deflection coil (23) Unlike the embodiment, a pincushion magnetic field is generated as shown by a curve (F). This pincushion magnetic field can be easily obtained by changing the winding width of the toroidal coil.

The vertical deflection coil (21) having this configuration has the same operation and effect as the above embodiment.

[Effects of the Invention] As described above, according to the present invention, inversion cross miss convergence and inversion VC can be achieved without using a modulator.
It is possible to provide a color picture tube deflecting device capable of correcting R without inconvenience such as deflecting power loss and obtaining good convergence characteristics.

[Brief description of the drawings]

FIG. 1 is a connection diagram showing a vertical deflection coil used in an embodiment of the present invention, FIG. 2 is a perspective view of a color picture tube deflector for explaining an embodiment of the present invention, and FIG. FIG. 4 is a graph showing the distribution of the magnetic field strength H ₀ of the coil, and FIG.
Graph showing the distribution of the magnetic field characteristics of H ₂ indicated vertical deflection coils in FIG., FIG. 5 is connection diagram showing a vertical deflection coil used in another embodiment of the present invention, Figure 6 is yet another of the present invention Connection diagram illustrating a vertical deflection coil used in the embodiment of
FIG. 7 shows the magnetic field characteristic H ₂ of the vertical deflection coil shown in FIG.
FIG. 8 is a schematic diagram illustrating the state of a raster when a conventional deflecting device is used, and FIG.
FIG. 10 is a graph showing a change in the amount of inversion cross-misconvergence of the raster shown in FIG. 10, FIG. 10 is a schematic diagram for explaining an inversion VCR in a raster when a conventional deflection device is used, and FIG. 9 is a graph showing a change in the inverted VCR amount of the raster. DESCRIPTION OF SYMBOLS 1 ... Deflection device, 2 ... Separator, 3 ... Vertical deflection coil, 4 ... Core, 5 ... Toroidal type vertical deflection coil, 6 ... Saddle type vertical deflection coil, 7 ... Diode,

Claims (3)

(57) [Claims] 1. A deflection apparatus for a color picture tube, comprising: a horizontal deflection coil comprising a saddle type coil; and a vertical deflection coil comprising a saddle type vertical deflection coil and a toroidal type vertical deflection coil connected in series with each other. The strength of the barrel magnetic field generated from the vertical deflection coil is set to be larger than the strength of the barrel magnetic field generated from the saddle type vertical deflection coil, and the direction of the magnetic field of the barrel magnetic field from both vertical deflection coils is set to the same direction. A non-linear current control element connected in anti-parallel in parallel is connected to a deflection device for a color picture tube. 2. A deflection apparatus for a color picture tube, comprising: a horizontal deflection coil comprising a saddle type coil; and a vertical deflection coil comprising a saddle type vertical deflection coil and a toroidal type vertical deflection coil connected in series with each other. The strength of the barrel magnetic field generated from the vertical deflection coil is set to be larger than the strength of the barrel magnetic field generated from the saddle type vertical deflection coil, and the directions of the barrel magnetic fields from both the vertical deflection coils are set in opposite directions. A collar connected to the non-linear current control element connected in series and anti-parallel, and a resistor connected in parallel to the toroidal vertical deflection coil and the non-linear current control element; Deflection device for picture tube. 3. A deflection device for a color picture tube, comprising: a horizontal deflection coil comprising a saddle type coil; and a vertical deflection coil comprising a saddle type vertical deflection coil and a toroidal type vertical deflection coil connected in series with each other. The vertical deflection coil generates a pincushion magnetic field, the saddle type vertical deflection coil generates a barrel magnetic field, and sets the magnetic field directions of the magnetic fields from both vertical deflection coils in the same direction, and is antiparallel in series with the toroidal type vertical deflection coil. A deflection device for a color picture tube, wherein a connected non-linear current control element is connected and a resistor is connected in parallel to the toroidal vertical deflection coil and the non-linear current control element. .