KR820000416B1 - Color receiver - Google Patents

Abstract

A color TV picture tube having an earth magnetism compensation panel member comprises a pair of magnetic panels(11) which attached at the short sides(10) of the shadow mask member of the picture tube, the other pair of magnetic panels(13) which attached at the upper and lower ends of the panels(11). Where, the magnetic panels parallel with the axis of the tube and the inside of the panel, resp.

Description

Cala Award House

1 to 4 are diagrams showing electron beam landing errors due to geomagnetic components at each position of the water pipe screen when the magnetic shield is not used (number unit is micron) .

5 is an exploded view of the shadow mask sphere near the water pipe for explaining the conventional simple inner shield.

6 is an exploded view of a shadow mask sphere in the vicinity of a conventionally used inner shield.

7 to 9 are diagrams showing the amount of landing error due to the geomagnetic component when a simple inner shield is used.

Fig. 10 is a perspective view showing the relative relationship between a shadow mask sphere, an element coil, a deflection coil, and an electron cylinder for explaining the present invention.

Figure 11 is a perspective view of a shadow mask sphere and geomagnetic correction magnetic plate sphere showing an embodiment of the present invention.

12 to 14 show the amount of landing errors due to the geomagnetic components in the case of carrying out the present invention.

TECHNICAL FIELD The present invention relates to a geomagnetic correction plate sphere mounted in a collar water pipe, particularly in the collar water pipe. Conventionally, especially in small sized receivers, due to the weight reduction and cost reduction of the receivers, since the magnetic shield is not mounted to reduce the orbital distortion of the pole of the receiving pipe generated by the geomagnets generally used in large machines, the geomagnets are used in different regions. There was a problem that the color purity of the screen is impaired and the quality of the product is reduced.

As one of the countermeasures, an inner shield for shielding the geomagnetism by installing a magnetic sphere inside the receiving tube is known. However, since the size of the magnetic sphere is the same as or larger than the shadow mask sphere inside the receiving tube, the surface of the receiving tube is manufactured. When processing by a processing furnace, a large amount of space is required, thereby reducing the processing capacity. In addition, in the product, the shadow mask surface is irradiated by the scanning electron beam, and the temperature of the surface increases, but since the irradiation surface of the shadow mask is surrounded by the inner shield, heat dissipation is deteriorated and heat deformation is increased, and magnetization is applied to the shadow mask. In terms of manufacturing and characteristics such as an increase in element current for erasing a magnetic field, the use of an inner shield, particularly in a small water tube, has not been preferable.

An object of the present invention is to provide a high-quality color water tube with a simple configuration to eliminate the defects that the conventional inner shield water tube had, to mitigate the effects of geomagnetic effects.

The present invention does not reduce the landing error by shielding the geomagnetism, but is characterized in that a simple correction plate is installed in the inside of the water tube so that the non-landing error caused by the geomagnetism is the smallest in the entire screen of the water tube. Has a magnetic plate that is approximately parallel to the inner wall of the observation or panel installed along the short side of the shadow mask sphere, and again a magnetic plate that is perpendicular to the tube axis that is installed to preserve the gap along the long side of the shadow mask sphere or approximately parallel to the inner wall of the panel. A color water tube with geomagnetically corrected plates is obtained.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail, referring drawings. Conventionally, particularly in the case of small tubes, since the magnetic shield is not used, when the vertical component of the geomagnetic changes from about 0 to 0.7 gauss at approximately the same as the anode at the equator, the beam landing has a landing error as shown in FIG. Here, the outer frame of the figure shows the screen of the water pipe and the numerical value indicates the amount of beam landing error in the vicinity of the screen in microns.

Therefore, for example, what happens when the water tube is actually used will be described in the case of 0.35 gauss, which is roughly equivalent to the vertical magnetic field component in Japan. On the basis of the absence of geomagnetism (i.e., zero gauss), the amount of landing error at each position is half of that of FIG. 1 as shown in FIG. Thus, when the central landing error is adjusted to zero by the purity adjustment correction stimulus, only 28.5 microns of the landing error is reduced in the front of the screen, respectively, as shown in FIG. 3. As such, the landing error is large at the current position on the screen and is large again in a high latitude region. In addition, the landing error in Japan is the largest in the north-south direction due to the horizontal component of the geomagnetism and indicates the error as shown in FIG. 4, and the color purity of the screen is damaged by the error of these two components. Therefore, since the amount of landing errors caused by geomagnetism is reduced, a conventional internal shield has been devised and used. An example of the schematic structure is shown in FIG. The magnetic plate sphere 3 divided up and down is installed on the long side 2 of the shadow part of the shadow mask sphere, and a large part of the landing error caused by the influence of the magnetic field around the screen is shielded from the geomagnetism. An increase in device current, a decrease in heat dissipation of the shadow mask, and easy lighting of the processing were performed, which were the drawbacks of the conventional inner shield 4 of the conventional whole type shown in FIG.

As a result, when there is no magnetic shield, the error corresponding to the first degree of the landing error for the 0 to 0.7 Gaussian change can be reduced in absolute magnitude as shown in FIG. However, the error after the purity adjustment at 0.35 gauss is as shown in FIG. 8, and for the horizontal magnetic component, a slight error improvement is performed as shown in FIG. 9 with the maximum error amount in the trend and west direction. Lost but not enough.

The present invention is further improved by the structure as shown in FIG. The electron beam trajectory 7 is bent in the horizontal direction by the vertical magnetic field component between the beam incidence opening 5 and the electron gun 6 of the shadow mask sphere 1. In addition, the electron beam 9 deflected by the deflection coil 8 has a longer reach as compared to the center of the screen, so that the magnetic field is largely affected by the magnetic field, and the beam movement amount increases. In order to prevent this from happening so that the landing error is the same at the entire position of the screen, in this embodiment, a vertical magnetic plate 11 is installed on the short side side 10 of the shadow part of the shadow mask bracket 1 and the outer edge of the vertical magnetic plate 11 is provided. A horizontal magnetic plate 13 is mounted above and below 12, and a magnetic field near the periphery of the vertical magnetic field is guided to the vertical magnetic plate 11, and the distribution of the passage area of the electron beam is changed.

In addition, since the horizontal magnetic plate 13 is provided with a gap between the long side 14 of the hurdle portion, the vertical alternating magnetic field that is most effective for the elements of the shadow mask passes through the shadow mask in the vertical direction, and most of the device effects do not decrease. In order to eliminate the magnetic field magnetized in the shadow mask, the element coil 15 is wound around the water pipe, and an AC current flows automatically at the moment when the switch of the water receiver is inserted or disconnected. In the conventional simple internal shields shown in FIGS. 5 and 6, it is preferable to carry out a device with a large current flowing until many element systems pass through the internal system of the inner shield metal near the device coil and the device on the shadow mask surface is completely disappeared. Needed.

However, according to the present invention, since the surface close to the element coil is opened up and down, the element system is guided to the shadow mask surface a lot and the element is completely performed.

An embodiment of such a geomagnetic correction plate will be described.

In FIG. 11, a vertical magnetic plate 11 is mounted on the short side face 10 of the shadow mask sphere frame part substantially parallel to the tube axis, and the horizontal magnetic plate 11 is perpendicular to the tube axis on the side 12 facing the mounting part or the surface 16 is substantially parallel to the panel inner wall. Mount the directional magnetic plate 13 '. Although this mounting may be a welding method, it may be a method of assembling by combining a part of parts. Geomagnetism from 0 to 0.7 gauss when the size of the vertical magnetic plate 11 is approximately the same as the dimensions of the frem and the width of the horizontal magnetic plate 13 'is approximately twice the width of the metal surface 17 at the incident side of the electron beam. The landing error amount when the vertical component of is changed is shown in FIG. The error amount after the purity adjustment to 0.35 gauss is shown in FIG. As a result, the amount of error with respect to the change of the vertical magnetic field was also reduced in the above-described shielding method. In addition, there is little landing error amount after the purity adjustment. In addition, the landing error amount in the north-south direction indicating the maximum value by the horizontal component of the magnetic field is also as shown in FIG. 14, which is the main purpose of the present invention. The landing error at each position of the screen after the purity adjustment can be minimized, and the amount of landing error due to the horizontal component of the magnetic field can be reduced. In addition, in the manufacturing process, it is only necessary to process two or four small pieces of small body, so that the processing capacity is dramatically increased.

Claims (1)

As shown in the drawings and described above in the main text, a magnetic plate having a tube axis or a surface substantially parallel to the inner wall of the panel is provided on the short side of the shadow tube shadow mask sphere, and on the mounting side of the shadow mask sphere of the magnetic plate. And a magnetic plate having a magnetic plate having a surface perpendicular to a tube axis or substantially parallel to an inner wall of the panel at a side opposite to the side, and having a geomagnetic correction plate sphere spaced from a horizontal long side above and below the shadow mask sphere.

Images