KR0135858B1 - Cathode-ray tube - Google Patents

Abstract

Disclosed are cathode ray tubes with improved screen surface. The cathode ray tube includes a panel having a screen surface, and a funnel sealed to the funnel and encapsulated with an electron gun at its neck. The long axis of the screen surface is called X axis and the short axis is Y axis. The curvature of the screen is Z = A ₁ X ² + A ₂ X ⁴ + A ₃ Y ² + A ₄ Y ⁴ + A ₅ X ² Y ² + A ₆ X ⁴ X ² + A ₇ X ² Y ² Approximated by + A ₈ X ⁴ Y ⁴ ,

When the value of P is defined as satisfying the inequality -0.1P0, it has the advantage of preventing distortion of the image formed on the screen surface.

Description

Cathode ray tube with improved curvature on the screen

1 is a cross-sectional view of a typical cathode ray tube.

2 is a perspective view schematically showing a device for measuring an image distortion state of a conventional cathode ray tube screen surface.

3 and 4 are plan views showing a distortion state of an image formed on the screen surface of a conventional cathode ray tube.

5 is a plan view showing a distorted state of an image formed on an improved screen surface of a cathode ray tube according to the present invention.

* Description of the symbols for the main parts of the drawings *

11,30 panel 11a, 31 screen surface

13 funnel 13a neck part

14 electron gun 15 deflection yoke

The present invention relates to a cathode ray tube, and more particularly, to a cathode ray tube having improved curvature of a screen surface so that distortion of an image in which the cathode ray tube is formed on the screen surface can be prevented.

In general, the cathode ray tube uses a high-speed electron beam. As shown in FIG. 1, the shadow mask frame assembly 12 having the color screening function is fixed inside the panel 11 having the screen surface 11a. The panel 11 is provided with a funnel 13 in which an electron gun 14 and a deflection yoke 15 are provided inside and outside the neck portion 13a.

The cathode ray tube 10 configured as described above selectively deflects the yoke according to the position at which the electron beam emitted from the electron gun 14 installed in the neck portion 13a of the funnel 13 is scanned onto the fluorescent film of the screen surface 11a. 15 is deflected and landed on the screen surface 11a to form one pixel, and these pixels gather to form a screen. The cathode ray tube configured as described above is formed such that the screen surface 11a of the panel 13 has a predetermined curvature so that the periphery of the arc formed on the screen surface 11a is distorted to the viewer's eyes sitting at the periphery of the cathode ray tube. It becomes visible. That is, the image formed on the periphery of the screen surface 11a has a predetermined inclination with respect to the audiovisual angle of the viewer, so that the image is distorted. In order to solve the problems described above, the screen surface of the cathode ray tube is formed flat, but when the screen surface is completely flat, the screen is curved when the viewer views the side of the screen surface. In order to solve such a problem, the image formed by the cathode ray tube should be formed with a predetermined curvature so that the image is not distorted when the viewer views in an arbitrary direction. However, the conventional cathode ray tube could not measure the distortion state of the image of the screen surface.

That is, in order to measure the degree of distortion of the image formed on the screen surface of the cathode ray tube, as shown in FIG. 2, the lattice shape is located at a position spaced apart from the screen surface 11a of the cathode ray tube 10 by a predetermined distance (about 2 m). The mesh 100 is installed, and the degree of distortion of the mesh 100 projected onto the screen surface 11a by projecting the screen surface 11 a onto the mesh network 100 using a light source from the upper surface of the mesh 100. By analogy, the distortion of the image is inferred. By the way, the cathode ray tube developed by Hitachi Japan Co., Ltd., measured in the above manner, remains as horizontal and perpendicular to the center of the screen surface as the remnants of the projected net 100 as shown in FIG. It can be seen that the distortion appears severely at the edges on both sides thereof. As shown in FIG. 4, the cathode ray tube developed by Toshiba Corporation, Japan, shows that afterimages projected on the screen surface are generally distorted at the center and periphery of the screen surface.

In the cathode ray tube as described above, when the viewer views the image formed on the screen surface of the cathode ray tube in front of the cathode ray tube, the distortion of the image does not appear severely, but when the viewer views the image from the side of the screen surface, There is a problem that the image formed is severely distorted.

The present invention has been made to solve the above problems, and an object thereof is to provide a cathode ray tube having an improved screen surface that can prevent distortion of an image formed on the screen surface.

Another object of the present invention is to prevent the distortion of the image formed in the periphery of the screen to reduce the fatigue of the viewer's eyes even if the viewer views the image in any direction of the front of the screen, and further improve its commercial value The present invention provides an improved cathode ray tube.

In order to achieve the above object, the present invention provides a cathode ray tube having an improved screen surface including a panel having a screen surface, and a funnel sealed to the panel and having an electron gun enclosed in the neck portion thereof. When the major axis is called X axis and the minor axis is called Z axis, the curvature of the screen is Z = A ₁ X ² + A ₂ X ⁴ + A ₃ Y ² + A ₄ Y ⁴ + A ₅ X ² Y ² + A ₆ X ⁴ X ² + A ₇ X ² Y ² + A ₈ X ⁴ Y ⁴

When the value of P is defined as an inequality at the boundary point (X = X1, Y = Y1) of the effective screen; It is characterized by satisfying -0.1P0.

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

As shown in FIG. 1, the cathode ray tube is a panel 30 having a screen surface 31 and a funnel 13 sealed to the panel 11 and having an electron gun 14 enclosed in its neck portion 13a. It is configured with. Here, the curved shape of the screen surface is expressed as an approximation formula by combining elements of quadratic and quadratic in consideration of the rotational target.

Z = A ₁ X ² + A ₂ X ⁴ + A ₃ Y ² + A ₄ Y ⁴ + A ₅ X ² Y ² + A ₆ X ⁴ X ² + A ₇ X ² Y ² + A ₈ X ⁴ Y ⁴ ( One)

In the above formula, X and Y each represent a distance in the X-axis and Y-axis directions from the center of the panel.

From the above formula (1), a predetermined design reference value is set

In this case, distortion of the image formed on the screen surface 31 can be prevented when the value of P satisfies the inequality -0.1P0 at X = X1 Y = Y1. X1 is half of the X-axis effective screen length of the screen surface, and Y1 is half of the Y-axis effective screen length.

The above-described technology will be described in more detail with reference to one embodiment.

Assuming that the quadratic coefficient of Equation (2) is as follows, (X = 270.4, Y = 202.8)

A1 = 2.275831 * 10 ^-10

A2 = -9.165778 * 10 ^-11

A3 = 2.36601 * 10 ^-4

A4 = -1.053829 * 10 ^-10

A6 = 1.67825 * 10 ^-16

A7 = 2.058604 * 10 ^-16

If the coefficients A5 and A8 are 0 (A5 = A8 = 0), the value of P becomes 0. At this time, the shape of the image distortion formed on the screen is barrel-shaped as shown in FIG. Will have

When the values of A5 and A8 of Equation (2) are -2.13787 * 10 ^-10 and -2.38673 * 10 ^-22 , respectively, the value of P has -0.025, and the distortion of the image formed on the screen surface is As shown in Fig. 5 (b), it is completely removed so that the distortion of the image does not occur even if the viewer views the image formed on the screen surface of the cathode ray tube in an arbitrary direction. And when the coefficients of A5 and A8 in Eq. (2) are -8.56969 * 10 ^-10 and 0, respectively, the value of P is -0.1 and the distortion of the image formed on the screen surface as shown in FIG. Has a pincushion shape.

As can be seen from the above description, in order to minimize the image formed on the screen surface of the cathode ray tube, the P value must satisfy the range of inequality -0.1P0.

As described above, the cathode ray tube of which the screen surface of the present invention is improved can prevent distortion of an image formed on the screen surface by limiting the curvature of the screen to a predetermined shape. Furthermore, the cathode ray tube can be formed on the screen surface even if the viewer views in an arbitrary direction. There is an advantage in that the product value of the product can be improved by preventing the image to be distorted.

Claims (1)

In a cathode ray tube having an improved screen surface including a panel having a screen surface and a funnel encapsulating the panel and having an electron gun enclosed therein, the long axis of the screen surface is referred to as the X axis and the short axis is referred to as the Y axis. When the tube axis is called the Z axis, the curvature of the screen surface is Z = A ₁ X ² + A ₂ X ⁴ + A ₃ Y ² + A ₄ Y ⁴ + A ₅ X ² Y ² + A ₆ X ⁴ X ² + A ₇ X | Approximately represent ² Y ² + A ₈ X ⁴ Y ⁴ , And the value of P satisfies the inequality -0.1P0 at the boundary points (X = X1, Y = Y1) of the effective screen.