KR100299170B1 - Purity improvement device of display device - Google Patents

Abstract

The purity improvement apparatus of the display apparatus of the present invention for removing the unevenness of the screen generated by the influence of the magnetic field by the linearity correction coil, the CRT of the electron beam is projected to form an image, and the A display device comprising a deflection yoke for imparting a deflection force to a path and a linearity correction coil connected to the deflection yoke in series to correct linearity and provided on a circuit board, the magnetic flux generated from the linearity correction coil. And the electron beam is installed horizontally to minimize mutual interference.

Description

Purity improvement device of display device

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a display device, and more particularly, to an apparatus for improving the purity of a display device, by which the structure of the linearity correction coil can be changed to improve the screen purity.

1 shows a configuration of a horizontal deflection circuit of a display device. A horizontal output transistor Q1 receiving a horizontal drive pulse at the base end, a damping diode D1 connected to the collector end of the horizontal output transistor Q1, and a resonance connected in parallel with the damping diode D1. Horizontal Deflection Yoke (H-DY) And a linearity correction coil L1 connected in series to the deflection yoke H-DY and correcting linearity using a change value of inductance, and connected in series to the linearity correction coil L1. It is comprised including the S correction capacitor C2.

The horizontal output transistor Q1 performs the switching operation by the horizontal drive pulse. A sawtooth wave current output from the collector stage is applied to the horizontal deflection yoke H_DY to perform deflection in the vertical direction of the electron beam. At this time, in order to stably maintain the linearity of the horizontal sawtooth wave current waveform for each frequency, the linearity correction coil L1 and the S correction capacitor C2 are connected to the horizontal deflection yoke H_DY.

2 is a cross-sectional view illustrating a state in which a linearity correction coil is installed on a circuit board. As shown in FIG. 2, the linearity correction coil 100 is mounted on a circuit board 50 installed below the CRT. The coil 100 for linearity correction includes a bobbin-type core 10 in which the cross-sectional area of the center portion 12 is smaller than that of the upper and lower portions 11 and 13, and the center portion of the core 10 ( 12 is wound around the winding 20, the magnet 30 is installed in contact with the lower portion 13 of the core 10, and the lower end of the magnet 30 is configured to support the coil 100 And a start point and an end point of the winding 20 are connected to the circuit board 50 by connecting pins 14 and 15.

As shown in FIG. 3, from the coil 100 for linearity correction, an electron beam is projected from an electron gun 70 provided in the CRT 60 in which an image is formed and reaches the lower end of the fluorescent screen 61. The magnetic flux generated will affect it. Magnetic flux is generated when a current is applied to the winding 20 wound around the central portion 12 of the coil 100 for linearity correction. This magnetic flux affects the path (solid line display) of the normal electron beam, and thus has an abnormal path (dotted line display) of the electron beam.

4A shows a part of the configuration of a phospho formed on the fluorescent surface. It is shown that the phosphors that can represent the colors of R, G, and B are formed in a predetermined arrangement. The electron beam impacts each phosphor and emits light from the phosphor, which is called beam landing. 4B shows that the electron beam is ideally applied to the phosphor. The image at this time will be displayed in white. 4C illustrates a case in which the path of the electron beam deviates due to the influence of the linearity correction coil 100. Therefore, the image is not emitted in the correct white color, but appears slightly smeared.

In the experimental data of FIG. 5, the rectangular mark indicates beam landing when the linearity correction coil 100 is measured at a sufficiently far position from the CRT, and the triangle mark indicates that the linearity correction coil 100 is generally mounted. It shows the beam landing when mounted close to the CRT according to the scheme. When dividing the CRT into 25 areas, the landing position in each part is shown in Table 1 below. This data is an example of detecting only G color among R, G, and B. In Table 1, A is data measured by a general display device, and B is data when a sufficient distance is provided between the linearity correction coil 100 and the CRT.

The numerical values in the following [Table 1] refer to the horizontal and vertical positions of the beams beamed in each region. As shown in the experimental data of FIG. 5 and Table 1, specific regions P ₁₁ , P ₁₆ , P ₁₇ , P ₂₁ , P ₂₂ , and P ₂₃ , that is, the coil for linearity correction as shown in FIG. 6 ( 100) and the distance between two points in the "A" region adjacent to the CRT is large. For reference, the method of calculating the distance between two points (X1, Y1), (X2, Y2) Same as This means that a plurality of electron beams do not reach the position of the fluorescent surface due to the influence of the magnetic force generated from the linearity correction coil 100. Accordingly, it can be seen that the purity of the display device is poorly affected by the magnetic force generated from the linearity correction coil 100.

division A B The distance of two points level Perpendicular level Perpendicular One 0 0 7 -2 7.3 2 -10 -2 -4 -5 6.7 3 -9 -3 -4 -4 5.1 4 -8 -2 -4 -6 5.7 5 -8 4 -6 0 4.5 6 -8 5 0 2 8.5 7 -17 2 -10 -One 7.6 8 -8 One -2 -One 6.3 9 0 5 5 2 5.8 10 -6 2 -One 0 5.4 11 -6 7 5 4 11.4 12 -16 2 -8 0 8.2 13 -8 One -One 0 7.1 14 0 3 5 One 5.4 15 0 -One 4 -4 5.0 16 -8 2 7 -One 15.3 17 -14 One -2 -One 12.2 18 -11 One -2 -One 9.2 19 -6 3 One 0 7.6 20 One -3 6 -6 5.8 21 -11 -12 10 -14 21.1 22 -10 -One 8 -5 18.2 23 -15 0 -One -4 14.6 24 -16 3 -8 -2 9.4 25 -One -6 6 -8 7.3

In other words, the reason why the linearity correction coil 100 should be installed on the lower surface of the CRT 60 is because of the optimized layout of the circuit board 50. Specifically, due to the characteristics of the monitor, as well as the circuit elements and components that drive the monitor, the CRT 60 itself is affected by an external electric field, magnetic field, or geomagnetic field. The components to be constructed are designed with an optimized layout to eliminate the effects of interaction. For this reason, the linearity correction coil 100 is positioned on the bottom surface of the CRT 60.

Therefore, the task of changing the position of the straightness correction coil 100 located on the lower surface of the CRT 60 is a difficult task in itself, or there is a problem of a huge development cost and a cost of reconfiguring a production line.

An object of the present invention is to improve the purity of a display device.

Another object of the present invention is to reduce the influence of the magnetic force generated from the linearity correction coil located on the lower surface of the CRT on the electron beam.

The present invention for achieving this object is a CRT in which an electron beam is projected to form an image, a deflection yoke for imparting a deflection force to a path of an electron beam projected on the fluorescent surface of the CRT, and connected in series to the deflection yoke In the display device having a linearity correction coil to be disposed on the circuit board, the magnetic flux generated from the linearity correction coil and the electric beam to be horizontally installed to minimize mutual interference.

1 is a circuit diagram showing the configuration of a horizontal deflection circuit of a general display device;

2 is a cross-sectional view showing the structure of a coil for linearity correction according to the prior art;

3 is a cross-sectional view showing a mounting state of the linearity correction coil according to the prior art,

4 is a diagram illustrating light emission of a phosphor by projection of an electron beam;

5 is a landing experiment data according to the prior art,

6 is an exemplary view showing a defective portion generated in accordance with the prior art;

7 is a cross-sectional view showing the structure of the coil for linearity correction according to the present invention;

8 is an exploded perspective view of the coil for linearity correction according to the present invention;

9 is a perspective view of the coupling state of the linearity correction coil according to FIG.

10 is a cross-sectional view showing a mounting state of the linearity correction coil according to the present invention;

11 is a landing test data diagram of an electron beam according to the present invention.

Hereinafter, the configuration and operation thereof according to the present invention will be described with reference to the accompanying drawings.

7 is a cross-sectional view showing the structure of the linearity correction coil according to the present invention. As shown in FIG. 7, the linearity correction coil of the present invention includes a bobbin-type core 10 having a small cross-sectional area of the central portion 12, and a central portion 12 of the core 10. The winding 20 wound a plurality of times in a direction perpendicular to the moving direction of the electron beam, a magnet 30 installed in contact with one surface 13 of the core 10, the core 10 and the magnet 30. The base 40 is provided at the lower end to prevent the flow of the) and the connecting pins 14 and 15 for fixing the coil 100 to the circuit board 50.

8 is an exploded perspective view of the linearity correction coil 100 according to the present invention, Figure 9 is a perspective view of the coupling state of the linearity correction coil 100 viewed from the bottom.

10 is a cross-sectional view showing a mounting state of the linearity correction coil according to the present invention. Unlike the prior art, it can be seen that the linearity correction coil 100 is mounted horizontally with the circuit board 50. At this time, since the magnetic flux generated from the linearity correction coil 100 and the moving path of the electron beam are horizontal, the range of influence of the magnetic flux of the linearity correction coil 100 on the electron beam is reduced. Therefore, since the mutual interference between the electron beam and the magnetic flux by the linearity correction coil 100 is minimized, the electron beam starting from the electron gun 70 reaches the fluorescent surface 61 through an accurate path (solid line display).

11 shows experimental data when the coil for linearity correction according to the present invention is mounted. The square mark represents the beam landing when the linearity correction coil is measured at a sufficient distance from the CRT, and the rhombus mark represents the beam landing when the straight line correction coil 100 is mounted according to the present invention. will be.

Unlike the conventional experimental data, it can be seen that the distance between the two markers is very close. This means that the magnetic flux generated from the linearity correction coil 100 does not affect the electron beam of the CRT. Table 2 below shows the numerical results of the experimental data of FIG.

From these experimental results, in the region (P ₁₁ , P ₁₆ , P ₁₇ , P ₂₁ , P ₂₂ , P ₂₃ ), the linearity correction coil 100 according to the present invention and when the linearity correction coil is measured at a sufficient distance and It can be seen that there is little difference in the beam landing position in the case of mounting. This result indicates that when the linearity correction coil 100 according to the present invention is mounted, the magnetic force generated from the linearity correction coil 100 does not affect the electron beam path of the cathode ray tube. Therefore, the poorness of purity caused by the electron beam not reaching the path can be improved.

division When the coil is separated out Application example of the present invention The distance of two points level Perpendicular level Perpendicular One 7 -2 8 -3 1.4 2 -3 -6 -4 -7 1.4 3 -4 -7 -7 -7 3.0 4 -7 -8 -9 -8 2.0 5 -13 -3 -15 -2 2.2 6 -One 4 -One 4 0 7 -10 One -11 One 1.0 8 -4 -One -5 -2 1.4 9 0 3 -3 One 3.6 10 -9 One -10 2 1.4 11 3 9 4 10 1.4 12 -9 4 -9 4 0 13 -4 4 -5 3 1.4 14 -One 6 -2 5 1.4 15 -5 3 -8 2 3.2 16 5 7 4 9 2.2 17 -4 7 -5 7 1.0 18 -5 7 -8 4 4.2 19 -5 7 -7 7 2.0 20 -4 3 -6 3 2.0 21 2 -4 One One 5.1 22 2 7 One 7 1.0 23 -4 7 -9 6 5.1 24 -13 8 -16 7 3.2 25 -3 3 -5 One 2.8

As described above, the range of the influence of the magnetic flux of the linearity correction coil on the electron beam of the CRT is reduced by the purity improving apparatus according to the present invention, thereby improving the purity of the screen.

Claims (3)

A CRT in which an electron beam is projected to form an image, A deflection yoke for imparting a deflection force to a path of an electron beam projected on the fluorescent surface of the CRT; In the display device having a linearity correction coil is connected to the deflection yoke in series to correct the linearity and installed on the circuit board, And a magnetic flux generated from the linearity correction coil so that the electron beam is horizontal to minimize mutual interference. The method of claim 1, And the circuit board on which the linearity correction coil is installed is installed at a lower end of the CRT. The method according to claim 1 or 2, And the magnetic flux of the electron beam and the linearity correction coil and the circuit board are horizontal to each other.