KR20030092330A - Electron gun for cathode ray tube - Google Patents

Abstract

PURPOSE: An electron gun for a cathode ray tube is provided to prevent the asymmetry of focusing characteristics of a center part and a peripheral part and improve the sensitivity of an SVM coil. CONSTITUTION: An electron gun for a cathode ray tube includes a triode portion(12), a plurality of focus electrodes(14), an anode electrode(G5), and a couple of bead glasses(16). The triode portion(12) is formed with a cathode(C), a first grid electrode(G1), and a second grid electrode(G2). The bead glasses(16) are used for arranging the electrodes in a row line. The focus electrode(14) includes a third grid electrode(G3) and a fourth electrode(G4). The third grid electrode(G3) is electrically connected to the anode electrode(G5) by means of a connector. The fourth grid electrode(G4) is connected between the third grid electrode(G3) and the anode electrode(G5). The connector is fixed on the bead glasses(16).

Description

Electron gun for cathode ray tube {ELECTRON GUN FOR CATHODE RAY TUBE}

The present invention relates to an electron gun for a cathode ray tube, and more particularly, to prevent the electric field generated from the connector connecting the third grid electrode and the anode electrode from penetrating through the VM gap of the focus electrode, thereby deteriorating the central focus characteristic and peripheral focus. The present invention relates to an electron gun capable of preventing asymmetry of characteristics and improving sensitivity of an SVM coil.

In general, a cathode ray tube includes a fluorescent screen on which an electron beam is irradiated, a neck portion on which an electron gun is disposed, a funnel portion connecting the screen and the neck portion, and a deflection yoke for deflecting the electron beam on the outer surface of the neck portion, and an SVM (scanning speed). Modulation (Scanning Velocity Modulation) coil is placed.

In this case, the SVM coil functions to improve the sharpness at the boundary of the image by changing the position of the electron beam passing through the electrode of the electron gun in synchronization with the image signal, and is usually arranged to face two saddle coils. Is formed by connecting the coils in series, and a signal obtained by differentiating the luminance signal of the video signal twice is applied to the SVM coil. The focus electrode of the electron gun forms a VM gap so that the magnetic field of the SVM coil can penetrate. Hereinafter, the basic structure of the electron gun for cathode ray tube having the VM gap will be described with reference to FIG. 1.

1 illustrates a UPF (Uni Potential Focus) type electron gun which is widely used as an electron gun for a projection display device. The electron gun includes a cathode C emitting electrons and first and second grid electrodes G1 and G2. And a tripolar tube portion 112, a plurality of focus electrodes 114 and an anode electrode G5, and bead glass 116 for fixing the electrodes in a row. In addition, the focus electrode 114 forms a prefocus lens 118 between the third grid electrode G3 and the third grid electrode G3 maintained at an equipotential with the anode electrode G5, And a fourth grid electrode G4 forming a main focus lens 120 between the anode electrode G5, and the fourth grid electrode G4 includes a VM through which a magnetic field generated in the SVM coil 122 passes. The first and second split electrodes G4-1 and G4-2 are divided to form a gap G.

Here, the VM gap G prevents the degradation of the sensitivity of the SVM coil due to the eddy current generated on the surface of the electrode G4, and serves to easily penetrate the magnetic field of the SVM coil.

In the electron gun having such a configuration, since the driving voltage of approximately 32 kW is applied to the anode electrode G5, this voltage is also applied to the third electrode G3 through the connector 124. However, since the connector 124 is disposed at a position adjacent to the focus electrode G4 in a space where the pair of bead glass 116 is not provided as shown, a high voltage (32 kV) applied to the connector 124 is provided. ), The generated electric field penetrates through the VM gap G between the first and second split electrodes G4-1 and G4-2 to which a driving voltage of 8 to 9 kV is applied.

Thus, as shown in FIG. 2, the electric field inside the electrode forming the prefocus lens is affected by the electric field penetration from the connector 124 described above, which deteriorates the center focus characteristic and the peripheral focus characteristic. There is a problem of asymmetry. In FIG. 2, reference numeral O denotes the center of the electron gun.

In addition, the electron gun having the above structure increases the electric field penetration from the connector 124 as the VM gap G is formed wider. Therefore, the VM gap G cannot be set sufficiently wide, so that the sensitivity improvement of the SVM coil is limited. It must be done.

Accordingly, the present invention is to solve the above problems, by suppressing the electric field generated from the connector connecting the third grid electrode and the anode electrode penetrates through the VM gap of the focus electrode, deterioration of the central focus characteristic and peripheral focus An object of the present invention is to provide an electron gun capable of preventing the asymmetry of characteristics and improving the sensitivity of the SVM coil.

1 is a schematic view showing the configuration of an electron gun for a cathode ray tube according to the prior art;

FIG. 2 is a diagram showing electric field distribution at the center of the VM gap of FIG. 1. FIG.

Figure 3 is a schematic diagram showing the configuration of an electron gun for a cathode ray tube according to an embodiment of the present invention.

4 is a diagram showing electric field distribution at the center of the VM gap of FIG.

5 is a schematic view showing the configuration of an electron gun for a cathode ray tube according to another embodiment of the present invention.

The object of the present invention described above,

A triode portion comprising a cathode for emitting electrons and first and second grid electrodes;

A plurality of focus electrodes and anode electrodes;

Includes; a pair of bead glass for fixing the electrodes in a row;

The focus electrode is divided so as to form a third grid electrode electrically connected to the anode electrode by a connector, and a VM gap through which the magnetic field generated in the SVM coil penetrates, and is installed between the third grid electrode and the anode electrode. Consists of four grid electrodes, the connector is achieved by an electron gun for cathode ray tubes fixed to the bead glass on the outside of the inner surface facing the electrodes.

According to a preferred embodiment of the present invention, the connector comprises fixed ends fixed to the third grid electrode and the anode electrode, respectively, and connecting portions connecting the fixed ends, wherein the connecting portion is fixed to the outer surface of the bead glass. Or embedded in the bead glass.

The third grid electrode side fixed end may be fixed to the buried part of the third grid electrode embedded in the bead glass, and the anode electrode side fixed end may be fixed to the buried part of the anode electrode embedded in the bead glass, or It may be fixed to the anode electrode outside the longitudinal end of the bead glass.

Hereinafter, an electron gun for a cathode ray tube according to a preferred embodiment of the present invention with reference to the accompanying drawings in detail as follows.

3 is a view showing a schematic configuration of an electron gun for a cathode ray tube according to an embodiment of the present invention, the electron gun is a cathode (C) for emitting electrons and the first, second grid electrodes (G1, G2) And a tripolar tube portion 12, a plurality of focus electrodes 14 and anode electrodes G5, and bead glass 16 for fixing the electrodes in a row.

In addition, the focus electrode 14 forms a prefocus lens 18 between the third grid electrode G3 and the third grid electrode G3 maintained at the equipotential with the anode electrode G5, The fourth grid electrode G4 forms a main focus lens 20 between the anode electrode G5 and the fourth grid electrode G4 is a VM through which a magnetic field generated in the SVM coil 22 passes. The first and second split electrodes G4-1 and G4-2 are divided to form a gap G.

Here, the VM gap G prevents the degradation of the sensitivity of the SVM coil 22 due to the eddy current generated on the surface of the electrode, and serves to easily penetrate the magnetic field of the SVM coil 22.

In the electron gun having such a configuration, the connector 24 electrically connecting the anode electrode G5 and the third grid electrode G3 includes a fixed end 24a fixed to the third grid electrode G3, and an anode electrode. It consists of a fixed end portion 24b fixed to (G5) and a connecting portion 24c for connecting both fixed ends 24a and 24b. The present invention provides that the connection portion 24c is insulated by the bead glass 16. It features.

In other words, the connector 24 serves to transfer the driving voltage of approximately 32 kV applied to the anode electrode G5 to the third grid electrode G3, as described above. Drive voltage is applied. Accordingly, when the driving voltage is applied, an electric field due to the driving voltage is formed in the connector 24, and the electric field formed in the connector 24 is blocked by the bead glass 16.

In order to allow the bead glass 16 to block the electric field of the connector 24 as described above, the present embodiment places the connecting portion 24c on the outer surface of the bead glass 16, and the fixed end of the third grid electrode G3 side. The 24a is fixed to the buried portion 26 of the third grid electrode G3 embedded in the bead glass 16, and the fixed end 24b of the anode electrode G5 side is a longitudinal end of the bead glass 16. It is fixed to the anode electrode G5 from the outside.

Thus, the electric field generated at the connector 24 is effectively blocked by the bead glass 16.

4 shows the electric field distribution at the center of the VM gap in the electron gun of the present invention, and it can be seen that the field asymmetry at the center of the focus electrode is mostly removed as compared with the conventional electron gun shown in FIG. 2. Therefore, the electron gun of the present invention in which the connector is disposed as described above can prevent the deterioration of the central focus characteristic and the asymmetry of the peripheral focus characteristic, and increase the VM gap since the influence of the penetration of the connector electric field is not considered. This makes it possible to improve the sensitivity of the SVM coil.

5 illustrates a schematic configuration of an electron gun according to another embodiment of the present invention, in which a connection portion 24c of the connector 24 is embedded in the bead glass 16, and an end portion of the anode electrode G5 side is beaded. Except for being fixed to the buried portion 26 of the anode electrode G5 embedded in the glass 16, the basic configuration is the same as the embodiment of Figure 3, and has the same operation and effect as the above-described embodiment.

Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various modifications and changes can be made within the scope of the claims and the detailed description of the invention and the accompanying drawings. Naturally, it belongs to the range.

As described above, in the electron gun of the present invention, since the connection part connecting the fixed end of the connector is located outside the inner surface of the bead glass, the electric field generated by the connector is blocked by the bead glass.

Therefore, deterioration of the central focus characteristic and asymmetry of the peripheral focus characteristic can be effectively prevented, and the VM gap can be increased, thereby improving the sensitivity of the SVM coil.

Claims (6)

A triode portion comprising a cathode for emitting electrons and first and second grid electrodes; A plurality of focus electrodes and anode electrodes; Includes; a pair of bead glass for fixing the electrodes in a row; The focus electrode is divided so as to form a third grid electrode electrically connected to the anode electrode by a connector, and a VM gap through which the magnetic field generated in the SVM coil penetrates, and is installed between the third grid electrode and the anode electrode. The electron gun for the cathode ray tube made of a grid electrode, the connector is fixed to the bead glass to the outside of the inner surface facing the electrodes. The electron gun of claim 1, wherein the connector comprises fixed ends fixed to the third grid electrode and the anode electrode, and a connecting part connecting the fixed ends, and the connecting part is fixed to an outer surface of the bead glass. The electron gun for a cathode ray tube according to claim 1, wherein the connector comprises fixed ends fixed to the third grid electrode and the anode electrode, and a connection part connecting the fixed ends, and the connection part is embedded in the bead glass. The electron gun for cathode ray tube according to claim 2 or 3, wherein the third grid electrode side fixed end is fixed to a buried portion of the third grid electrode embedded in the bead glass. The electron gun for cathode ray tube according to claim 2 or 3, wherein the anode electrode side fixed end is fixed to a buried portion of an anode electrode embedded in bead glass. The electron gun for a cathode ray tube according to claim 2, wherein the anode electrode side fixed end is fixed to the anode electrode outside the longitudinal end of the bead glass.