KR20060060469A - Electron gun assembly and cathode ray tube with the same - Google Patents

Abstract

The present invention relates to an electron gun for a cathode ray tube having an improved electrode structure to suppress inter-electrode discharge while maintaining a high resolution in a high current region.

An electron gun for a cathode ray tube according to the present invention includes a cathode for emitting electrons, a control electrode, a screen electrode, an intermediate electrode, a first anode electrode, a focusing electrode, and a second anode electrode disposed at an arbitrary distance from each other. It comprises a plurality of electrodes and a support for fixing the electrodes arranged in a row. In this case, the intermediate electrode receives a voltage higher than the voltage applied to the screen electrode and lower than the voltage applied to the first anode electrode.

Electron gun, cathode, support, control electrode, screen electrode, anode electrode, focusing electrode, slit

Description

ELECTRON GUN ASSEMBLY AND CATHODE RAY TUBE WITH THE SAME}

1 is a partial cutaway cross-sectional view showing a neck portion embedded with an electron gun according to an embodiment of the present invention.

2 is a cross-sectional view of the electron gun shown in FIG. 1.

3 is a schematic diagram of electrodes for explaining a wiring structure of an electron gun.

4A is a perspective view of the intermediate electrode shown in FIG. 1.

4B is a perspective view showing another embodiment of the intermediate electrode auxiliary support.

5 and 6 are perspective views showing another embodiment of the intermediate electrode, respectively.

7 is a partial cutaway sectional view showing an electron gun according to another embodiment of the present invention, and a neck portion in which the electron gun is incorporated.

FIG. 8 is a plan view of an electron gun showing another embodiment of the focusing electrode shown in FIG. 7.

9 is a partial cutaway cross-sectional view of a cathode ray tube according to an embodiment of the present invention.

10 is a partial cross-sectional view of an electron gun for a cathode ray tube according to the prior art.

The present invention relates to an electron gun for cathode ray tube, and more particularly, to an electron gun for cathode ray tube with improved electrode structure to suppress inter-electrode discharge while maintaining high resolution in a high current region.

In general, a projection display device using a cathode ray tube is composed of three monochrome cathode ray tubes each displaying a single color screen of red, green, and blue colors, and a monochromatic image of each cathode ray tube is projected on a projection screen to synthesize a color image. The optical system is a main configuration.

The projection type cathode ray tube realizes an image by using one stem electron beam, unlike a general color cathode ray tube using three stem electron beams, and the screen of each cathode ray tube is magnified about 10 times and projected onto a projection screen. Therefore, the conventional projection type cathode ray tube uses a unipotential-focus (UPF) electron gun that can realize a small electron beam mirror while using an electron beam in a high current region.

The UPF electron gun has a configuration in which a control electrode, a screen electrode, a first anode electrode, a focusing electrode, and a second anode electrode are sequentially disposed from a cathode for emitting electrons. A ground voltage is applied to the control electrode, a voltage of approximately 500 V is applied to the screen electrode, a voltage of 25 kV or more to the first and second anode electrodes, and a variable focus voltage of approximately 9 kV to the focusing electrode. As a result, a strong pre-focus lens is formed between the screen electrode and the first anode electrode, and a main-focus lens is formed between the first anode electrode and the focusing electrode and between the focusing electrode and the second anode electrode.

However, the UPF electron gun has a structure in which a discharge can easily occur because a potential difference between the screen electrode and the first anode electrode is about 30 kV or more. In fact, when driving the projection cathode ray tube, most of the discharge generated in the electron gun is generated between the screen electrode and the first anode electrode.

10 illustrates a discharge generation path of the electron gun for a conventional cathode ray tube.

Referring to FIG. 10, when driving the cathode ray tube, the potential of the first anode electrode G3 is guided to the screen electrode G2 through the bead glass 3 through the auxiliary support 1 so that the screen electrode G2 and the first electrode 1 are driven. Discharge failure due to arcing easily occurs between the anode electrodes G3. Black arrows in the figure indicate the paths through which discharge occurs. In the drawings, reference numeral K denotes a cathode, G1 denotes a control electrode, and G4 denotes a focusing electrode.

Accordingly, an object of the present invention is to provide an electron gun for a cathode ray tube having a structure that is advantageous for suppressing discharge between electrodes while maintaining a high resolution in a high current region.

In order to achieve the above object, the present invention,

A plurality of electrodes comprising a cathode for emitting electrons, a control electrode, a screen electrode, an intermediate electrode, a first anode electrode, a focusing electrode, and a second anode electrode arranged at an arbitrary distance from each other; It includes a support for arranging and fixing them in a row, and provides an electron gun for the cathode ray tube is applied to the intermediate electrode is higher than the voltage applied to the screen electrode and lower than the voltage applied to the first anode electrode.

The intermediate electrode may receive a fixed voltage from a corresponding stem pin through a connector or may be electrically connected to the focusing electrode through a connector to receive the same voltage as the focusing electrode.

The focusing electrode may be divided into two or more focusing electrodes to form a gap between the divided focusing electrodes, and at least one focusing electrode may form a slit in a direction orthogonal to the traveling direction of the electron beam.

In addition, the present invention, in order to achieve the above object,

An electron gun, a neck in which the electron gun is embedded, a funnel and a face panel positioned in front of the neck, a deflection yoke installed on the outer periphery of the funnel to generate a magnetic field for electron beam deflection, and a fluorescent film formed on the inner surface of the face panel, The electron gun includes a cathode, a plurality of electrodes including a control electrode, a screen electrode, an intermediate electrode, a first anode electrode, a focusing electrode, and a second anode electrode arranged at an arbitrary distance from each other, and the electrodes in line It provides a cathode ray tube which includes a support arranged to be fixed to the, wherein the intermediate electrode is applied with a voltage higher than the voltage applied to the screen electrode and lower than the voltage applied to the first anode electrode.

The electron gun has a single cathode, and the fluorescent film has one of red, green, and blue colors. The inner surface of the face panel is formed as a convex curved surface toward the neck.

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

1 is a partial cutaway cross-sectional view showing a neck portion in which the electron gun is embedded according to an embodiment of the present invention, Figure 2 is a cross-sectional view of the electron gun shown in FIG.

1 and 2, the electron gun 2 includes a cathode 4 emitting electrons, grid electrodes for focusing and accelerating electrons emitted from the cathode 4 into a single electron beam, and grid electrodes It includes a pair of supports (6) arranged and fixed to.

In the present embodiment, the grid electrodes are arranged sequentially from the cathode 4 at an arbitrary distance from each other, such as the control electrode 8, the screen electrode 10, the intermediate electrode 12, the first anode electrode 14, and the focusing electrode. It is composed of an electrode 16 and a second anode electrode 18, the first anode electrode 14 and the second anode electrode 18 is electrically connected by the first connector 20.

The control electrode 8 and the screen electrode 10 together with the cathode 4 constitute a triode, and control the amount of electron emission of the cathode 4 and pre-focus the electrons emitted from the cathode 4. To this end, a voltage lower than the voltage applied to the cathode 4, for example, a ground voltage is applied to the control electrode 8, and a voltage higher than the voltage applied to the cathode 4, for example, about 500V, is applied to the screen electrode 10. Is applied.

A high voltage of approximately 25 kV or more is applied to the first anode electrode 14 and the second anode electrode 18, and a variable focus voltage of 10 to 20 kV is applied to the focusing electrode 16. Thus, the pre-focus lens PFL is formed between the two electrodes by the potential difference between the screen electrode 10 and the first anode electrode 14, and by the potential difference between the first anode electrode 14 and the focusing electrode 16. The first main-focus lens FL ₁ is formed between the two electrodes. The second main-focus lens FL ₂ is formed between the two electrodes by the potential difference between the focusing electrode 16 and the second anode electrode 18.

The intermediate electrode 12 is applied with an intermediate voltage higher than the voltage applied to the screen electrode 10 and lower than the voltage applied to the first anode electrode 14. As a result, the intermediate electrode 12 smoothes the potential difference between the two electrodes in the space between the screen electrode 10 and the first anode electrode 14 on which the pre-focus lens PFL is formed, thereby reducing the screen electrode 10 and the first electrode. It serves to suppress discharge between the anode electrodes 14.

The intermediate electrode 12 is connected to the corresponding stem pin 24 through the second connector 22 to receive the above-described intermediate voltage from an external circuit device (not shown), or as shown in FIG. 3. Likewise, the third connector 24 may be electrically connected to the focusing electrode 16 to receive the same voltage as the focusing electrode 16. In the latter case, since the intermediate electrode 12 has a potential difference of up to about 23 kV with the first anode electrode 14, the withstand voltage characteristics can be improved as compared with the conventional electron gun structure.

On the other hand, the intermediate electrode 12 has a pair of supports (such as black arrow in FIG. 10) to block the discharge generation path (see the black arrow in FIG. 10) that the potential of the first anode electrode 14 is guided to the screen electrode riding on the support 6. 6) is formed with a maximum outer diameter between.

1 to 4B, the intermediate electrode 12 has a cylindrical body 12a through which an electron beam passes, and has an auxiliary support 26 for fixing to the support 6 on its outer surface. do. The outer diameter of the intermediate electrode 12 may be set to be equal to the maximum outer diameter of the first anode electrode 14 and the outer diameter of the focusing electrode 16. At this time, the first anode electrode 14 is composed of a first half portion 14a (see FIG. 2) and a second half portion 14b (see FIG. 2) having a larger diameter than the first half portion 14a. 1 is formed in a columnar shape having the same diameter as the second half 14b of the anode electrode 14.

The intermediate electrode 12 is also arranged to surround a portion of the first anode electrode 14, preferably a portion of the first portion 14a of the first anode electrode 14 facing the screen electrode 10.

As the intermediate electrode 12 is positioned at a distance from the support 6 while surrounding the part of the first anode electrode 14, the electron gun 2 of the present embodiment has a potential of the first anode electrode 14. Can be prevented from being guided to the screen electrode 10 on the support 6 to suppress discharge failure.

As shown in FIG. 4A, the intermediate electrode 12 may be integrally formed with the cylindrical body 12a and the support 26, and in this case, the number of assembly steps of the electron gun can be reduced, thereby making the production easy. As shown in FIG. 4B, the auxiliary support 26 ′ of the intermediate electrode 12 may be configured in the form of a pair of support portions arranged side by side. In this case, the intermediate electrode 12 may be a pair of supports ( 6) can be more firmly fixed.

The intermediate electrode 12 may have a shape shown in FIGS. 5 and 6 in addition to the above-described cylindrical shape. Referring to FIG. 5, the intermediate electrode 12 ′ is formed of a bottom portion 28 having a circular electron beam passing hole 28a and a cylindrical body portion 30 through which an electron beam passes. The part 30 and the auxiliary support 26 may be integrally formed. Referring to FIG. 6, the intermediate electrode 12 ″ may be formed of a plate electrode having a circular electron beam through hole 12 b, and the auxiliary support 26 may be integrally formed.

Meanwhile, as illustrated in FIG. 7, a scanning velocity modulation (SVM) coil 34 may be positioned on an outer circumference of the neck 32 of the cathode ray tube. The SVM coil 34 adjusts the speed at which the electron beam is scanned according to an image signal applied to the cathode ray tube, thereby clearly correcting the outline of the image. SVM coils 34 typically consist of two saddle coils that are connected in series.

In this embodiment, the focusing electrode 16 'is divided into the first focusing electrode 16a and the second focusing electrode 16b to form a gap between the two focusing electrodes 16a and 16b. In addition to the above configuration, as shown in FIG. 8, a plurality of slits 36 are formed along a direction orthogonal to the electron beam traveling direction, as any one focusing electrode 16 ″, for example, the first focusing electrode 16a '. do.

The gaps and slits 36 reduce the surface area of the focusing electrodes 6 ', 6 "facing the SVM coil 34, so that eddy currents are generated at the focusing electrode surfaces 6', 6" by the SVM magnetic field. It is possible to suppress the occurrence and to increase the sensitivity of the SVM coil 34 by causing the SVM magnetic field to directly affect the electron beam traveling through the electron guns 2 'and 2 ".

The electron guns 2, 2 ', 2 "of the present embodiment have the effect of reducing the electron beam diameter at the periphery of the screen by the shape of the above-described intermediate electrode and focusing electrode, thereby improving image quality.

Table 1 below shows the results of comparative experiments of the electron gun of the comparative example without the intermediate electrode, and the electron gun of the embodiment in which the cylindrical intermediate electrode provided integrally with the auxiliary support was electrically connected to the focusing electrode. The experiment was performed by applying the same voltage to the electron gun of the comparative example and the electron gun of the example.

Electron Beam Current (mA) Electron beam diameter (㎛) Comparative example Example Remarks One Center screen 200 198 Screen perimeter 282 267 5.3% improvement Peripheral / center beam diameter ratio 1.41 1.35 Uniformity Improvement 5 Center screen 265 263 Screen perimeter 368 352 4.3% improvement Peripheral / center beam diameter ratio 1.39 1.34 Uniformity Improvement

According to the above table, it can be seen that the electron gun of the present embodiment exhibits an electron beam reduction ratio of about 5% at the periphery of the screen while implementing an electron beam diameter equivalent to that of the conventional electron gun in the center of the screen, thereby improving image quality.

FIG. 9 is a cross-sectional view of a cathode ray tube equipped with the electron gun, and a projection type cathode ray tube which emits a single electron beam from an electron gun to realize a monochrome image will be described as an example.

Referring to the drawings, the cathode ray tube 38 includes a face panel 42 having a fluorescent film 40 formed on an inner surface thereof, a funnel 44 and a neck 32 positioned behind the face panel 42. The electron gun 2 having the above-described configuration is mounted inside the neck 32 to emit an electron beam toward the fluorescent film 40. On the outer circumference of the funnel 44, a deflection yoke 46 for generating a deflection magnetic field is mounted, and the deflection magnetic field deflects the electron beam emitted from the electron gun 2 so that the electron beam scans the fluorescent film 40.

The fluorescent film 40 is formed of a single color of red, green, and blue, and the inner surface of the face panel 42 in which the fluorescent film 40 is located is formed as a so-called reverse spherical surface convex toward the neck 32.

The projection display device (not shown) projects three projection type cathode ray tubes each displaying R (red), G (green), and B (blue) monochromatic screens, and monochromatic images implemented in these cathode ray tubes. An optical system (not shown) for magnifying and projecting onto a screen (not shown) is provided to implement a predetermined color image.

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

As described above, the electron gun according to the present invention gently induces the potential difference between the screen electrode and the first anode electrode by the intermediate electrode described above to suppress discharge failure. In addition, the electron gun according to the present invention has the effect of improving the image quality by reducing the electron beam mirror in the periphery of the screen.

Claims (20)

A cathode for emitting electrons; A plurality of electrodes including a control electrode, a screen electrode, an intermediate electrode, a first anode electrode, a focusing electrode, and a second anode electrode disposed at an arbitrary distance from the cathode; And A support for arranging and fixing the electrodes in a row; An electron gun for a cathode ray tube, wherein the intermediate electrode receives a voltage higher than a voltage applied to the screen electrode and lower than a voltage applied to the first anode electrode. The method of claim 1, An electron gun for a cathode ray tube, wherein the intermediate electrode receives a fixed voltage from a corresponding stem pin through a connector. The method of claim 1, An electron gun for a cathode ray tube, wherein the intermediate electrode is electrically connected to the focusing electrode through a connector to receive the same voltage as the focusing electrode. The method of claim 1, The intermediate electrode is an electron gun for a cathode ray tube consisting of a columnar hollow inside. The method of claim 4, wherein The intermediate electrode is an electron gun for the cathode ray tube, the auxiliary support is provided integrally on the outer surface. The method of claim 1, The intermediate electrode is a cathode ray tube electron gun including a bottom portion is formed with an electron beam through hole, and a columnar body portion which is connected to the edge of the bottom portion and hollow. The method of claim 6, The intermediate electrode is a cathode ray tube electron gun provided with an auxiliary support integrally on the outer surface of the body portion. The method of claim 1, The intermediate electrode is an electron gun for a cathode ray tube made of a plate shape having an electron beam through hole. The method of claim 8, The intermediate electrode is an electron gun for the cathode ray tube is provided with an integral support. The method according to any one of claims 4 to 9, And an electron gun for the cathode ray tube, wherein the intermediate electrode has an outer diameter equal to a maximum outer diameter of the first anode electrode or an outer diameter of the focusing electrode. The method according to any one of claims 4 to 9, An electron gun for a cathode ray tube, wherein the intermediate electrode surrounds a portion of the first anode electrode. The method of claim 1, An electron gun for a cathode ray tube, wherein the focusing electrode is divided into two or more focusing electrodes to form a gap between the divided focusing electrodes. The method of claim 12, At least one focusing electrode of the focusing electrodes forms a slit along a direction orthogonal to an electron beam traveling direction. The method of claim 1, An electron gun for a cathode ray tube, the electron gun having a single cathode to emit a single electron beam. A plurality of electrodes comprising a cathode and a control electrode, a screen electrode, an intermediate electrode, a first anode electrode, a focusing electrode, and a second anode electrode arranged at an arbitrary distance from the cathode, and the electrodes are arranged in a row An electron gun including a support fixed to the lens; A neck into which the electron gun is embedded; A funnel and a face panel positioned in front of the neck; A deflection yoke installed on an outer circumference of the funnel to generate a magnetic field for deflection of an electron beam; And It includes a fluorescent film formed on the inner surface of the face panel, A cathode ray tube receiving a voltage higher than the voltage applied to the screen electrode and lower than the voltage applied to the first anode electrode. The method of claim 15, And said electron gun comprises a single cathode and said fluorescent film is formed of any one of red, green and blue. The method of claim 15, Cathode ray tube formed in the inner surface of the face panel is convex toward the neck. The method of claim 15, Cathode ray tube is the intermediate electrode receives a fixed voltage from the stem pin through the connector. The method of claim 15, And the intermediate electrode is electrically connected to the focusing electrode through a connector to receive the same voltage as the focusing electrode. The method of claim 15, And the intermediate electrode is disposed to surround a portion of the first anode electrode and has an outer diameter equal to a maximum outer diameter of the first anode electrode or an outer diameter of the focusing electrode.

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