KR200266525Y1 - Electron gun of color cathode ray tube_ - Google Patents

Abstract

The present disclosure relates to an electron gun of a color cathode ray tube in which a plurality of deflection yokes for deflecting and converging a plurality of electron beams emitted from a cathode in a horizontal and vertical direction are incorporated in a shield cup.

The disclosed subject matter includes a cathode for emitting a three-color electron beam, first to fifth lattice electrodes for controlling, accelerating, and converging the electron beam, and a shield cup for shielding an electron beam passing through the lattice electrodes from an external electromagnetic field. The horizontal coil and the vertical coil are wound a predetermined number of times so that the first to third deflection yokes having passages of the electron beam are disposed to be spaced apart from the electron beam through holes on the electron beam passage path in the shield cup, and are arranged on the arrangement line of the electron beam. The first to third deflection yokes are fixed by an electrical insulator installed across the inside of the shield cup so as to be parallel.

Accordingly, the cost and power consumption of the product is reduced compared to the prior art, and the tilt and misconvergence of the electron beam is minimized, thereby improving image quality.

Description

Electron gun of color cathode ray tube

The present invention relates to an electron gun of a color cathode ray tube, and more particularly, a plurality of deflection yokes for deflecting and converging a plurality of electron beams emitted from a cathode in a horizontal and vertical direction, respectively, are incorporated into a shield cup to reduce cost and improve image quality. An electron gun of a color cathode ray tube made compatible.

As is well known, color cathode ray tubes are the most widely used display devices for the observation of television oscillators, oscilloscopes, and radars.

The color cathode ray tube basically displays the information by landing the electron beam emitted from the electron gun on the fluorescent film, and typically uses an inline method in which the electron beams are arranged in one row to facilitate the adjustment of convergence.

As such an inline type color cathode ray tube, the shadow mask type color water tube shown in FIGS. 1 to 3 will be described as an example of the prior art.

The color water pipe is formed of a substantially rectangular glass panel 1, a funnel-shaped glass funnel 2 coupled to the panel 1, and a cylindrical shape which is successively provided at an end having a smaller diameter of the funnel 2. It is formed by the glass neck 3.

In addition, the panel 1 and the funnel 2 have a binding force increased by the reinforcing band 4, and the screen 5 including three-color phosphor layers emitting red, green, and blue light on the inner surface of the panel 1. ), And a shadow mask 6 for color screening is spaced apart from the screen 5 by a frame 7.

In addition, the frame 7 is coupled to the panel 1 through the spring 8, the inner shield 9 for shielding the external geomagnetism during the operation of the water pipe is fixed to the frame 7 is sealed with a high vacuum.

An electron gun 10 is installed in the neck 3 in an inline manner, and the electron gun 10 includes three cathodes 14 that emit three-color electron beams 11 of red, green, and blue, and the cathode 14. The first to fifth grating electrodes 15 to 19 are sequentially arranged at predetermined intervals by the glass beads 20 to be sequentially spaced apart from each other at a predetermined distance in order to control, accelerate, and focus the three-color electron beam 11.

A deflection yoke 12 is mounted on the outer side of the neck 3 side of the funnel 2 to generate a pincushion type horizontal deflection magnetic field and a barrel type vertical deflection magnetic field. A shield cup 21 having three-color electron beam through holes 22 is provided in the shielding to shield and weaken the leakage magnetic field and the external magnetic field of the deflection yoke 12, and the outer side of the neck 3 around the electron gun 10 CPM (Convergence Purity Magnet) 13 for color purity and color matching of the color electron beam 11 is mounted.

Reference numeral 23 in the figure is a stem pin for applying power to each electrode.

In the color receiver configured as described above, first, the three-color electron beam 11 emitted from the cathode 14 is controlled, accelerated and focused while passing through the first to fifth lattice electrodes 15 to 19, thereby providing one point of the screen 5. Focused on.

At this time, the misalignment of the three-color electron beam 11 caused by the misalignment of the three colors electron beam 11 caused by the concentration correction or the misalignment of the electrodes when the concentration of the three-color electron beam 11 is attempted to be focused on the screen Try to match one point.

Therefore, the three-color electron beams 11 arranged in a row have their paths precisely adjusted by the CPM 13 and are deflected in the horizontal and vertical directions by the horizontal deflection magnetic field and the vertical deflection magnetic field generated by the deflection yoke 12. do. As a result, when the three-color electron beam 11 reaches the screen 5 through the shadow mask 6, the three-color electron beam 11 is concentrated on the entirety of the screen 5, that is, the entire screen. Color images are displayed by vertical scanning.

In the above-described color cathode ray tube according to the prior art, the three-color electron beam 11 emitted from the electron gun 10 is focused by one point by the CPM 13 and the focused electron beam 11 is deflected yoke 12. It can be seen that the deflection in the horizontal and vertical directions by.

On the other hand, the current development of color cathode ray tube can be divided into shortening the depth from the panel to the neck and flattening the panel. Among them, the wide angle method that widens the deflection angle as a method for shortening the depth is widely used. The disadvantage is that more power is consumed.

Therefore, a method of reducing the diameter of the neck has been proposed at various times, and in fact, the diameter of the neck has been greatly reduced.

By the way, the deflection yoke according to the prior art as described above has a problem that acts as a factor in preventing this in reducing the diameter of the neck.

That is, as described above, the deflection yoke is mounted outside the neck side of the funnel and deflects the electron beam to the entire area of the screen. Under the same conditions, it is assumed that the diameter of the neck is too small to deflect the electron beam to the corner portion of the screen. At this time, the water pipe may be damaged by hitting the connection between the funnel and the neck.

In addition, the color cathode ray tube adopting the CPM and the deflection yoke according to the prior art increases the amount of tilt and mis-convergence of the electron beam at the corner portion of the screen as the screen gets closer to the plane. There is a problem of deterioration.

In addition, there is a problem in that large power is consumed in order to maintain the deflection sensitivity.

Accordingly, the present invention has been proposed to solve the problems of the prior art as described above, wherein a plurality of deflection yokes for deflecting and concentrating the plurality of electron beams emitted from the cathode in the horizontal and vertical directions, respectively, are embedded in the shield cup. By providing a tube electron gun,

First: by removing the deflection yoke mounted on the outside of the funnel and the CPM mounted on the outside of the neck, it is possible to reduce the diameter of the neck as much as possible while reducing the cost of the product.

Secondly, the image quality is improved by minimizing the tilt and misconvergence of the electron beam generated at the corners of the screen.

Third, the aim is to reduce the power consumption to maintain the deflection sensitivity.

1 is a partial cutaway cross-sectional view of a typical shadow mask type cathode ray tube,

2 is a configuration diagram of an electron gun embedded in the cathode ray tube illustrated in FIG. 1,

3 is a detailed configuration diagram of the shield cup shown in FIG.

4 is a partial cutaway cross-sectional view of the color cathode ray tube according to the present invention,

5 is a partial cutaway sectional view of an electron gun for a color cathode ray tube according to the present invention;

FIG. 6 is a detailed configuration diagram of the shield cup shown in FIG. 5.

<Explanation of symbols for the main parts of the drawings>

100: electron gun 110: shield cup

111: first deflection yoke 112: second deflection yoke

113: third deflection yoke 114: electron beam through hole

115: electrical insulator 116,117: power line

The electron gun of the color cathode ray tube according to the present invention for achieving the above object is passed through a cathode for emitting a plurality of electron beams, a plurality of grating electrodes for controlling, accelerating and converging the electron beams, In the color cathode ray tube having a shield cup for shielding the electron beams from an external electromagnetic field,

(1) horizontal and vertical coils are wound a predetermined number of times so that a plurality of deflection yokes having passages of the electron beams are disposed on the electron beam passage paths in the shield cup;

(2) The electron beams are deflected in a horizontal and vertical direction by a deflection magnetic field by the deflection yoke and are focused at one point.

Preferably, the electronic device further comprises an electrical insulator installed across the inside of the shield cup so as to be parallel to an arrangement line of the electron beams, wherein the plurality of deflection yokes are fixed by the electrical insulator.

Preferably, independent power is applied to each of the horizontal coil and the vertical coil.

Optionally, a through hole is formed in a side wall of the shield cup in which the electric insulator is installed, and a plurality of power lines passing through the through hole are insulated by the electric insulator and connected to the horizontal coil and the vertical coil, respectively.

Optionally, the plurality of power lines are connected to different stem pins, respectively.

In this way, since the plurality of deflection yokes built into the shield cup focus the plurality of electron beams at one point while deflecting them individually, a separate magnet for focusing the electron beam is not required, and the tilt of the electron beam generated at the corner of the screen and Miss convergence is minimized.

In addition, compared with the prior art, the power saving is reduced because the electron beam is deflected to the entire area of the screen in a more adjacent position.

And, there may be a plurality of embodiments of the present invention, the following will be described in detail with reference to the accompanying drawings for the most preferred embodiment.

Through this preferred embodiment it is possible to better understand the objects, features and advantages of the present invention.

In particular, the technology of the present invention can be applied to a variety of products using a cathode ray tube such as an oscilloscope or radar observation for a television receiver.

Thus, the drawings used in the description are not specific color cathode ray tubes, but focus on various cathode ray tubes such as shadow mask type color cathode ray tubes and trinitron color cathode ray tubes.

In addition, in drawing used for description, about the component same as FIG. 1 thru | or FIG. 3, the same code | symbol may be attached | subjected, and the overlapping description may be abbreviate | omitted.

In the following, an example applied to a shadow mask-type color receiving tube is considered to help understand the description.

Figure 4 is a partial cutaway cross-sectional view of the color cathode ray tube according to the present invention, Figure 5 is a partial cutaway cross-sectional view of the electron gun for color cathode ray tube according to the present invention, Figure 6 is a detailed configuration of the shield cup shown in FIG.

The electron gun 100 according to the embodiment of the present invention includes a cathode 14 for emitting the three-color electron beam 11 and first to fifth lattice electrodes 15 to 5 for controlling, accelerating and converging the electron beam 11. 19 and a shield cup 110 for shielding the electron beam 11 passing through the grating electrodes 15 to 19 from an external electromagnetic field, wherein the horizontal coil and the vertical coil are wound a predetermined number of times to produce an electron beam ( The first to third deflection yokes 111 to 113 having passages 11 are disposed to be spaced apart from the electron beam passing holes 114 at the bottom by a predetermined distance on the electron beam passing path in the shield cup 110. The first to third deflection yokes 111 to 113 are fixed by the electric insulator 115 installed across the inner side of the shield cup 110 so as to be parallel to the arrangement line of the shield cup 110. By the deflecting magnetic field by 111-113), they are deflected in the horizontal and vertical directions and are focused at one point.

In addition, a hole is formed in the side wall of the shield cup 110 in which the electric insulator 115 is installed, and the power lines 116 and 117 passing through the hole are insulated by the electric insulator 115 and have the first to third deflection yokes ( 111 to 113, respectively, connected to the horizontal coil and the vertical coil, and the power lines 116 and 117 are connected to different stem pins 23, respectively, and independent power is applied to the horizontal coil and the vertical coil, respectively.

In the electron gun of the color cathode ray tube according to the present invention configured as described above, when power is first supplied to each electrode from the stem pin 23, the three-color electron beam 11 is emitted from the cathode 14. It is controlled, accelerated and focused while passing through the 1st-5th grating electrodes 15-19.

In addition, independent power is supplied from the stem pin 23 to the horizontal coils and the vertical coils of the first to third deflection yokes 111 to 113 through the power lines 116 and 117, respectively. 11) A horizontal deflection field due to a horizontal coil and a vertical deflection field due to a vertical coil are generated on the pass path, respectively.

Therefore, each electron beam 11 passes through the electron beam through hole 114 formed in the bottom of the shield cup 110, and thus, the path of the electron beam 11 of the first to third deflection yokes 111 to 113, that is, the horizontal deflection magnetic field and While passing through the region of the vertical deflection field, it is deflected in the horizontal and vertical directions by Fleming's left-hand law, respectively.

Here, the windings of the horizontal coil and the vertical coil wound around the first to third deflection yokes 111 to 113 by a predetermined number of times are uniform, thereby forming a uniform magnetic field.

In addition, in the deflection circuit (not shown), the power supplied to the first to third deflection yokes 111 to 113 through the stem pin 23 and the power lines 116 and 117, that is, the sawtooth wave type deflection current, is used for each electron beam ( 11) Each has a different value.

Therefore, the deflection angle of each electron beam 11 is slightly different, so that the screen 5 at the tip of the deflection yoke 11 to 13 when the electron beam 11 is deflected to one point of the screen 5. Even if the arrival distances up to a point of) are different from each other, the respective electron beams 11 are correctly focused.

When the three-color electron beam 11 reaches the screen 5 through the shadow mask 6 by this process, the three-color electron beam 11 is concentrated on the entirety of the screen 5, that is, the entire screen, and is horizontal. Color images are displayed by scanning and vertical scanning.

On the other hand, unlike the conventional technique, that is, the electron beam is deflected by the deflection yoke mounted outside the neck side of the funnel as a comparative example, the present invention has a plurality of deflections embedded in the shield cup and located closer to the electron beam. It is understood that the yoke causes the plurality of electron beams to be deflected and focused individually.

As a result, according to the present invention, the same effect is obtained even if the number of turns of the horizontal and vertical coils wound on the deflection yoke is greatly reduced from the number of turns of the deflection yoke according to the prior art, and the CPM is essential in the prior art. Even if deleted, the function of the CPM is performed by the deflection yoke according to the present invention to obtain at least an equivalent effect.

Therefore, according to this application example, the CPM, that is, the electron beam focusing magnet, is not required, and thus the cost of the product is reduced, and since the deflection angle has a wide angle characteristic because the electron beams are deflected individually at the tip of the shield cup, the diameter of the neck Can be reduced as much as possible, and the tilt and misconvergence of the electron beam generated in the corner portion of the screen is minimized to improve the image quality.

In addition, compared with the prior art, since the electron beam is deflected to the entire area of the screen in a more adjacent position, the power consumption can be reduced, resulting in improved product reliability.

In addition, although specific embodiments of the present invention have been described and illustrated above, it will be apparent that various modifications may be made by those skilled in the art.

Such modified embodiments should not be individually understood from the technical spirit or the prospect of the present invention, and such modified embodiments shall fall within the appended utility model registration claims of the present invention.

The present invention as described above, the CPM is eliminated compared to the prior art, the cost of the product is reduced, and the power consumption for maintaining the deflection sensitivity is reduced because the electron beam is deflected at a closer position, the tilt and miss of the electron beam Minimizing convergence has the effect of improving image quality.

Claims (5)

A color cathode ray tube having a cathode for emitting a plurality of electron beams, a plurality of lattice electrodes for controlling, accelerating and concentrating the electron beams, and a shield cup for shielding the electron beams passing through the lattice electrodes from an external electromagnetic field. , (1) horizontal and vertical coils are wound a predetermined number of times so that a plurality of deflection yokes having passages of the electron beams are disposed on the electron beam passage paths in the shield cup; (2) The electron gun of the color cathode ray tube, wherein the electron beams are deflected horizontally and vertically by a deflection magnetic field by the deflection yoke and are focused at one point. The method of claim 1, (1) an electrical insulator installed across the inside of the shield cup so as to be parallel to the placement line of the electron beams, (2) The tank gun of the color cathode ray tube, wherein the plurality of deflection yokes are fixed by the electric insulator. The method of claim 1, Electron gun of the color cathode ray tube, characterized in that independent power is applied to the horizontal coil and the vertical coil. The method according to claim 1 or 2, (1) a through hole is formed in a side wall of the shield cup provided with the electrical insulator; (2) The electron gun of the color cathode ray tube, characterized in that the plurality of power lines passing through the through hole is insulated by the electrical insulator and connected to the horizontal coil and the vertical coil, respectively. The method of claim 4, wherein The electron gun of the color cathode ray tube, characterized in that the plurality of power lines are respectively connected to different stem pins.