KR0166872B1 - Main lens structure for electronic gun in color cathode tub - Google Patents

Abstract

The present invention relates to the structure of the main lens portion of the electron gun for the color cathode ray tube, the burring shape formed in the diaphragm of the fifth electrode and the sixth electrode constituting the main lens portion is different between the central electron beam and the outer electron beam during operation of the color cathode ray tube As the difference in astigmatism is compensated for, the spot size of each beam is kept constant with each other so that the screen state of the screen is always clear.

To this end, the present invention is provided with a fifth electrode diaphragm in which the fifth electrode beam through hole is formed in the inline direction by being spaced apart from the rim in the fifth electrode body, and in the sixth electrode body, the rim is spaced apart from the rim. The sixth electrode diaphragm having three sixth electrode beam through holes formed in an inline direction is provided, and the fifth electrode diaphragm is formed with a fifth electrode burring connected to each of the fifth electrode beam through holes. In the sixth electrode burring is formed to be connected to each of the sixth electrode beam through hole, at least one of the three burrings formed on the fifth electrode plate and the sixth electrode diaphragm is formed in a pair in parallel to one direction will be.

Description

Main lens unit structure of electron gun for color cathode ray tube

1 is a longitudinal sectional view showing a colored cathode ray tube by reference.

2 is a perspective view showing a part of the conventional main lens section of the electron gun for color cathode ray tubes.

3 is a perspective view showing a diaphragm constituting a conventional main lens portion of an electron gun for a color cathode ray tube.

4 is a beam spot shape diagram of a conventional main lens unit of a color cathode ray tube electron gun;

5 is a perspective view showing a part of the main lens of the present invention of the electron gun for a color cathode ray tube.

6 is a perspective view showing an embodiment of a diaphragm constituting a conventional main lens portion of an electron gun for a color cathode ray tube.

7 is a beam spot shape diagram of the main lens unit of the present invention of the electron gun for color cathode ray tubes.

* Explanation of symbols for main parts of the drawings

71: fifth electrode body 72: rim

73: fifth electrode beam through hole 74: fifth electrode diaphragm

75: fifth electrode burring 81: sixth electrode cylinder

82: figure 83: sixth electrode beam through hole

84: sixth electrode diaphragm 85: sixth electrode burring

The present invention relates to the structure of the main lens portion of the electron gun for color cathode ray tube, more specifically, the diaphragm structure of the fifth electrode and the sixth electrode constituting the main lens portion, the operation between the central electron beam and the outer electron beam during operation of the color cathode ray tube The difference between the astigmatism of is compensated for.

In general, the color cathode ray tube has a bulb shape in which a panel 1 and a funnel 3 having neck portions 2 are integrated with each other as shown in FIG. Form is formed, the neck portion (2) has a built-in electron gun to emit red, green, blue three-color electron beam, an electron gun on the outer peripheral surface of the neck portion (2) of the funnel (3) A deflection yoke 4 is provided to deflect the electron beam emitted in the horizontal and vertical directions, and a frame 5 is supported by a plurality of support springs 6 inside the panel 1. On the side of the funnel 3, an inner shield 7 is fixed to prevent the electron beam emitted from the electron gun from being deformed by a geomagnetic field or a leaking magnetic field, and the panel of the frame 5 1) To pass a part of the electron beam emitted from the electron gun on the side A shadow mask 8 having a large number of holes formed therein is fixed, and an inner surface of the panel 1 is formed so that an image is formed when an electron beam passing through the shadow mask 8 strikes. The graphite film 10 is successively applied to the inner surface of the funnel 3 and a part of the inner surface of the neck 2 so as to apply a high pressure with an electron gun.

The electron gun is supported by the cathode support 11, three cathodes 12 for generating red, green, and blue electron beams respectively under high pressure, and a first one for accelerating each electron beam generated from the three cathodes. An electrode 13 and a second electrode 14, a third electrode 15 and a fourth electrode 16 serving as an auxiliary lens to focus the electron beams accelerated by the first and second electrodes, and the first, The fifth electrode 17 and the sixth electrode 18 serving as the main lens to focus the electron beam accelerated from the two electrodes, the cathode support 11 and the electrodes 13, 14, 15, and 16. (17) (18) and a pair of beadgrass (19) for integrating the shield cup (20) fixed to the upper end of the sixth electrode (18) to protect the electron beam emitted by acceleration and focus from the geomagnetic field (20) ) And fixed to the outer circumferential surface of the shield cup to apply high pressure to the shield cup 20 and to support the electron gun to the neck part 2 during assembly. It consists of the several leaf spring 21 which plays a role.

Thus, the three cathodes 12 supported by the cathode support 11 and the first, second, third, fourth, fifth, and sixth electrodes 13, 14, 15, 16, 17, 18 and shield When a high pressure is applied to the cup 20, a three-color electron beam of red, green, and blue is generated at the cathode 12, and the generated three-color electron beam is accelerated by the first electrode 13 and the second electrode 14. Next, the light is focused and radiated by the third electrode 15 and the fourth electrode 16 serving as the auxiliary lens, and the fifth electrode 17 and the sixth electrode 18 serving as the main lens. The shield cup 18 fixed to is applied with a high pressure from the graphite film 10 to protect each electron beam emitted from the geomagnetic field.

Then, the process of the three-color electron beam emitted from the electron gun hits the screen 9 formed on the inner surface of the panel 1 to reproduce the color screen will be described in detail.

The three-color electron beam emitted from the electron gun is deflected in the horizontal and vertical directions by the magnetic field of the deflection yoke 4 provided on the outer circumferential surface of the neck portion 2 of the funnel 3, whereby the funnel 3 side of the frame 5 The fixed inner shield 7 prevents the path of the electron beam from being deformed on the way by preventing the support system or the leakage magnetic field of the three-color electron beam continuously radiated in a deflected state.

On the other hand, most of the emitted electron beam (about 80%) is scattered by the shadow mask 8 fixed on the panel 1 side of the frame 5, and only a part (about 20%) passes through the hole drilled in the shadow mask. Since it hits the screen 9 formed on the inner side of the panel 12, a color screen is reproduced by a combination of three color electron beams.

In the electron gun constituting such a color cathode ray tube, the fifth electrode 17 and the sixth electrode 18 serving as the main lens unit to focus the electron beams accelerated by the first and second electrodes, which are the acceleration electrodes, are the conventional electrodes. As shown in FIGS. 2 to 3, the lens unit is an opposing surface of the fifth electrode body 71 and the sixth electrode body 81, which is common to the three-color electron beams, and has an inline direction (horizontal direction). Race track-shaped transverse rims 72 and 82 which are larger than the direction perpendicular to the inline (vertical direction) are formed, respectively, and are spaced apart from the rim 72 by a predetermined distance within the fifth electrode cylinder 71. The fifth electrode diaphragm 74 having five fifth electrode beam through holes 73 formed in the in-line direction is provided, and the sixth electrode cylinder 81 is spaced apart from the rim 82 by three intervals. A sixth electrode diaphragm 84 having a six-electrode beam passing hole 83 formed in an inline direction is provided. The fifth electrode burring 75 is formed in the diaphragm 74 so as to be connected to the same diameter as the fifth electrode beam through hole 73, and the sixth electrode diaphragm 84 has each sixth electrode beam through hole 83 formed therein. The sixth electrode burring 85 is formed to be connected to the same diameter as that of the sixth electrode.

Therefore, as described above, when the color cathode ray tube is operated, the electron beams accelerated and emitted from the first and second lenses 13 and 14 are arranged in parallel in the same plane, and thus the electron beam passages 22, 22a and 22b. Is focused while passing through the third electrode 15 and the fourth electrode 16 constituting the auxiliary lens unit, followed by the fifth electrode 17 and the sixth electrode 18 constituting the main lens unit. Incident.

As described above, the three electron beams incident on the main lens unit are axially symmetrical with respect to the center electron beam, so that the center electron beam is formed on the fifth electrode diaphragm 74 constituting the fifth electrode 17. The sixth electrode beam through hole located in the middle of the sixth electrode beam through hole 83 formed in the sixth electrode diaphragm 84 constituting the sixth electrode 18 and the fifth electrode beam through hole located in the middle of the through hole 73. Concentrated and narrowly condensed, and an asymmetric main lens portion is formed at both portions of the fifth electrode 17 and the sixth electrode 18 so that both electron beams passing through the portion may pass through the fifth electrode 17. On the sixth electrode diaphragm 84 constituting the fifth electrode beam through hole and the sixth electrode 18 positioned on both left and right sides of the fifth electrode beam through hole 73 formed on the fifth electrode diaphragm 74. The sixth electrode beam through holes located at both left and right sides of the sixth electrode beam through holes 83 are continuously passed. At the same time, the three-color electron beams are concentrated to overlap each other at one point of the shadow mask 8, so that the screen 9 of the panel 1 is accelerated to display colors. do.

The two most important and important considerations in the design of the main lens of the cathode ray tube electron gun are the astigmatism of the three-color electron beam and the astigmatism of the outer electron beam. Astigmatism is the difference in the focusing force between the horizontal and vertical directions of the electron beam. Is converted to the difference of the percussion voltage when it is optimally focused, and is positive when the horizontal direction has a larger focusing force than the vertical direction.

In addition, the convergence characteristic refers to a characteristic in which the outer electron beam gathers toward the center electron beam.

Therefore, when the structural design of the main lens unit satisfies the astigmatism and convergence characteristics, the fifth electrode beam through hole 73 formed in the fifth electrode diaphragm 74 and the sixth electrode beam formed in the sixth electrode diaphragm 84. The aperture of the through-hole 83 should be increased. In this case, the large-diameter main lens portion, which can reduce the spot size on the screen due to the reduction of spherical aberration, acts on the lens by the transverse rims 72 and 82 facing each other. The horizontal force is formed in a state in which the focusing force is smaller than the vertical, and thus the fifth electrode diaphragm 74 is provided at a predetermined interval apart from the rim 72 and the sixth electrode diaphragm 84 is provided at the rim 82. The fifth and sixth electrode diaphragms 74 and 84 are divided into respective lenses with respect to the three-color electron beam to form astigmatism design and convergence design. The main design elements at this time are each diaphragm ( 74) the boiling point according to the position of the diaphragm as the position of 84 Aberrations and convergences vary greatly.

However, it is impossible to compensate for the difference in astigmatism between the central electron beam and the outer electron beam of the fifth electrode 17 and the sixth electrode 18 in the above design. Even if it can be satisfied, it is difficult to satisfy the convergence characteristics of the outer electron beam. Accordingly, the fifth electrode beam through hole 73 of the fifth electrode 17 and the sixth electrode beam through hole of the sixth electrode 18 ( 83, the beam spot on the screen 9 due to the astigmatism difference between the center electron beam and the outer electron beam appears as shown in FIG. 4 a). It can be seen that the astigmatism of the electron beam spot becomes larger than that of the central electron beam spot, and the fifth electrode beam through hole 73 of the fifth electrode 17 and the sixth electrode beam through hole of the sixth electrode 18. Out of (83) If the setting point is set on the basis of the beam passing hole, the beam spot on the screen 9 due to the astigmatism difference between the center electron beam and the outer electron beam appears as shown in FIG. 4 b), and consequently, the astigmatism of the center electron beam spot. It can be seen that is larger than the astigmatism of the outer electron beam spot.

However, the difference between the astigmatism of the center electron beam spot and the astigmatism of the outer electron beam spot is generated according to where the setting point is set as described above. Therefore, the size of each beam spot is not constant. As a result, there was a problem that the screen state is not clear.

The present invention has been made to solve the above problems, by varying the burring shape formed on the diaphragm of the fifth electrode and the sixth electrode constituting the main lens portion, the astigmatism between the central electron beam and the outer electron beam during operation of the color cathode ray tube ( As the difference is compensated for, the spot size of each beam is kept constant with each other, and the screen state of the screen is always displayed clearly.

According to an embodiment of the present invention for achieving the above object, the sixth electrode is provided with a fifth electrode diaphragm in which the fifth electrode beam through hole is formed in an inline direction and spaced apart from the rim in a fifth electrode cylinder. The sixth electrode diaphragm having three sixth electrode beam through holes spaced apart from the rim by a predetermined distance and formed in an inline direction is provided, and the fifth electrode diaphragm is formed by the fifth electrode diaphragm having the same diameter as that of the fifth electrode beam through holes. The five-electrode burring is formed and the sixth electrode diaphragm has sixth electrode burrings connected to the same diameter as the sixth electrode beam through hole, and each of three burrs formed on the fifth electrode diaphragm and the sixth electrode diaphragm. There is provided a main lens portion structure of an electron gun for the present invention color cathode ray tube formed in pairs of at least one burring in a pair.

Hereinafter, the present invention will be described in more detail with reference to FIGS. 5 to 6 of the accompanying drawings.

5 is a perspective view showing a part of the present invention main lens portion of a color cathode ray tube electron gun, and FIG. 6 is a perspective view showing an embodiment of a diaphragm constituting a conventional main lens portion of a color cathode ray tube electron gun, the present invention is a fifth electrode Race track-like sill type 72 which is common to three-color electron beams and is larger than an inline direction (horizontal direction) orthogonal to the inline direction (vertical direction) as opposed to the cylinder 71 and the sixth electrode cylinder 81. The fifth electrode diaphragm 82 is formed, and the fifth electrode cylinder 71 has three fifth electrode beam through holes 73 formed in the in-line direction, spaced apart from the rim 72 by a predetermined distance. A sixth electrode diaphragm 84 having three sixth electrode beam through-holes 83 formed in the in-line direction with a 74 and spaced apart from the rim 82 in the sixth electrode tube 7. ) Is provided, and the fifth electrode diaphragm 74 has respective fifth electrodes. A fifth electrode burring 75 integrally connected to the same diameter as the through hole 73 is formed, and the sixth electrode diaphragm 84 is integrally connected to the sixth electrode beam through hole 83 with the same diameter. In the sixth electrode burring 85 is formed, at least one pair of burrings each of the three burrings 75 and 85 formed on the fifth electrode diaphragm 74 and the sixth electrode diaphragm 84 is a pair. While forming a side by side in the inline direction or a side by side in the direction orthogonal to the inline direction or a structure.

The operation and effects of the present invention configured as described above are as follows.

The main lens unit has one opening common to the three-color electron beam at opposite portions of the fifth electrode 17 and the sixth electrode 18 so that the inline direction (horizontal direction) is perpendicular to the inline direction (vertical direction). As the larger horizontal shape is used, the main lens portion causes the horizontal focusing force to be much smaller than the vertical focusing force, thereby causing deterioration in focus performance on the screen 9.

In order to compensate for this problem, the fifth electrode diaphragm 74 and the sixth electrode diaphragm 84 constituting the fifth electrode 17 are spaced apart at predetermined intervals from each rim 72, 82. 74 and 84 serve to distinguish the lenses of the three-color electron beams.

Accordingly, the present invention is directed to three beam through holes 83 formed in the sixth plate 84 as shown in FIG. 6A when the astigmatism of the central electron beam by the main lens unit is smaller than that of the outer electron beam. A pair of burrings 85 integrated in a row are vertically formed in a direction orthogonal to the in-line direction by pairing only the burrings integrated in the center beam passing hole or formed in the fifth plate 74 as shown in FIG. If a pair of burrings 75 integrated in succession to the three beam passing holes 73 are formed horizontally in the in-line direction using only a pair of burrings integrated into the center beam through hole, the lens action of the central electron beam is more focused than the vertical. This strongly increases the astigmatism of the central electron beam, and as a result, the astigmatism of the central electron beam and the outer electron beam appears to be the same, so that each beam hits the screen 9. The spot size is constant.

In addition, when the astigmatism of the outer electron beam by the main lens unit is smaller than the astigmatism of the central electron beam, it is integrated in succession to three beam through holes 83 formed in the sixth plate 84 as shown in FIG. Only a pair of burrings which are integrally connected to the beam passing holes on the left and right outer sides of the burring 85 are vertically formed in a direction orthogonal to the in-line direction, or as shown in FIG. 6 d) to the fifth plate 74. If only a pair of burrings 75 integrated with the left and right outer beam passing holes are formed horizontally in the in-line direction, the lens action of the outer electron beam is horizontal. As the focusing force is stronger than the vertical, the astigmatism of the outer electron beam is increased, and as a result, the astigmatism of the center electron beam and the outer electron beam appears to be the same, so that each beam is attached to the screen 9. When the hill and the spot size is constant.

As described above, any one of the shapes of a), b), c) and d) of FIG. 6 may be selected and applied to the fifth electrode 17 constituting the main lens unit or the sixth electrode 18. Although not limited thereto, one shape may be applied to the fifth electrode 17 according to the astigmatism difference value between the central electron beam and the outer electron beam, and one shape may be applied to the sixth electrode 18. ) May be applied.

On the other hand, when the amount of convergence of the outer electron beam is reduced, in order to satisfy the convergence, in order to satisfy the above convergence, a pair of ones integrated into the left and right outer beam passing holes are applied while the shape of d) of FIG. 6 is applied to the fifth electrode 17. During the burring, the inner burring is made shorter than the outer burring (see FIG. 6 e)), and the beam through hole in the outer left and right sides with the shape of FIG. 6 d) applied to the sixth electrode 18. If the outer burring is shorter than the inner burring of the pair of integrated burrings (see FIG. 6 f), the convergence amount of the outer electron beam is increased, and conversely, when the convergence amount of the outer electron beam is increased, the convergence is increased. In order to satisfy the condition of FIG. 6, d) of FIG. 6 is applied to the fifth electrode 17, the outer burring is shorter than the inner burring among the pair of burrings integrated in the left and right outer beam passing holes. With See Fig. 6 (f)). In the state where the shape of Fig. 6 (d) is applied to the sixth electrode 18, one of the pairs of burrings integrated with the beam passing hole on the left and right outer sides is replaced with the outer burring. In short (see FIG. 6 e), the amount of convergence of the outer electron beam is reduced, resulting in an adjustment of the amount of convergence.

In summary, when the diaphragm is applied to the fifth electrode 17 in a state where a pair of burrings formed on the diaphragm are formed horizontally, the astigmatism of the main lens unit increases and the sixth When applied to the electrode 18, the astigmatism of the main lens portion is reduced, and when the diaphragm is applied to the fifth electrode 17 while a pair of burrings formed in the diaphragm are formed vertically, the astigmatism of the main lens portion is reduced. In addition, when applied to the sixth electrode 18, astigmatism of the main lens unit increases.

Therefore, the present invention can compensate for the difference in astigmatism between the central electron beam lens and the outer electron beam lens of the large-diameter main lens, so that the astigmatism of the three-color electron beam is the same while the cathode ray tube is operated, so that the set point is adjusted to anywhere. The spot size when the three-color electron beam hits the screen is also the same as in FIG. 7 regardless of whether or not it is, thereby improving the focus performance and the convergence performance, thereby providing a clean screen at all times.

Claims (7)

A fifth electrode diaphragm having three fifth electrode beam through holes formed in an in-line direction by being spaced apart from the rim in a fifth electrode cylinder is provided, and the sixth electrode cylinder is spaced apart from the rim by three intervals in the sixth electrode cylinder. A sixth electrode diaphragm having an electrode beam through hole formed in an inline direction is provided, and a fifth electrode burring is formed in the fifth electrode diaphragm so as to be connected to each fifth electrode beam through hole. The sixth electrode burring is formed in succession to the beam passing hole, the color cathode ray characterized in that the burring of at least one of the three burrings formed on the fifth electrode plate and the sixth electrode diaphragm are formed in a pair and side by side in one direction. Main lens unit structure of the conventional electron gun. The main lens unit structure of the electron gun for color cathode ray tube according to claim 1, wherein a pair of burrings integrated in a central beam through hole among the three burrings is formed in a vertical direction in a direction perpendicular to the inline direction. 2. The main lens unit structure of the electron gun for color cathode ray tube according to claim 1, wherein the burrs are horizontally formed in an in-line direction by pairing only the burrings integrated in a central beam through hole among the three burrings. The main lens unit structure of the electron gun for color cathode ray tube according to claim 1, wherein the pair of burrings are vertically formed in a direction orthogonal to the in-line direction by pairing only the burrings integrated with the beam passing holes at the left and right outer sides. The main lens unit structure of an electron gun for a color cathode ray tube according to claim 1, wherein one of the three burrings is formed horizontally in an inline direction by pairing only the burrings integrated with the beam passing holes on the left and right outer sides. The main lens unit structure of the electron gun for color cathode ray tube according to claim 5, wherein the length of the inner burring is shorter than the length of the outer burring among the pair of burrings horizontally formed in the inline direction on the left and right outer sides. The main lens unit structure of the electron gun for color cathode ray tube according to claim 5, wherein the length of the outer burring is shorter than the length of the inner burring among the pair of burrings horizontally formed in the inline direction on the left and right outer sides.