KR19980072339A - Cathode Ray Springs - Google Patents

Abstract

The present invention relates to a spring for a cathode ray tube, in particular, serves as a support for fixing the shadow mask assembly to the panel surface, and the high expansion side material and low expansion of the spring to correct the thermal displacement of the shadow mask by the electron beam close to the initial position The purpose of the present invention is to numerically quantify the position of the welding seam of the side material to improve the domming characteristics of the cathode ray tube and to reduce the manufacturing cost.

To this end, the present invention supports the frame to the stud pin mounted on the panel surface, the low-expansion material and the high-expansion material are configured to be in contact with each other to compensate for the thermal displacement of the shadow mask by the impact of the electron beam to perform a bimetal action In the spring for cathode ray tube, the welding seam of the low-expansion material and the high-expansion material of the spring is 0.35L to 0.65 from the bottom of the high-expansion material side so as to compensate the thermal displacement of the shadow mask to the maximum / optimum. It is located in the range of L.

Description

Cathode Ray Springs

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a cathode ray tube, and in particular, serves as a support for fixing a shadow mask assembly to a panel surface. The present invention relates to a spring for a cathode ray tube, which numerically quantifies the position of a welding seam, thereby improving the doming characteristic of the cathode ray tube and reducing manufacturing costs.

As shown in FIG. 1, a conventional cathode ray tube includes a panel 2 having R, G, and B fluorescent films 1 coated on its inner surface, and a funnel 3 fused to a rear end of the panel 2. ), An electron gun 5 encapsulated in the neck portion 4 of the funnel 3, and an electron beam 6 emitted from the electron gun 5 to strike the entire surface of the fluorescent film 1. A deflection yoke 7 for deflecting 6, a frame 8 supported inside the panel 2, and a slot or dot supported by the frame 8 to allow the electron beam 6 to pass therethrough. The shadow mask 9 arranged in the shape of a hole) and a spring 11 for fixing the frame 8 to the stud pins 10 mounted on the panel 2 surface.

As shown in FIG. 2, the spring 11 is composed of two kinds of materials having different thermal expansion coefficients, that is, a high expansion material 12 and a low expansion material 13, and a low expansion material ( 13) properties of bidirectional bending (bimetallic action) were used.

In the figure, ↑ is the fluorescent film direction, ↓ is the electron gun direction, → is the fluorescent film center direction, and ← is the fluorescent film peripheral direction.

When power is applied to the conventional cathode ray tube configured as described above, the electron beam 6 is emitted from the electron gun 5 inserted into the neck portion 4, and about 20% of the electron beam 6 emitted from the electron gun 5 The opening of the shadow mask 9 strikes the fluorescent film 1 to reproduce an image.

In addition, the remaining 80% of the electron beam 6 collides with the shadow mask 9 to cause thermal expansion, and due to thermal expansion of the shadow mask 9, doming in the fluorescent film direction as shown in FIG. As a phenomenon occurs, the landing of the electron beam 6 passing through the shadow mask 9 as shown in (b) of FIG. 3 moves toward the center of the fluorescent film.

After a certain time elapses, the frame 8 thermally expands in the peripheral direction of the fluorescent film, as shown in FIG. 3 (c). As a result, the shadow mask 9 moves in the electron gun direction, and passes through the shadow mask 9. Landing of the electron beam 6 is moved back to the peripheral direction of the fluorescent film as shown in (d) of FIG.

Thereafter, heat is transferred from the frame 8 to the spring 11, and the spring 11 has a bimetallic action caused by the transferred heat, so that the frame 8 and the shadow mask 9 are shown in FIG. ) Again to the fluorescent film direction, the landing of the electron beam (6) is gradually moved toward the center of the fluorescent film, as shown in Figure 3 (bar), after a certain time the incident energy As the and energy is balanced, the final stabilization phase is achieved without any further thermal displacement or landing changes.

However, in the conventional cathode ray tube, the ratio or shape of the low-expansion material and the high-expansion material was mainly determined by experiments and experiences, and the position and shape of the weld seam that maximized and optimized the compensation amount, and the stud pins. Since there is no quantified standard value regarding the position of the hole, it is difficult to apply to various materials, and there is a problem that the manufacturing cost increases due to many experiments.

In view of this point, the present invention provides that the position of the welding seam between the high expansion material and the low expansion material of the spring for the cathode ray tube is L in the range of 0.35 L to 0.65 L from the bottom of the high expansion material. The purpose is to improve the domming characteristics of the tube and to reduce the manufacturing cost.

1 is a longitudinal cross-sectional view of a typical cathode ray tube.

2 is a cross-sectional view of a spring for a conventional cathode ray tube.

3 is an operation diagram of a conventional cathode ray tube,

(A) is a cross-sectional view showing the dope step of the shadow mask.

(B) is sectional drawing which shows the landing state of the electron beam according to (a).

(C) is a cross-sectional view showing the thermal expansion step of the frame.

(D) is a sectional view showing the landing state of the electron beam according to (C).

(E) is sectional drawing which shows the correction | amendment step and stabilization step of a spring.

(Bar) is sectional drawing which shows the landing state of the electron beam as described in (e).

Figure 4 is a cross-sectional view of the spring for the cathode ray tube of the present invention.

Explanation of symbols on the main parts of the drawings

101: spring 102: high expansion material

103 low expansion material 104 weld seam

105: stud pin hole 106: welding point

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

4 shows a spring for a cathode ray tube according to the present invention, which serves as a support for fixing a frame (not shown in the drawing) to a stud pin attached to a panel surface, and the thermal displacement of the shadow mask by an electron beam to an initial position. The spring 101 for compensating to be close is composed of two materials having different thermal expansion coefficients, that is, the high expansion material 102 and the low expansion material 103 are in contact with each other, and the high expansion material 102 and the low expansion The joint welding line 104 of the material 103 is located within the range of 0.35L to 0.65L from the bottom of the high-expansion material 102 side, if the total width is L, and the spring 101 of the low-expansion / high-expansion welding raw material. In order to reduce the loss of raw materials during cutting, it is formed within the range of -10 ° to 10 ° with respect to the longitudinal direction of the spring 101, and the center of the stud pin hole 105 has a high expansion to increase the amount of thermal displacement compensation of the shadow mask. Located on the material 102 side The.

Reference numeral 106 denotes a welding point at which the spring 101 is welded to the frame.

Referring to the action of the spring for the cathode ray tube of the present invention configured as described in detail as follows.

First, when power is applied to the cathode ray tube, an electron beam is emitted from the electron gun, and the electron beam selectively passes through the opening of the shadow mask to strike the fluorescent film, thereby reproducing an image.

However, since only about 20% of the electron beam hits the fluorescent film, the remaining 80% collides with the shadow mask, causing thermal expansion, and a doming phenomenon occurs due to thermal expansion of the shadow mask. When the frame is thermally expanded, the shadow mask is firstly corrected, and then heat is transferred from the frame to the spring 101, and the spring 101 undergoes a bimetallic action by the transferred heat to fluoresce the frame and the shadow mask again. Secondary correction is performed in the direction of the film, and after a certain time, the incident energy and the emission energy are balanced to reach the final stabilization stage without any further thermal displacement or landing change.

At this time, the ratio combination of the high-expansion material 102 and the low-expansion material 103 of the spring 101 is numerically quantified to improve the domming characteristics of the cathode ray tube, and the spring 101 is quantified in terms of construction. Since it has a numerical value, the manufacturing process is reduced by reducing the experimental stage and work process.

As described above, the present invention improves the domming characteristics of the cathode ray tube by numerically quantifying the ratio combination of the high expansion material and the low expansion material of the spring, which performs the shadow mask correction role, and the spring is quantified in terms of construction. Since it reduces the experimental step and work process has the effect of reducing the manufacturing cost.

Claims (3)

In a spring for a cathode ray tube having a bimetal action, the frame is supported by a stud pin mounted on a panel surface, and a low-expanded material and a high-expanded material are in contact with each other to compensate for thermal displacement of a shadow mask caused by an electron beam strike. , The joint welding line of the low expansion material and the high expansion material of the spring is located within the range of 0.35L to 0.65L from the bottom of the high expansion material, if the total width is L, so as to compensate the thermal displacement of the shadow mask to the maximum and optimal. Spring for cathode ray tube, characterized in that. The method of claim 1, The hole center of the stud pin is a spring for cathode ray tube, characterized in that located on the high expansion material side to increase the amount of thermal displacement compensation of the shadow mask. The method of claim 1, The welding seam is a cathode ray tube spring, characterized in that formed in the range of -10 ° to 10 ° with respect to the longitudinal direction of the spring to reduce the loss of the raw material when cutting the spring in the low expansion / high expansion welding raw material.