KR20000033104A - Spring for color cathode ray tube - Google Patents

Abstract

PURPOSE: A spring for a color cathode ray tube is provided to compensate for a shadow mask inclination to a fluorescent membrane, to suppress howling of the mask, and to absorb the shock from outer space. CONSTITUTION: A spring for a color cathode ray tube includes a panel(2), a funnel(3), a neck (4), a vacuum container, and a support frame(8). A shadow mask with a curvature same to that of an inner part of the panel is fixed stationary to the support frame(8) with a predetermined distance. The side wall of the support frame(8) is welded to a support spring including a welder(101a), operator(101c) and a joint. The joint of the support spring is coupled with a stud pin(10) implemented in the inner wall of the support spring. The operator(101c) of the support spring is formed so as to tilt the supported spring in a direction of an axis and four directions of the cathode ray tube walls.

Description

Spring for Color Cathode

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a color cathode ray tube, and more particularly, to a spring structure for preventing a howling phenomenon caused by deformation of a mask due to external impact and sound pressure of a speaker.

As shown in FIG. 1, a general color cathode ray tube is fused to a panel 2 having a red, green, and blue fluorescent film 1 coated on an inner surface thereof, and fused to a rear end of the panel 2 to form an inside of the cathode ray tube. A funnel 3 holding in a vacuum state, an electron gun 5 enclosed in the neck portion 4 of the funnel 3 to emit an electron beam 6, and an electron beam 6 emitted from the electron gun 5. A deflection yoke (7) for deflecting the electron beam (6) to the entire area of the screen so as to strike the entire surface of the fluorescent film (1), and a shadow mask (9) which serves as color screening of the electron beam (6); And a frame 8 for maintaining the shadow mask 9 at regular intervals from the inner surface of the panel 2, and a spring 11 for supporting the frame 8 to the stud pins 10 disposed on the inner surface of the panel 2. It consists of.

Here, the spring 11 is a row of the frame welding portion 11a welded to the frame 8 and the stud pin mounting portion 11b and the shadow mask 9 mounted to the stud pin 10 as shown in FIGS. 2 and 3. Comprising a movable portion (11c) for compensating the deformation amount, is welded to the center of the long side and short sides of the frame (8) supporting the shadow mask (9) to compensate for the dominant amount of the shadow mask (9) due to thermal expansion during cathode ray tube operation At the same time it serves to support the mask frame structure to the panel (2).

In addition, the spring 11 is a plate-like structure having a total thickness of about 0.6 mm to 1.0 mm, the movable portion 11c of the spring 11 is bent at a constant angle (θ), the bending angle (θ) ) Is formed such that the frame welding portion 11a and the stud pin mounting portion 11b are parallel to each other when the spring 11 is mounted on the stud pin 10, and generally, the stud pin 10 and the outer wall of the frame 8 are parallel to each other. Determined by the spacing and the thickness of the spring 11.

Reference numeral 11d in the drawing denotes a stud pin hole.

When power is applied to the cathode ray tube in this configuration, the electron beam 6 is emitted from the electron gun 5 enclosed in the neck portion 4, and about 20% of the electron beam 6 is opened by the shadow mask 9. It passes through and reaches the fluorescent film 1, and reproduces an image.

On the other hand, the remaining 80% of the electron beam (6) collide with the shadow mask (9) surface, which causes the shadow mask (9) is thermally expanded to cause a dominant phenomenon (the shadow mask is swollen in the direction of the fluorescent film) In addition, a landing error ΔL is generated in the electron beam 6 passing through the shadow mask 9 due to the dope phenomenon of the shadow mask 9, thereby causing a color purity degradation on the screen.

The spring 11 is adopted to compensate for the dominant amount of the shadow mask 9 and to reduce the color purity degradation on the screen. When the shadow mask 9 is thermally expanded, the spring 11 is used as a shadow mask ( By compensating for the path displacement of the electron beam 6 due to thermal expansion of 9), the landing error of the electron beam 6 can be minimized to realize high quality.

Other functions of the spring 11 include a function of absorbing the impact amount when an external impact occurs to prevent deformation of the shadow mask 9, and suppressing howling due to sound pressure of the speaker, thereby reducing the amount of mis-landing of the electron beam 6 There is a function to minimize.

Of these, the durability test for specifically testing the external shock absorbing function of the spring 11 is a box packed with a set of a cathode ray tube built in a protective material at a height of 76 cm, the front and rear, top, bottom, left, right, corners and sides. In each drop test, as shown in FIG. 4, when the impact amount F due to the drop is applied, the frame 11 of the spring 11 that is welded and fixed to the frame 8 is applied. 11a) absorbs the impact amount by tilting in the X-axis and Y-axis directions (four surface directions of the cathode ray tube) due to the elastic force of the movable part 11c, thereby preventing the deformation of the shadow mask 9 of the thin film structure. .

In addition, as shown in FIG. 5, external vibration due to the sound pressure of the speaker is transmitted in the order of the panel 2, the spring 11, the frame 8, and the shadow mask 9. If the natural frequency coincides with the structure, resonance occurs and the vibration amplitude of the shadow mask 9 becomes large (howling phenomenon). As a result, the shadow mask 9 vibrates, causing streaks to appear on the screen. The howling phenomenon is minimized by forming the spring 11 on the top to absorb or disperse the vibration amount.

However, in the conventional color cathode ray tube, the impact caused by the drop in the four plane directions, i.e., the up, down, left, and right directions of the cathode ray tube is applied in the course of dropping the four surfaces (up, down, left, right), sides, and angles (edges) to the bottom. In the case of losing, the drop direction is parallel to the tilting direction of the spring, which allows the buffering effect due to the tilting effect of the spring.However, when the impact is applied in the tube axis direction (Z-axis direction) of the cathode ray tube, the movable part of the spring has a plate-like structure. Since there is little tilting effect of the spring, the impact amount is easily transmitted to the shadow mask, and there is a problem in that the permanent deformation of the shadow mask is severe.

In particular, this problem becomes more serious as the cathode ray tube is flattened and the mechanical strength of the shadow mask is lowered.

In addition, even when the cathode ray tube is in operation, when a shock applied from the outside of the cathode ray tube or a sonic shock due to the sound pressure of the speaker is applied, the entire surface of the spring has a plate-like structure having a single thickness. The natural frequencies of all of the pin mounting parts are the same (the natural frequencies of the frame welding part, the moving part, and the stud pin mounting part are f, f ', f ", and f ≒ f' ≒ f"). A phenomenon in which color purity was degraded on the screen by being easily transmitted along the path from the mounting part to the movable part to the frame welding part to the frame mask to resonate the shadow mask.

In order to solve this problem, a method of properly adjusting the thickness of the spring is used or a beveled bead is formed on the surface of the movable part of the spring as described in Japanese Patent Application Laid-Open No. 9-167574 to compensate for the shadowing amount of the shadow mask and tilt the tube in the tube direction Although the effect was given, the amount of tilting was very small and the whole could not be satisfied.

The present invention has been proposed in view of the above, and provides a spring capable of satisfying both the dominant amount compensation function of the mask, the suppression of howling of the mask by the sound pressure of the speaker, and the like to absorb external shock such as free fall. There is a purpose.

In order to achieve the above object, the present invention supports the mask frame structure to the stud pins on the inner surface of the panel, the frame welding portion welded to the side of the frame, the stud pin mounting portion mounted on the stud pins on the inner surface of the panel, and the frame welding portion as the apex. In the spring for the color cathode ray tube consisting of a movable portion that tilts in a direction perpendicular to the side wall of the frame, the movable portion is formed in a bar shape so that the spring can be tilted in the four-plane direction and the tube axis direction of the cathode ray tube, but the frame welding portion and stud pin Characterized in that the mounting portion and the natural frequency is configured differently.

1 is a block diagram of a general color cathode ray tube.

Figure 2 is a plan view showing a state in which the mask frame structure of the conventional color cathode ray tube coupled to the panel.

Figure 3 is a side view of the mask frame structure of a conventional color cathode ray tube.

Figure 4 is a three-dimensional view showing the structure and operation of a spring for a conventional color cathode ray tube.

5 is a detailed view showing a vibration transmission path of a conventional color cathode ray tube.

Figure 6 is a plan view showing the natural frequency characteristics of each portion of the spring for a conventional color cathode ray tube.

7 is a spring for a color cathode ray tube according to the present invention;

(A) The top view.

(B) side view.

8 is a cross-sectional view taken along line AA ′ of FIG. 7;

9 is a plan view of the mask frame structure to which the spring is applied according to the present invention.

10 is a three-dimensional view showing the structure of a spring for color cathode ray tube according to the present invention.

11 is a plan view showing the natural frequency characteristics of each portion of the spring for color cathode ray tube according to the present invention.

12 is another exemplary view of the present invention.

(A) is development shape after blanking.

(B) is the process of forming the movable part.

*** Explanation of symbols for main parts of drawing ***

101: spring 101a: frame welding portion

101b: stud pin mounting portion 101c: movable portion

101d: Stud Pin Hole

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

7 is a configuration diagram of a spring for a color cathode ray tube according to the present invention, which includes a frame welding portion 101a welded to the frame 8, a stud pin mounting portion 101b mounted to the stud pin 10, and an elastic section. The movable portion 101c has a tilting action, and the spring 101 has a rod-like shape so that the spring 101 can be tilted not only on the four sides of the cathode ray tube but also in the tube axis direction.

Here, the movable portion 101c is bent to have a predetermined angle θ with the frame welding portion 101a, and the bending angle θ is a distance between the outer wall of the frame 8 and the stud pin 10 and the spring ( 101) is determined according to the thickness. In addition, the end of the stud pin mounting portion side of the movable portion (101c) is bent to have a predetermined angle (θ ') with the stud pin mounting portion 101b, the bending angle (θ') is the spring 101 is stud pin (10) When coupled to the) is determined so that the frame welding portion (101a) surface and the stud pin mounting portion (101b) surface is parallel.

The cross-sectional shape of the movable portion 101c may be a circle, a square or an ellipse with a similar ratio of W and H when the width is "W" and the height is "H" as shown in FIG. 8, and 0.3≤H / W≤ Determined to satisfy the inequality of 3.

Determination of the H / W ratio is required in the X-axis and Y-axis directions (four-side direction of the cathode ray tube) of the spring 101 in consideration of the weight of the shadow mask 9 and the frame 8 within the above range. The elastic force must be determined and the required elastic force in the Z-axis direction (tube direction) due to the drop impact must also be considered.

In addition, the movable portion 101c should be configured to have the same cross section in its entire length so that stress is not concentrated, and the thickness of the movable portion 101c is thicker than the plate-shaped frame welding portion 101a and the stud pin mounting portion 101b. It should be different from the natural frequencies of the frame welding portion 101a and the stud pin mounting portion 101b.

Reference numeral 101d in the drawing denotes a stud pin hole.

In this case, when the drop impact Fz of the Z component acts in the tube axis direction, that is, the Z axis direction of the cathode ray tube, as shown in FIGS. 9 and 10 in the drop test process of the cathode ray tube, the shadow mask 9 and the frame 8 The impact load of) is transmitted to the movable portion 101c through the frame welding portion 101a of the spring 101, and the movable portion 101c is tilted in the Z-axis direction by the transmitted load, thereby transmitting the impact load by the damping effect. Can be gradually absorbed and extinguished so that the deformation of the shadow mask 9 can be prevented. In the drop test, the drop impacts (Fx, Fy, Fd) have four sides (up, down, left, right), sides, and the like with respect to the cathode ray tube. When acting in the angular (corner) direction, the impact loads of the shadow mask 9 and the frame 8 transmitted to the spring 101 are transmitted as the sum of the vectors with the X, Y, and Z axes. Force of the vector of the impact load transmitted by the movable portion 101c of the spring 101 By tilting in the same direction as the damping action it is possible to absorb and extinguish the impact load.

In addition, when a mechanical shock or a sound wave shock of a speaker is applied during operation of the cathode ray tube, the vibration amount is transmitted in the order of panel → stud pin → spring → frame → shadow mask to cause a howling phenomenon, but as shown in FIG. The vibrations of the stud pin mounting portion 101b and the frame welding portion 101a, which have the same thickness as the plate structure, and the natural frequency f 'of the movable portion 101c composed of cylindrical rods are different from each other. The wavelength and amplitude of the frequency are absorbed or dispersed almost all over the spring 101, and only a very small amount or high frequency and low amplitude sound wave is transmitted to the mask frame structure so that the shadow mask 9 does not have a howling phenomenon.

Thus, the howling phenomenon of the shadow mask 9 can be prevented by differently configuring the natural frequency of the frame welding part 101a, the stud pin mounting part 101b of the spring 101, and the movable part 101c.

12 shows another embodiment of the present invention, in which the frame welding portion 101a, the movable portion 101c, and the stud pin mounting portion 101b constituting the spring 101 are integrally blanked by using a plate of a single thickness. After the fabrication is made into a developed shape, the movable portion 101c is rolled in the direction perpendicular to the length to form a rod shape.

Such a method eliminates manufacturing cost by fabricating the movable portion 101c by a separate bar, and eliminating manufacturing inconvenience in that both ends of the movable portion 101c are welded with the frame welding portion 101a and the stud pin mounting portion 101b, respectively. It is possible to reduce the cost and shorten the manufacturing process.

As described above, in the present invention, since the spring can be tilted not only on the four sides of the cathode ray tube but also in the tube axis direction by constituting the movable part of the spring, the damping effect is maximized to prevent the permanent deformation of the shadow mask due to the drop impact. It is possible to block the transmission path of vibration by differentiating the natural frequencies of the frame welding part stud pin mounting part and the moving part of the spring. Therefore, it is possible to suppress the resonance phenomenon of the shadow mask due to external shock or sound wave vibration of the speaker during operation of the cathode ray tube. It can be effective.

Claims (5)

A vacuum container consisting of a panel, a funnel, and a neck forming an outline, and a shadow mask having a curvature similar to the shape of the inner surface of the panel, are fixed to the support frame at a side end thereof with a predetermined distance from the inner surface of the panel. In the color cathode ray tube, wherein the side wall portion of the support frame is welded with a welded portion of the support spring consisting of a welded portion and a joining portion formed with a movable portion and a coupling hole, and the joining portion of the support spring is engaged with a stud pin provided on the inner wall of the panel. The spring for the color cathode ray tube, characterized in that the movable portion is formed in the bar shape so that the support spring can be tilted in the four-direction direction and the tube axis direction of the cathode ray tube, the weld and the coupling portion and the natural frequency. The method of claim 1, The spring for the color cathode ray tube, characterized in that the movable portion is configured in the same cross-sectional shape in the entire length. The method according to claim 1 or 2, When the width of the cross-section of the movable portion W, the height H is characterized in that it is configured to satisfy the inequality of 0.3≤H / W≤3. The method of claim 1, The spring for the color cathode ray tube, characterized in that the movable portion is thicker than the thickness of the welded portion and the coupling portion. The method of claim 1, The welding spring, the movable portion, the coupling portion of the support spring is integrally formed as a single material, but the movable portion is rolled in a direction perpendicular to the length of the rod-shaped spring characterized in that the resonant frequency is different from the weld and the coupling portion.