KR19990011198A - Vibration Damping Device for Flat Tension Mask - Google Patents

Abstract

The present invention relates to a vibration damping device for a flat tension mask, and in particular, an object of the present invention is to improve screen characteristics by applying a strain rate over a certain range to a damper wire installed to reduce mask vibration.

In order to realize this, in the present invention, a fluorescent screen is coated on an inner surface of a panel, a funnel having a neck portion in which an electron gun is enclosed, is coupled with a panel, and a support frame is coupled to an inner surface of the panel, and the long and short sides of the frame are coupled to the panel. In the planar brown tube provided with a slotted or dot-shaped shadow mask formed by tensioning the mask, one or more wires are installed in the space between the mask holes formed in the mask so as to be stretched and contacted on the mask surface, When the length is referred to as L, a strain of a value larger than 1.8 × 10 ⁻⁴ + 1.48 × 10 ⁻⁹ × L ² is applied in the length direction.

Description

Vibration Damping Device for Flat Tension Mask

The present invention relates to a vibration damping device of a flat tension mask, and more particularly, to a strain range of a damper wire mounted to prevent vibration of a shadow mask mounted on an inner surface of a panel.

In general, a flat CRT uses a panel 1 having R, G, and B fluorescent surfaces 9 coated on its inner surface as shown in FIGS. 1 and 2, and a frit glass behind the panel 1. A funnel (2) fused to each other, an electron gun (7) enclosed in the neck (3) of the funnel (2) for firing three electron beams (R, G, B), and a front surface of the panel (1). A tempered glass 11 mounted by the resin 6 and a shadow mask 4 having numerous slit-shaped small holes coupled to the inside of the panel 1 so as to perform the color discrimination function of the electron beam 8; , The shadow mask (4) is composed of a rail (5) that is a support frame for maintaining a predetermined distance from the panel (1).

The conventional color-brown tube constructed as described above collides and collides with the fluorescent screen 9 applied to the inner surface of the panel 1 through the hole of the shadow mask 4 that is the color-selective electrode. The kinetic energy of the electron beam is converted into thermal energy to emit phosphors.

However, the kinetic energy of the collimated electron beam 8 emits phosphors to reproduce an image. At this time, the electron beam passing through the electron beam through hole of the shadow mask 4 is only about 20% of the total electron beam, and the rest is applied to the shadow mask. The impact is converted into heat, causing a dominant phenomenon in which the shadow mask thermally expands.

When the doming phenomenon and the operation of the cathode ray tube, the shadow mask 4 vibrates due to the vibration of the speaker. The howling phenomenon occurs when the howling phenomenon exists. Electrons emitted from the mask pass through the electron beam through hole of the mask 4 to reach the screen accurately, but when the mask 4 is shaken, the electron beam 8 passes through the electron beam through hole to the screen at its original position. Mis-landing that arrives out of reach occurs.

In order to solve this problem, conventionally, as shown in FIG. 3, the vertical aperture is repeatedly arranged in the horizontal direction, and the aperture grill mask is formed by applying tension in the mask hole direction, that is, the longitudinal direction. The damper wire 10 was fixed in the horizontal direction on the cross section 13 by the elastic spring 12, and then the damper wire 10 was brought into contact with the shadow mask to reduce vibration of the mask.

However, when the damper wire is located at such a position, a shadow of the damper wire appears on the screen, causing a problem of reducing screen characteristics such as being unobtrusive.

In addition, in order to solve the problem, as shown in FIG. 4, the tensioner wire 110 is tensioned in the longitudinal direction between the mask passing holes 106 so that the damper wire 110 does not appear on the screen. 105 is used to fix the structure by welding.

However, even in the above method, in order to prevent the weak shadow of the wire from appearing on the screen, there should be an effect of preventing vibration while the wire is not stretched due to heat energy generation during the operation of the tube. However, if a lot of tension is applied to the wire, the wire may be broken during the installation work or impact, so it is necessary to find a suitable tension value, that is, a strain rate.

And it is not connected to the elastic body that can apply a tensile force to the wire, like the spring, in the way the wire is directly welded to the rail (5) should be applied to the wire strain more than a certain value. Because the spring-like elastic connection method uses the material such as bimetal, the thermal expansion of the elastic body during the operation of the tube naturally exerts tension on the wire, so it is not sensitive to the strain, otherwise it is caused by the increased temperature when the tube is driven. In order to prevent thermal expansion of the wire, a strain for this thermal expansion must be applied to the wire in advance. Therefore, in order to suppress the vibration of the mask or absorb the vibration energy, a strain corresponding to thermal expansion must be applied to a strain that can have an amplitude smaller than the vibration amplitude of the mask.

The present invention was invented to solve the problems of the prior art as described above to fix the anti-vibration wire in the longitudinal direction of the screen in the portion where the groove is not formed between the hole and the length of the wire when L It is an object of the present invention to provide a mask vibration damping device that effectively suppresses vibration of a mask by applying a strain of a value larger than 1.8 × 10 ⁻⁴ + 1.48 × 10 ⁻⁹ × L ² to the wire in the longitudinal direction.

1 is a cross-sectional view of a general flat cathode ray tube.

Figure 2 is an exploded perspective view of the panel portion of the planar cathode ray tube.

Figure 3 is a tension mask structure coupled to the damper wire in the horizontal direction.

Figure 4 shows the tension mask damper wire in the new direction,

(A) is a flat structure diagram.

(B) is sectional view of the wire joint.

* Explanation of symbols for main parts of the drawings

104: shadow mask 105: rail

106: mask through hole 110: damper wire

The present invention is described in detail below with reference to FIG.

Looking at the configuration of the present invention first to apply the tension in the horizontal and vertical direction to the thin flat foil mask 104 having a plurality of slot-like or dot-shaped holes to be fixed to the rail frame 105 of the support frame to a certain interval In the shadow mask structure to be maintained, the at least one damper wire 110 in the longitudinal direction (Y-axis direction) is tensioned between the mask passing holes 106 of the effective surface on which the electron beam is landing to be installed on the mask, The end of the damper wire 110 is configured by welding fixed to the flange portion of the rail 105, respectively, when the total length of the portion where the wire is in contact with the effective surface of the mask is L, the following equation in the longitudinal direction Strain values greater than one were applied.

The operation description of the present invention configured as described above is described below.

In order to prevent the shadow of the wire from appearing on the screen, the wire must not be stretched due to the heat energy generation during the operation of the tube, and it must also have the effect of a damper. However, if a lot of wire tension is applied, the wire may break during the work or the impact, so find a suitable tension value. The strain applied to the wire may vary depending on the temperature inside the cathode ray tube, and may vary depending on the coefficient of thermal expansion of the wire, but there are limitations on the materials that can be used. If the temperature in the tube is about 10 ^-6 / ℃ and the temperature is 50 to 100 ℃, strain is required at least 0.018% to 0.08% in order to prevent deformation due to temperature. More strain is needed. This strain is a strain that allows the maximum amplitude of the wire vibration to be less than the maximum amplitude of the mask vibration. The concept is to maintain, i.e., applying more strain will reduce the amplitude of longer wires. Therefore, in Equation 1, the strain is proportional to the square of the wire length L, 1.48 × 10 ⁻⁹ is a proportional constant, and 1.8 × 10 ⁻⁴ represents at least the required strain.

However, in order not to break the wire, excessive strain must not be applied. Since the tensile strength of ordinary tungsten wire is 200-700 ksi, the strain that can be applied is about 0.3 to 1%, so there will be no problem in applying strain if it is tilted only a little in the process. In addition, as the length of the wire becomes longer, the amplitude of the wire becomes larger, but as the amplitude of the wire increases, the screen quality may be deteriorated. Therefore, the longer the wire, the greater the strain applied in the longitudinal direction.

This strain is the main purpose of suppressing the first mask vibration as a strain for causing the maximum amplitude of the wire vibration to be smaller than the maximum amplitude of the mask vibration. However, since the wire is the same as one string, when the same strain is applied, the vibration amplitude of the long wire becomes larger. Therefore, the longer the length of the wire, the larger the strain applied to the wire. Therefore, to introduce this concept, the focus is on the strain, which must be further acquired under the concept that the change in the frequency as the length changes is kept constant as the length changes. However, since the frequency is inversely proportional to the half power of the length, the change of the strain with respect to the change of the length leads to an expression proportional to the square power of the length.

That is, as shown in Equation 1, the vibration of the mask is applied by applying a strain greater than 1.8 × 10 ⁻⁴ + 1.48 × 10 ⁻⁹ × L ² to the length L of the wire contacting the mask 104. Is to reduce the amplitude. In particular, when a lot of tension is applied to the wire, the vibration amplitude of the wire decreases, so that the vibration amplitude of the mask can be reduced by that amount, thereby reducing the amount of mislanding.

As described above, unlike the conventional damper wire, the mask vibration damping device of the present invention does not show a shadow of the damping element due to the vibration on the screen, and has an effect of improving the screen characteristics by applying a predetermined strain or more to the damper wire. .

Claims (3)

The inner surface of the panel is coated with a fluorescent screen, a funnel having a neck portion enclosed with an electron gun is coupled with the panel, and a support frame is coupled to the inner surface of the panel, and the slot type is formed by tensioning the frame in the long side and the short side direction. In the flat brown tube provided with a dot-shaped shadow mask, One or more wires are provided in the space between the mask holes formed in the mask to be in contact with the mask surface by tension; When the length of the wire is L, the vibration damping device of the flat tension mask, characterized in that the strain applied in the longitudinal direction greater than 1.8 × 10 ^-4 + 1.48 × 10 ^-9 × L ² . The method of claim 1, Length (L) of the wire is a vibration damping device of the flat tension mask, characterized in that the length of the portion in contact with the effective surface of the mask. The method of claim 1, Vibration damping device of the flat tension mask, characterized in that the wire is installed in the longitudinal direction in the space between the mask hole formed in the mask.