KR920005768Y1 - A stud pin in color crt - Google Patents

Abstract

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Description

Stud pins for colored cathode ray tubes

1 is a schematic sectional view showing a general structure of a color cathode ray tube.

2 is a cross-sectional view taken along the X direction of FIG.

3 is an example of the use of the stud pins related to the present invention, a) is a side cross-sectional view of a stud pin made of a seismic metal as a whole, b) is a seismic metal as another embodiment of the present invention A sectional view of the stud pin with the ring in the outer circumference.

* Explanation of symbols for main parts of the drawings

1: Face 2a-2c: Stud Pin

3: fluorescent film 4: shadow mask

5: mask frame 6a-6c: support spring

The present invention relates to a stud pin for a color cathode ray tube, and more particularly, to a stud pin for a color cathode ray tube that does not transmit vibration by an external impact to a shadow mask of an inner shaft.

In a color cathode ray tube, especially a color cathode ray tube having a shadow mask disposed therein, the electron beam radiated from the electron gun is configured to be landed in a phosphor of a corresponding color by an aperture formed in the shadow mask. In this case, if the electron beam misses landing with another phosphor, phenomena such as color spreading and sharpness deterioration will appear in the image.

On the other hand, the mis-landing of the electron beam is caused by an internal factor such as shadow mask misalignment or an external factor caused by an external shock caused by vibrating the shadow mask.

In the past, quality improvement has been progressed to prevent mis-landing due to internal factors. However, since the AV system, which combines video equipment and audio memory, has recently been in the spotlight, color television has gradually increased in size and high-output audio. I had a system.

As a result, the shadow mask mounted inside the large-sized television, unlike the conventional one, causes mislanding due to external factors such as vibration generated in the large speakers, and to solve this problem, holes for preventing resonance in the frame supporting the shadow mask. In order to prevent mis-landing caused by resonance, a plan has been devised, and at present, there is no practical obstacle, but there is no groundbreaking anti-resonance measure.

1 and 2 are views for showing the process of propagation of the external factors of the mislanding through the general structure of the color cathode ray tube, and at least three of which are cut out in a side view at a predetermined position on the inner wall of the face 1. Two metal stud pins 2a, 2b, and 2c are arranged at predetermined positions, and the shadow mask 4 is framed against the fluorescent film 3 laminated inside the face 1; It is fixed by the position.

On the other hand, the frame 5 is suspended by bimetal springs 6a-6c whose one end is supported by the stud pins 2a-2c.

In the color cathode ray tube configured in this way, the path through which the external factor causing resonance propagates is determined by the stud pins 2a-2c-bimetal springs 6a-6c-the frame 5 and the shadow mask 4.

Here, if the point at which the above propagation path is blocked can be calculated, it can be impregnated into three places: the stud pins 2a-2c, the bimetal springs 6a-6c, and the frame 5.

By the way, since the stud pin and the bimetal spring must have a structural shape, the easiest method is to change the shape or structure of the frame so that resonance does not occur as has been conventionally attempted.

However, this method does not have a great effect as revealed in the prior art.

It is an object of the present invention to provide a stud pin for cathode ray tubes that blocks external factors of mislanding in color televisions from propagating therein.

The present invention according to the above object is characterized by forming a stud pin of the truncated view from the side of the seismic metal material.

The seismic metal materials that can be used for stud pins are alloys containing 1-3% aluminum in 12% chrome steel, or KIXI alloys containing 0.2-0.7% zinc in magnesium.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to FIG. 3.

3 is a side cross-sectional view of the stud pin 10 according to the present invention, in which the stud pin 10 is formed entirely of seismic metal.

First, in the case where the applied seismic metal is 12% chromium steel containing 1-3% aluminum, this is a ferromagnetic material with a large magnetostriction, and when subjected to vibration from the outside, the magnetic wall surrounding the inside of the magnetic material is moved by the magnetostrictive effect. The magnetization of the magnetic material changes, and the change of the magnetic wall consumes energy without returning to its original state after the vibration is extinguished.

As a result, the energy consumed by the magnetic domain is the main cause of the vibration, and in practice, the 18-8 nickel-ktom steel, which is conventionally used as a material for stud pins, exhibits a dustproof coefficient of 1%. A 12% creme steel containing 1-3% of aluminum exhibits a dust-proof factor of 10%.

In addition, KIXI alloys are crystal grains that cause slip dislocations against external stress, and when the vibrations are applied from the outside, the slip dislocations progress, and when the vibrations disappear, the KIXI alloy has physical properties of returning to the original potentials. Progress and return are disproportionate hysteresis, releasing some of the absorbed energy as heat, and in this process, energy released as heat is a direct cause of vibration absorption.

As described above, the present invention may form the steed pin itself as a seismic metal to absorb vibrations applied from the outside, thereby preventing mis-landing caused by the vibration of the shadow mask.

3 is a side cross-sectional view showing another embodiment of the present invention, in which the ring 12 is fitted to the outer circumference of the stud pin 10.

Here, the stud pin 10 may be made of the same 18-8 nickel chromium steel, and the ring 12 may be made of 12% chromium steel or KIXI alloy containing 1-3% aluminum, and on the other hand, the stud pin 10 ) May be 12% chromium steel, and the ring 12 may be KIXI alloy or vice versa.

Claims (6)

In the normal stud pin for color cathode ray tube which supports the bimetal spring which suspends the frame to which the shadow mask is fixed to the face inner surface of the cathode ray tube, the material of this stud pin 10 is seismic metal. A colored pin for cathode ray tube. The stud pin for color cathode ray tubes of claim 1, wherein the seismic metal is 12% chromium steel containing 1-3% aluminum. The stud pin for color cathode ray tubes according to claim 1, wherein the seismic metal is a KIXI alloy made of magnesium containing 0.2-0.7% zinc. The stud pin (10) according to claim 1, wherein the stud pin (10) has a ring (12) fitted on its outer circumference. 5. Stud pin for color cathode ray tubes according to claim 4, characterized in that the stud pin (10) is 12% chromium steel and the ring (12) is of KIXI alloy or vice versa. 5. Stud pin for color cathode ray tube according to claim 4, characterized in that the ring (12) is formed of either 12% chromium steel or KIXI alloy.