KR920006863Y1 - Shadowmask assemble of color crt - Google Patents

Abstract

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Description

Shadow Mask Support

1 is a cross-sectional view showing the structure of a conventional color water pipe.

2 is a cross-sectional view showing the operation of a conventional shadow mask support.

3 is a cross-sectional view showing the structure of the shadow mask support of the present invention.

4 is a graph showing the change in inclination of the electron beam.

5 is a cross-sectional view showing the operation of the shadow mask support of the present invention.

6 is a graph showing the frame movement amount according to the temperature rise of the shadow mask support of the present invention.

* Explanation of symbols for main parts of the drawings

5: shadow mask 6: frame

7: Supporting tool 8: Stud pin

9: movable part l0: metal piece

The present invention relates to a support for a shadow mask that can properly compensate for mislanding of an electron beam due to thermal expansion of the shadow mask in a color water pipe.

The conventional color water pipe is composed of a rectangular panel 1, a nude chanel 2 and a neck 3, as shown in FIG.

That is, the inside of the water tube is formed in a vacuum state of about 10 ^-5 Torr, and the inner surface of the panel 1 is formed of a striped phosphor layer, and deposits a phosphor screen emitting red, green, and blue light, In (3), an IN-LINE electron gun 4 which is arranged in a line with respect to the horizontal axis of the panel 1 and emits three electron beams corresponding to red, green, and blue phosphors is provided.

In addition, a shadow mask 5 having a plurality of holes is disposed at a position facing the phosphor screen, wherein the shadow mask 5 is fixed to and supported by the frame 6, and the shadow mask 5 and the frame 6 are disposed. ), The shadow mask 5 and the frame 6 were supported by a stud pin (STUD PIN, 8) embedded in the inner side of the panel 1 by the support 7.

In addition, the shadow mask 5 is made of a thin plate having a thickness of about 0.15 mm mainly composed of iron (Fe) having a large coefficient of thermal expansion, and the peripheral portion is fixed by a rigid frame 6 around 1 mm thick.

Therefore, the three electron beams emitted from the electron gun 4 are deflected by the deflector outside the receiving tube and scanned onto the phosphor screen, and the color is selected through the holes of the shadow mask 5 to impinge on the stripe-shaped phosphors. The image was expressed.

However, in the above process, the electron beam passing through the hole of the shadow mask 5 is less than 1/3 of the electron beams emitted from the electron gun, and the remaining electron beams collide with the shadow mask 15 to heat the shadow mask 5 to about 70 ° C. I was.

The heated shadow mask 5 is then thermally expanded to change the distance between the so-called phosphor screen and the shadow mask 5, and if the change in g value is more than the allowable value, the mislanding of the electron beam does not land correctly on the phosphor. There was a problem that the color purity is reduced (MISLANDING) occurs.

Therefore, in order to prevent such color purity deterioration, by attaching the support 7 to the frame 6, the shadow mask 5 and the entire frame 6 are moved in the phosphor screen direction so that the change of the value is allowed. A way to make it happen was devised.

That is, one side of the support 7 is bent at a predetermined angle α with the tube axis and fixed to the stud pin 8 of the panel 1 as shown in FIG. 2, and the other axis is fixed to the frame 6. When the frame 6 thermally expands, the top portion A of the support 7 moves to the position A 'by the thermal expansion.

Thus, the frame 6 and the shadow mask 5 fixed to the support 7 can be moved toward the phosphor screen to compensate for mislanding.

However, the above-mentioned improvement measures are based on (b) of FIG. 2 when the force F accompanying the thermal expansion of the frame 6 acts on the support 7 when the displacement f due to thermal expansion of the frame 6 occurs. As shown, the force F is the component force F ₁ and the support 7 which rotates the movable portion 9 of the support 7 which is the portion of the support 7 from the top portion A to another curved portion. The support 7 formed into a thin plate by dispersing with the component F ₂ compressing the movable part 9 of the member 9 is curved as shown in (c) of FIG. 2 by the compressive component F ₂ , thereby causing the shadow mask 5. And the frame 6 could not be moved toward the phosphor screen 11, and mislanding could not be corrected.

In addition, since about two-thirds of the electron beam emitted from the electron gun collides intensively with the shadow mask 5, the temperature rise rate, final arrival temperature, and thermal expansion rate of the shadow mask 5 and the frame 6 are different. Therefore, the inclination change of the electron beam appears almost linearly in the curve (a) of FIG. 4 as shown in part II. In order to make the electron beam inclination change like the line b of FIG. 6, the frame according to the temperature rise of the frame 6 6) and the amount of movement toward the phosphor screen 11 of the shadow mask 5 (D in FIG. 2 (a)) preferably has a straight line or an increasing curve.

The reason is that the temperature rise of the frame 6 over time satisfies T = T ₆ (1-e ^- t / z), and the electron beam mislanding decreases linearly over time. .

Then, the movement amount D toward the phosphor screen 11 of the shadow mask 5 and the frame 6 by the conventional support 7 is determined by the length of the movable part 9 of the support 7 and the movable part 9. The amount of movement D of the shadow mask 5 and the frame 6 is determined by the angle α formed with the hydrous correlation and is represented by D = L (cos α′-cos α).

At this time, α is the angle formed by the initial water observation and the movable part of the support, α 'is an angle formed by the water observation and the movable part of the support after a certain temperature rise, and l is the length of the support movable part.

However, the conventional supporter 7 exhibits a reduction compensation curve which gradually decreases with respect to the unit temperature rise as the temperature increases as shown in (a) of FIG. 6, as the amount of movement toward the phosphor screen 11 of the frame 6 increases. The same compensation curve cannot achieve optimal electron beam landing, and in extreme cases, color purity deterioration cannot be prevented.

Therefore, the present invention compensates for the insufficient movement of the frame due to the curvature of the movable part of the support, and the movement amount of the shadow mask and the frame moving toward the phosphor screen according to the temperature rise is approximated by the straight line or the increase curve with respect to the temperature rise. It is an object of the present invention to provide a structure of a support to have.

The present invention, for this purpose, by attaching a metal piece capable of high thermal expansion to the inside of the movable part corresponding to the predetermined portion between the bent portion to fix the support to the start pin and the frame, the movable part of the support serves as a bimetal In accordance with an embodiment of the present invention shown in the accompanying drawings as to have a curvature of the portion facing the phosphor screen in the movable portion of the support as follows.

Among the support members 7 having elasticity, a predetermined portion corresponding to a portion between the curved portions A and B is used to fix the support 7 to the stud pin 8 and the frame 6 due to the characteristics of the material. The inner side of the movable portion 9 is thermally expanded by high heat, and a metal piece 10 having a larger coefficient of thermal expansion than the movable portion 9 is attached.

Then, the movable portion 9 and the metal piece 10 are curved to have a predetermined curvature toward the phosphor screen 11 side.

The support 7 secures one end to the stud pin 8 and the other end to the frame.

Therefore, the heat of the frame 6 is transferred to the support 7, which causes the movable portion 9 and the metal piece 10 of the support 7 to move toward the phosphor screen 11 so that the frame 6 also moves. At the same time, it moves to the phosphor screen 11.

In addition, since the coefficient of thermal expansion of the metal piece 10 is larger than that of the movable part 9, the movable part 9 and the attachment portion of the metal piece 10 play a role of a bimetal, so that the movable part 9 of the movable part 9 of the support 7 is supported. When displaced, the movable part 9 and the metal piece 10 are spread evenly due to the thermal expansion of the metal piece 10 having a larger coefficient of thermal expansion than the movable part 9 so that the curved portion curved at a predetermined curvature so that the shadow mask 5 and the frame The movement amount D of (6) is further increased.

That is, the movement amount D of the shadow mask 5 and the frame 6 is caused by the thermal expansion of the movement amount D1 = αf Tf L tan α and the metal piece 10 by the position movement of the movable portion 9 and the metal piece 10. Movement amount by bimetal role Is the sum of (D = D ₁ + D ₂ ).

In this case, K is the flexurality (FLEXIVITY), Tf is the frame rise temperature, t is the combined thickness L of the movable part 9 and the metal piece 10 is the distance from the water tube axis to the frame αf is the frame coefficient of thermal expansion.

Also greater than the second degree (b) the compressed component force F _2, the moving part 9 and the curved development of the metal piece 10 includes a compression component force F ₂ strain of the combined thickness of the movable part 9 and the metal piece 10 of the illustrated in Not only does it occur because it is small, but also because the expansion of the metal piece 10 is larger than that of the movable portion 9.

As shown in FIG. 6, the shadow mask and the frame movement amount can satisfy the movement curve of the straight line or the increase curve required to compensate the electron beam landing tilt change (a) with the electron beam landing time change (b).

In addition, the present invention has the effect of preventing the curved phenomenon of the movable portion by the thermal expansion of the frame.

Claims (1)

In order to support the frame and the shadow mask, one side is fixed to the frame and the other side is fixed to the stud pins. In the support of the collar receiving pipe, the thermal expansion of the movable part 9 on the inner side of the movable part 9 of the support 7 A shadow mask of a color water pipe, characterized by attaching a metal piece 10 having a coefficient of thermal expansion larger than the coefficient and bending the movable portion 9 in which the metal piece 10 and the metal piece 10 are in close contact with each other to have a predetermined curvature. Support.