KR100907331B1 - Flat color cathode ray tube - Google Patents

Abstract

The present invention relates to a detachable lamination resin, and more particularly, when a component of a curing resin, which is an adhesive for attaching a safety glass to a panel, appears to be defective in a panel and safety glass bonding process during intermediate manufacturing of a cathode ray tube. The present invention relates to a planar cathode ray tube with a removable lamination resin that can easily separate the panel and the safety glass.

In order to achieve the object of the present invention, a panel having a screen on the inner surface, a safety glass for reducing external impact on the upper surface of the panel, a funnel having a non-circular cone portion mounted on the rear of the panel, inserted into the neck portion of the funnel A planar cathode ray tube comprising an electron gun that emits an electron beam towards a screen, and a shadow mask having a plurality of electron beam through holes arranged at regular intervals on the inner surface of the panel, wherein the removable lamination for attaching the safety glass and the panel is provided. The resin is characterized in that it comprises a silicone acrylate (Silicone Acrylate) resin.

Description

Flat Cathode Ray Tube {A Flate Color Cathode-ray Tube}

1 is a cross-sectional view showing a typical flat color cathode ray tube.

2a shows a schematic structure of a laminating system;

Figure 2b schematically shows the curing structure of the resin in the laminating system.

3 shows a laminating system process.

4 is a view showing the adhesive structure of the panel and the safety glass according to the laminating process.

 5 is a view showing a structure of a silicone acrylate resin.

6 is a view showing a curing principle of the resin used when the panel and the safety glass in the lamination process.

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

10: safety glass 20: panel

30: funnel 40: explosion proof band

50: electron beam 60: shadow mask

70: rail 80: thermosetting resin (Resin)

The present invention relates to a detachable lamination resin, and more particularly, when a component of a curing resin, which is an adhesive for attaching a safety glass to a panel, appears to be defective in a panel and safety glass bonding process during intermediate manufacturing of a cathode ray tube. The present invention relates to a planar cathode ray tube with a removable lamination resin that can easily separate the panel and the safety glass.

In general, the color flat cathode ray tube is coated with a fluorescent film of red, blue, green (R, G, B) on the inner surface of the panel 20, as shown in Figure 1, the safety glass 10 is fixed to the upper surface of the panel In addition, the electron beam 50 is fused to the rear end of the panel 20 and the electron beam 50 is enclosed in the neck of the funnel 30 and the electron gun is enclosed in the neck portion of the funnel 30. The image is reproduced by striking the fluorescent film applied to the inner surface of the panel 20 in the state where color selection is made while passing.

The inside of the cathode ray tube is in a vacuum state of about 10 ^-7 Torr so that the electron beam from the electron gun can reach the phosphor.

If a strong impact is applied from the outside of the cathode ray tube, the cathode ray tube may explode and glass fragments of the panel and the funnel scatter to the front, which may cause a great danger to the user.

Therefore, after fabricating the cathode ray tube, the panel portion of the cathode ray tube is excited with a steel sphere having a constant energy. Therefore, it is determined whether the cathode ray tube is safe.

In general, in case of cathode ray tube with curvature, the panel is curved, so the internal deflection is not large, and because there is a skirt in the panel, the panel has a deflection band and the panel and the funnel Since much of the stress applied to the circuit can be reduced, there is no significant problem in the explosion-proof characteristics.

However, as the panel is flattened by eliminating the curvature of the screen so that the cathode ray tube does not cause an image distortion phenomenon, the deflection and stress value due to atmospheric pressure are large as the skirt portion disappears, which has a great vulnerability in the explosion-proof characteristics of the cathode ray tube.

Therefore, in the conventional flat color cathode ray tube in which the rail 70 and the funnel 30 are fused and fixed to the inner surface of the panel 20 by fritted glass, the safety glass 10 has a modulus of elasticity. By attaching to the outer surface of the panel 20 using a relatively small thermosetting resin (80) to reduce the amount of impact on the panel 20 and funnel 30 due to the impact from the outside of the cathode ray tube to prevent damage to the panel Even if the panels were broken, safety glass and resin-bonded structures prevented the front fragments of the glass fragments from exploding.

On the other hand, the bonding process of the panel and the safety glass, which is an intermediate process of the cathode ray tube manufacturing process is made by a lamination system method, such a lamination process is as follows.

FIG. 2A shows a schematic structure of a laminating system and FIG. 2B schematically shows a hardening structure of a resin in the laminating system.

First, as shown in FIGS. 2A and 2B, when the worker loads the safety glass S.G on the explosion-proof glass receiving plate 1, the seal 3 moves to the safety glass side and comes into close contact with the safety glass. When the seal 3 is in close contact with the upper surface of the safety glass S.G, the operator places the CRT on the safety glass S.G and the seal 3.

As described above, when the C tube, the safety glass S.G, and the seal 3 are positioned to each other, the clamp 4 is operated to fix the C tube.

At this time, between the panel (P) and the safety glass (SG) of the CRT (B) is formed a micro-space to be applied with the resin by the seal (3), the injection and discharge of the resin in the seal (3) Inlet and outlet for each one is formed.

Thereafter, air pressure is applied to the inside of the resin tank 5 through the air pipe 7 to inject the resin into the micro space between the safety glass S.G and the panel P. When air pressure is applied to the resin tank 5, the resin in the resin tank 5 is moved through the resin supply pipe 9 and injected into the micro space between the safety glass S.G and the panel P.

At this time, the air remaining in the micro-space between the safety glass (SG) and the panel (P) and the remaining resin after the filling of the micro-space is moved to the residual volume collection tube 13 through the residual amount collection pipe (11). .

A resin discharge pipe 15 and a stop valve 17 are installed at the lower end of the resin tank 5 for cleaning and repairing the resin tank 5, and at the upper end of the resin tank 5 as necessary. The tank cover 19 is installed to open and close. Then, when the resin is filled in the micro-space between the safety glass (SG) and the panel (P) and the application is complete, the air pressure provided through the air pipe 7 is interrupted to stop the injection of the resin and the safety glass fixed receiving Lower (1).

When the safety glass holder 1 is lowered, the curing lamp 21 is moved to the lower side of the explosion-proof glass SG to irradiate ultraviolet rays toward the safety glass SG, and thus the safety glass SG and the panel P. The resin applied in between is cured.

When the safety glass and the panel bonded by the above process are not adhered or the defect is not adhered to the proper position, the regeneration treatment becomes difficult, so that the process is performed again by separating the safety glass and the panel in the intermediate process.

In this process, a process of coating and applying a surfactant, which is a removable material, is required to separate the safety glass and the panel well.

However, such a process causes a problem that causes another process failure due to the inflow of foreign substances in the atmosphere before the panel and the safety glass are bonded.

The present invention is to solve the conventional problems as described above, manufacturing costs and production by eliminating the process of separating the panel and the safety glass by applying a surfactant by changing the components of the curing resin that is an adhesive for attaching the safety glass to the panel The objective is to provide a planar cathode ray tube with a removable lamination resin that can shorten the reader time.

Technical means of the present invention for achieving the above object, a panel having a screen on the inner surface, a safety glass for reducing external impact on the upper surface of the panel, a funnel mounted with a non-circular cone portion on the rear of the panel, the funnel A flat cathode ray tube including an electron gun inserted into a neck portion of a shadow mask having an electron gun that emits an electron beam toward a screen, and a shadow mask having a plurality of electron beam through holes disposed at regular intervals on an inner surface of the panel. Removable lamination resin for attachment is characterized in that it comprises a silicone acrylate (Silicone Acrylate) resin.

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

 Figure 3 briefly shows the laminating system process as described above.

As shown in FIG. 3, the panel and the safety glass are subjected to a soldering process using a thermosetting resin, and when a defect is found, the panel and the safety glass are subjected to a process of detaching the panel and the safety glass.

Figure 4 shows the adhesive structure of the panel and the safety glass according to the laminating process.

In the present invention, by changing the composition ratio of the resin 80 to be injected when the panel and the safety glass is bonded, a detachable lamination resin is used that enables the resin to be detachable as well as adhesive without using a surfactant required during the desorption process.

It is preferable to form a resin by adding a silicone acrylate (Silicone Acrylate) reactive release agent to the composition of the removable lamination resin.

As shown in FIG. 5, the reactive release agent is a substance having an acrylic structure as a monomer and having a silicone group on its branch.

Therefore, before the reaction occurs, it is compatible with other monomers and may be distributed evenly, but at the same time, the surface energy of the silicon group in the branch is very low and is directed toward the surface rather than inside the reactant.

Therefore, the same effect as the application of a large number of silicon on the surface of the reactant can be obtained.

Figure 6 shows the principle of curing of the resin used when the panel and the safety glass in the lamination process when irradiated with UV light to the resin applied to the front panel of the resin composition is discharged and activated, the double bond between the composition The resin is cured while forming a chain shape.

Table 1 shows the composition of the conventional resin and the removable lamination resin according to the present invention.

TABLE 1

Conventional The present invention Resin Removable Lamination Resin Composition Composition ratio (%) Composition Composition ratio (%) Aliphatic Urethane Acrylate 45 Diflunctional Urethane Acrylate 25 Isobornyl acrylate 22 Isobornyl acrylate 30 Polyethylenglycol Diacryllate 10 Triflunctional Urethane Acrylate 15 Tripropylenglycol Diacryllate 3.0 Hexandiol diacrtlate 14.8 Pomodified Neopentylcol Diacryllate 3.0 Pomodified Neopentylcol Diacryllate 3.0 Eomodified Trimethylpropane Diacryllate 3.0 Silicone acrylate 0.005 to 0.2 Photoinitaor 2.0 Photoinitaor 2.1

The composition of the removable lamination resin of the present invention as shown in Table 1

Diflunctional Urethane Acrylate, Isobornyl Acrylate, Trifunctional Urethane Acrylate, Hexandiol Diacrylate, Formerdefined Neopanylcol Die It is preferable that it is made of acrylate (Pomodified Neopentylcol Diacrylate), silicon acrylate (Silicone Acrylate), photoinitaor (Photoinitaor).

The silicone acrylate resin may have a composition ratio of 0.05 to 0.2%.

The lamination resin configured as described above is easily detachable even after the reaction because the release agent is treated by itself without applying the surfactant in the process of separating the panel and the safety glass by applying the surfactant.

As such, those skilled in the art will appreciate that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof. Therefore, the above-described embodiments are to be understood as illustrative and not restrictive in all respects, and the scope of the present invention is indicated by the appended claims rather than the foregoing description, and the meaning and scope of the claims and All changes or modifications derived from the equivalent concept should be interpreted as being included in the scope of the present invention.

As can be seen from the above, the present invention can reduce the manufacturing cost and production lead time by eliminating the process of separating the panel and the safety glass by applying a surfactant by changing the components of the curing resin, which is an adhesive for attaching the safety glass to the panel. It has an effect.

Claims (6)

A panel having a screen on an inner surface, a safety glass for reducing external impact on an upper surface of the panel, a funnel mounted with a non-circular cone portion on a rear surface of the panel, inserted into a neck portion of the funnel to emit an electron beam toward a screen In a planar cathode ray tube comprising an electron gun, a shadow mask having a plurality of electron beam through holes arranged at regular intervals on the inner surface of the panel, The detachable lamination resin for attaching the safety glass and the panel may include a diflunctional urethane acrylate, an isobornyl acrylate, a trifunctional urethane acrylate, and a hexanediol die. A flat colored cathode ray tube comprising an acrylate (Hexandiol Diacrylate), a foamed neopentylcol diacrylate, a silicone acrylate (Silicone Acrylate), a photoinitaor. The method of claim 1, The structure of the silicone acrylate (Silicone Acrylate) resin

Flat color cathode ray tube, characterized in that consisting of. delete The method of claim 1, The silicone acrylate (Silicone Acrylate) resin is a flat color cathode ray tube, characterized in that having a composition ratio of 0.05 ~ 0.2%. A panel having a screen on an inner surface, a safety glass for reducing external impact on an upper surface of the panel, a funnel mounted with a non-circular cone portion on a rear surface of the panel, inserted into a neck portion of the funnel to emit an electron beam toward a screen In a planar cathode ray tube comprising an electron gun, a shadow mask having a plurality of electron beam through holes arranged at regular intervals on the inner surface of the panel, Removable lamination resin for attaching the safety glass and the panel comprises a silicone acrylate (Silicone Acrylate) resin, The structure of the silicone acrylate (Silicone Acrylate) resin

Flat color cathode ray tube, characterized in that consisting of. The method of claim 5, The silicone acrylate (Silicone Acrylate) resin is a flat color cathode ray tube, characterized in that having a composition ratio of 0.05 to 0.2% by weight.

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