KR0152541B1 - Banding method of cathode ray tube and apparatus thereof - Google Patents

Abstract

The present invention discloses an improved banding method and apparatus for a cathode ray tube.

Conventionally, an adhesive tape was used to prevent the thermal shock of the cathode ray tube when the heat-shrink banding of the explosion-proof band, but the adhesive tape is melted to contaminate the appearance and difficult to regenerate.

In the present invention, by preheating the cathode ray tube step by step to insert the explosion-proof band to cool the step by step to mount the explosion-proof band to implement the banding without using the adhesive tape.

Description

Bending method and apparatus of cathode ray tube

1 is a side view of a cathode ray tube showing the stress distribution during exhaustion.

2 is a side view of a cathode ray tube for explaining a conventional bending method.

3 is a flow chart showing the bending method of the present invention.

4 is a schematic cross-sectional view showing an example of a banding device for implementing the method of the present invention.

* Explanation of symbols for main parts of the drawings

T: Cathode Ray Tube P: Panel

B: explosion-proof band 1: preheating chamber

11: hot air nozzle (hot air heating means for primary preheating)

12: heater (radiant heating means for secondary preheating)

2: lifting means

3: band heating position

4: cooling means

41: cooling nozzle (of the first nozzle group)

42: cooling nozzle (of second nozzle group)

The present invention relates to a cathode ray tube, and more particularly to a banding method of the explosion-proof band and a banding device for implementing the same.

A cathode ray tube is an apparatus for displaying an image by selectively emitting a fluorescent surface with an electron beam formed by generating electrons from an electron gun and focusing and accelerating them. In order to stably generate and accelerate the electron beam, gas molecules must not exist on the path of the electron beam, and thus the inside of the cathode ray tube must be exhausted in a high vacuum state. When the cathode ray tube is evacuated and sealed, as shown in FIG. 1, the panel P and the funnel F of the cathode ray tube T try to contract inward and the skirt P of the panel P is inclined. S) is a large stress state to be expanded to the outside occurs. This stress can be supported by the strength of the cathode ray tube (T) in a normal state, but since the cathode ray tube (T) is made of a glass of brittle material, there is a risk of sudden ablation due to external impact. do.

Accordingly, a reinforcement method is used to reduce the expansion stress by winding the explosion-proof band with a large tensile force on the outer periphery of the skirt P of the panel P. The banding method of the explosion-proof band is largely divided into a shrinkage banding and a tension banding method, and in particular, the heat shrinking banding method has a proper process characteristic for production automation.

However, the heat shrink banding method is a method of applying a tensile force by a difference in thermal expansion rate by heating a metal band having a higher thermal expansion rate than a glass material of a cathode ray tube at a high temperature and then covering the panel with cooling. However, when the high-temperature metal band is directly applied to the glass panel, cracks are likely to occur due to thermal shocks on the panel, and are easily separated from the panel by an increase in tensile force due to cooling. Accordingly, for the purpose of insulation and band separation prevention, a banding method of attaching an adhesive tape to the outer periphery of the panel and winding the band thereon is generally used.

That is, as shown in FIG. 2, the adhesive tape A is wound around and adhered to the banding portion of the panel P outer periphery, and then the explosion-proof band B is covered on the adhesive tape A.

However, in such an adhesive banding method, it is common to fix the band with a heat-melt adhesive, so when the banding is completed, the melted adhesive flows down to contaminate the appearance of the cathode ray tube and de-banding the band for regeneration. When the band was stuck to the outer periphery of the panel through the adhesive, the regeneration was not easy. In addition, even when the band is not sufficiently heated or the correct insertion is not made even when the band is inserted, the banding defects such as cracks are generated due to the adhesive tape is pushed out and the tension is unbalanced.

In view of these conventional problems, an object of the present invention is to provide a banding method that does not use adhesive tape.

Another object of the present invention is to provide an apparatus suitable for the implementation of such a banding method.

The banding method of the present invention to achieve the above object is to preheat the panel portion to be installed in the explosion-proof band to a predetermined temperature, the step of inserting the band in the preheated panel, and the band and the panel so that the band is mounted on the panel It characterized in that it comprises a step of cooling.

According to a preferred feature of the invention the step of changing the temperature of the panel, such as preheating or cooling is made of a multi-step to prevent the rapid temperature change of the panel.

The banding device of the present invention suitable for the implementation of this invention is provided with a preheating means for preheating the cathode ray tube to be banded to a predetermined temperature, and a band heating position for heating and supporting the band to another predetermined temperature. And lifting means for moving the cathode ray tube between preheating and the band heating position, and cooling means for cooling the band and the cathode ray tube on the band heating position.

Such specific features and other advantages of the present invention will become more apparent from the following description of the preferred embodiments with reference to the attached drawings.

In FIG. 3, the banding method of the present invention consists of a preheating step, a band insertion step and a cooling step.

In the band insertion step, the explosion-proof band is heated to at least 300 ° C. or more, typically 400 ° C., so that the preheating temperature in the preheating step is not appropriate to the temperature between the room temperature and the band heating temperature, that is, does not apply a thermal shock to the cathode ray tube panel by the band contact. Preheated to a temperature that will not maintain an appropriate temperature difference. When the mand heating temperature is about 400 ° C, the preferred target preheating temperature is about 200 ° C. On the other hand, the preheating step is preferably composed of a multi-step primary and secondary preheating step in order to prevent the thermal shock of the cathode ray tube due to rapid heating.

The primary preheating step is, for example, heating by hot air injection, and the preheating temperature is about halfway between the normal temperature and the target preheating temperature, for example, about 100 ° C. In the second preheating step, radiant heating using a gas burner or a heater is preferable, and the first preheated cathode ray tube is heated to a target preheating temperature, for example, 200 ° C.

In the panel of the cathode ray tube preheated in the band insertion step, for example, an explosion-proof band heated to about 400 ° C. is inserted.

In the cooling step, the cathode ray tube and the explosion-proof band are cooled together by injection of airflow by a nozzle, and the explosion-proof band tightens the outer periphery of the cathode ray tube panel with a large tensile force due to the difference in thermal expansion rate between the cathode ray tube and the explosion-proof band.

At this time, the cooling step is also made of a multi-step in order to prevent thermal shock due to the rapid temperature change of the cathode ray tube, preferably consisting of the first and second cooling step. To this end, the first cooling step consists of hot air at a temperature higher than room temperature and the second cooling step consists of airflow at room temperature, or the first cooling step consists of a small flow rate and injection pressure, that is, a small amount of air, and the second cooling step Differentiation is given to the cooling rates of both stages, for example, by a large amount of air.

According to the present invention as described above it is possible to prevent the thermal shock or the separation of the band of the cathode ray tube without using a separate adhesive tape for insulation.

On the other hand, Figure 4 shows a banding device suitable for the implementation of such a method. In FIG. 4, the cathode ray tube T enters the preheating chamber 1 by the elevating means 2, is preheated, and is then coupled with the explosion-proof band B supported by the band heating position 3 below. have.

The preheating chamber 1 is open so that the cathode ray tube T supported on the elevating means 2 enters and enters a lower portion thereof, and hot air nozzles 11 for injecting hot air and radiant heaters 12 are formed on the side walls thereof. Is provided so as to direct the skirt of the panel P of the cathode ray tube T.

In the band heating position 3, a conductive heater block 31 is moved forward and backward by an actuator (not shown) to direct the explosion-proof band 13, and as the cooling means 4, a plurality of cooling nozzles ( 41 and 42 are provided to face the outer circumference of the explosion-proof band B. The cooling nozzles 41 and 42 are preferably divided into two groups. For example, the cooling nozzles 41 and 42 are divided into first and second cooling nozzle groups 41 and 42 and controlled separately.

Meanwhile, the elevating means 2 includes a vacuum pad 21 for holding the cathode ray tube T and a support plate 22 for shielding the lower portion of the lower portion 1 during preheating by an actuator not shown. The cathode ray tube T is preheated by entering the preheating chamber 1 from the whole process, then banded and cooled in the band heating position 3, and taken out in a subsequent process. The connecting rod between the support plate 22 and the actuator may be configured in the form of a crank, for the convenience of mounting the explosion-proof band B, but such a detailed configuration may include a cathode ray tube T and Since they can be configured differently according to the coupling direction or order of the explosion-proof band (B), a separate illustration or description thereof will be omitted.

Such operation of the banding device of the present invention will be described.

First, the cathode ray tube T is gripped on the vacuum pad 21 of the elevating means 2, and then the elevating means 2 is raised to enter the cathode ray tube into the preheating chamber 1. At this time, since the support plate 22 of the elevating means 2 shields the lower part of the preheating chamber 1, the preheating chamber 1 forms a closed space.

Next, at least the circumference of the panel P of the cathode ray tube T is preheated to a primary preheating temperature, for example, about 100 ° C. by blowing hot air into the hot air nozzles 11. When the primary preheating is completed, the heater 12 is operated to preheat the cathode ray tube T to the secondary preheating temperature, for example, about 200 ° C.

In the preheating process, the band heating position 3 is equipped with an explosion-proof band B and the heater block 31 is operated to heat the explosion-proof band B to a predetermined heating temperature, for example, 400 ° C.

When the preheating of the cathode ray tube T and the heating of the explosion-proof band B are completed, the elevating means 2 descends to match the skirt of the panel P of the cathode ray tube T with the explosion-proof band B. FIG.

In this state, the airflow at a predetermined temperature is injected from the cooling nozzles 41 of the first nozzle group at a predetermined pressure to cool the explosion-proof band B and the cathode ray tube T. Since this process is a primary cooling step, when a predetermined time has elapsed, airflows having different predetermined temperatures are preferably injected at different pressures in the cooling nozzles 42 of the second nozzle group to perform secondary cooling.

When the first and second cooling is completed, the explosion-proof band B is clamped with a predetermined tensile force on the outer periphery of the panel P of the cathode ray tube T, and accordingly, the band heating position 3 releases the band support and lifts it. The means 2 descends to take out the cathode ray tube T in which the bending is completed.

As described above, according to the present invention, the thermal shock is not applied to the cathode ray tube due to a sudden temperature change, and the band is slowly cooled, so that no crack is generated in the cathode ray tube without any bonding means such as adhesive tape or insulation material. No departure occurs. Accordingly, contamination of the cathode ray tube or poor tensile force due to the provision of the adhesive tape is not generated, and the band can be easily removed during regeneration.

Therefore, the present invention greatly improves the stability and productivity of the cathode ray tube and has the effect of reducing the production cost.

Claims (8)

Preheating the panel portion of the cathode ray tube on which the explosion-proof band is to be mounted to a predetermined temperature; inserting a heated explosion-proof band into the panel portion of the cathode ray tube preheated to another predetermined temperature; Bending method of the cathode ray tube, characterized in that it comprises the step of cooling to be mounted on the panel portion of the cathode ray tube. The bending method for a cathode ray tube according to claim 1, wherein at least one of the preheating step and the cooling step is performed in a multi-step. The method of claim 1, wherein the heating temperature of the explosion-proof band is about 400 ℃. The method of claim 1, wherein the preheating step comprises a first preheating step of heating a panel portion of the cathode ray tube to about 100 ° C., and a second preheating step of heating to 200 ° C. Bending method of the cathode ray tube, characterized in that. The cooling step according to any one of claims 1 to 3, wherein the cooling step is performed by cooling by air flow injection, and is performed by a first cooling step by a predetermined amount of air and a second cooling step by a larger amount of air. Bending method of the cathode ray tube, characterized in that the. Preheating means (11, 12) is provided with a preheating chamber (1) for preheating the cathode ray tube (T) to be banded to a predetermined temperature, and the band heating position for supporting the explosion-proof band (B) and heating to another predetermined temperature ( 3) elevating means (2) for moving the cathode ray tube (T) between the preheating chamber (1) and the band heating position (3), and the cathode ray tube located at the band heating position (3). A banding device for a cathode ray tube, characterized in that it comprises cooling means (4) for cooling T) and the explosion-proof band (B). The bending device of a cathode ray tube according to claim 6, wherein the preheating means (11, 12) comprises hot air heating means (11) and radiation type heating means (12) which are operated step by step. The cathode ray tube according to claim 6, characterized in that the cooling means (4) comprises cooling nozzles (41, 42) of the first nozzle group (41) and the second nozzle group (42) operated in steps. Banding device.