KR920008509Y1 - Apparatus for sealing electron gun of crt - Google Patents

Abstract

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Description

Electron Gun Enclosing Device of Cathode Ray Tube

1 is a perspective view schematically showing an electron gun encapsulation device of a typical cathode ray tube.

2 is a perspective view showing an electron gun encapsulation device of a cathode ray tube according to the present invention.

3 is a partial ablation perspective view showing a state in which an electron gun is inserted into the neck portion of the cathode ray tube.

* Explanation of symbols for the main parts of the drawings

11: turntable 12: mount

13 electron gun support rod 15 first light source device

16: first light receiving device 17: second light source device

18: second light receiving device 40: cathode ray tube

G: Electron gun GM: Mounting hole

The present invention relates to an electron gun encapsulation device of a cathode ray tube, and more particularly, to an encapsulation device in which an electron gun fuses a step to a neck portion of a cathode ray tube.

In general, the electron gun encapsulation of cathode ray tube is used to make a tube for fusion of the stem of electron gun to the neck of cathode ray tube to make vacuum, and it has a great effect on the characteristics of electron gun enclosed in the neck of cathode ray tube. Will cause. Therefore, the encapsulation device for encapsulating the electron gun of the cathode ray tube should be made very precisely.

By the way, the sealing device of the electron gun for a conventional cathode ray tube is moved up and down by a lifting means (not shown in the figure) on a rotating table 2 as shown in Fig. 1 to support the stem of the electron gun from below. The electron gun support rod 3 and the mount 4 positioned vertically on the electron gun support rod 3 are rotatably installed. The plurality of burners 5 supported by the support 5a are installed around the electron gun support rod 3.

In order to seal the stem of the electron gun G in the neck portion 40a of the cathode ray tube 40 as the conventional electron gun encapsulation device 1 configured as described above, the cathode ray tube 40 is mounted on the mount 4 and the electron gun supporting rod 3. ) And the stem of the electron gun (G). In this state, the mount 4 and the electron gun support rod 3 are rotated and the neck portion 40a is heated as the burner 5 to fuse the stem and the neck portion 40a of the electron gun to form the electron gun G. Enclose it.

However, the conventional electron gun encapsulation device has a problem in that the encapsulation defects are frequently caused because the encapsulation is not made in the state where the center of the neck portion 40a of the cathode ray tube 40 and the center of the electron gun G are exactly matched.

That is, the cathode ray tube 40 has the mount 4 and the electron gun support rod 3 precisely set when deviation occurs in the sealing process of the funnel and the panel or when the series between the electrode group and the stem of the electron gun is not good. Even if it is, the sealing defect will occur.

The present invention has been made to solve the above-described problems, the sealing can be made in the state that the center axis of the cathode ray tube and the center axis of the electron gun are always matched to improve the convergence characteristics and focus characteristics of the cathode ray tube In addition, an object of the present invention is to provide an electron gun encapsulation device of a cathode ray tube that can improve the reliability and productivity of a product.

In order to achieve the above object, the present invention is a cathode ray tube having an electron gun support rod which is positioned on the vertical part of the neck portion of the cathode ray tube seated on the mount and the electron gun support rod is lowered while supporting the electron gun. An electron gun encapsulation device, comprising: a first light source device for irradiating light to one side of the mount or cathode ray tube, a first light receiving device for detecting light emitted from the first light source device only at a predetermined angle, and the neck A second light source device for irradiating light to the mount rotation hole of the electron gun inserted into the unit, and a second light source device for sensing the light emitted from the second light source device and passing through the mount rotation hole on the turntable; When the mount and the electron gun support rod are rotated, the data process that detects the coincidence of the time detected by the first and second light receiving devices from the first and second light source devices is completed. It is characterized in that it comprises a transfer device installed in the electron gun support rod and controlled by a data process to transfer the end of the electron gun support rod forward, backward, left and right.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment according to the present invention.

The electron gun encapsulation device 10 of the cathode ray tube according to the present invention shown in FIGS. 2 and 3 has a mount 12 on which the cathode ray tube 40 is seated on the turntable 11, and the mount 12. An electron gun support rod 13 rotatably installed with respect to the turntable 11 is positioned below the neck portion 40a of the seated cathode ray tube 40 and inserted into the neck portion 40a while supporting the electron gun G. do.

On the turntable 11 around the mount 12, a first light source device 15 for irradiating light to one side of the cathode ray tube 40 or the mount 12 seated on the mount 12 according to a feature of the present invention. And a first light receiving device spaced apart from the first light source device 15 by a predetermined distance to detect light reflected from the mount 12 or the cathode ray tube 40 by being irradiated from the first light source device 15 ( 16) is installed. In this case, it is preferable that the first light receiving device 16 detects only light reflected from the first light source device 15 to the mount 12 or the cathode ray tube 40 and reflected at a predetermined angle. And a second light source device which is supported by the electron gun support rod 13 on the turntable 11 and irradiates light to the mount rotation hole GM of the electron gun G inserted into the neck portion 40a of the cathode ray tube 40 ( 17) and a second light receiving device 18, which is located at a height opposite to the second light source device 17 and senses light passing through the mount rotation hole GM, is installed. In addition, the electron gun support rod 13 is provided with a transfer device 20 capable of rotating the electron gun G supported therein at a predetermined angle and moving back and forth left and right. Here, the conveying device 20 is not shown in detail in the drawings, but a drive mechanism using a motor and a ball screw, or a hydraulic motor or a pulse motor and a ball screw, which are typically used in many mechanical devices. Preference is given to using. Then, the first and second light receiving devices 16 and 18 are irradiated from the first and second light source devices 15 and 17 to the mounting rotation holes GM of the cathode ray tube 40 and the electron gun G, which are rotated, respectively. A data process 19 for measuring and comparing the time detected is provided and the data processor 19 controls the transfer device. Here, the first light source device 15, 17 and the first, second light receiving device 16, 18 should be installed at the position set when the cathode ray tube 40 is mounted on the mount 12, the second light source The device 17 and the first light receiving device 11 have light emitted from the second light source device 17 when the electron gun G is inserted at the set position of the neck portion 40a. 18) is preferably installed so as to be detected. Reference numeral 30 is a burner.

Referring to the operation according to the present invention configured as described above are as follows.

In order to enclose the electron gun G in the neck portion 40a of the cathode ray tube 40, the cathode ray tube 40 is seated on the mount 12 of the turntable 11 which rotates intermittently, and the electron gun support rod 13. Support the electron gun (G) in the air, and lift the electron gun support rod (13) by a lifting device (not shown) to insert the electron gun (G) into the net portion (40a), and then the mount 12 and the electron gun support rod (13). ) Is rotated with respect to the turntable 11. The light is irradiated from one side of the cathode ray tube 40 or the mount 12 to the cathode ray tube 40 or the mount 12 from the first light source device 15 to reflect the first light receiving device 18. ) And irradiates light from the second light source device 17 to the mount rotation hole GM of the electron gun G so that the light passing through the second light source device 17 is detected by the second light receiving device 18. In this case, since the mount 12 supporting the cathode ray tube 40 and the electron gun support rod 13 rotate at the same rotation speed, the cathode 12 is irradiated from the first light source device 15 when the cathode ray tube 40 is rotated. The time detected by the first light receiving device 16 is irradiated from the second light source device 17 and passed through the mount rotation hole GM of the electron gun G, and then the time detected by the second light receiving device 18. When the neck portion 40a of the cathode ray tube 40 and the electron gun G are positioned coaxially, i.e., at a predetermined position, their times are equal to twice. Therefore, the data process 19 is irradiated from the first light source device 15 and sensed by the first light receiving unit 16 and the mount rotation hole of the electron gun G from the second light source device 17. GM) is scanned by comparing the time detected by the second light receiving device 18 and when these times are exactly the same, the neck portion 40a is heated by the burner 30 installed around the mount 12 to the neck. The stem 40a and the stem of the electron gun G are fused and sealed to perform the sealing operation. If the time detected by the first light receiving device 15 and the second light receiving device 18 is different from each other, the tapered process 19 causes the sub-motor of the transfer device 20 or By operating the pulse motor to transfer or rotate the electron gun support rod 13 to the front and rear or left and right to match the time sensed from the first, second light receiving device (16) (18). As described above, when the detected time from the first and second light receiving devices 16 and 18 coincides with each other, the electron gun G is positioned at the electron gun G setting position of the cathode ray tube neck portion 40a.

As described above, the electron gun encapsulation device of the cathode ray tube is irradiated from the first light source device and reflected on the cathode ray tube, and then detected by the first light receiving device and irradiated from the second light source device and passed through the mount rotation hole of the electron gun. 2 By moving the electron gun inserted into the neck part back and forth, right and left by matching the time detected by the light-receiving device, place the electron gun at the set position of the neck part and seal the electron gun to greatly reduce the sealing defect. There is an advantage to improve.

Claims (1)

An electron gun encapsulation device of a cathode ray tube, comprising: a mount on which a cathode ray tube is seated on a turntable, and an electron gun support rod which is positioned below a neck portion of a cathode ray tube seated on the mount and is supported by an electron gun; 12 or the first light source device 15 for irradiating light to one side of the cathode ray tube 40 and the first light receiving device for detecting light emitted from the first light source device 15 only at a predetermined angle. A second light source device 17 for irradiating light to the mount rotation hole GM of the electron gun G inserted into the neck portion 40a, and irradiated from the second light source device 17; When the mount 12 and the electron gun support rod 13 rotate, the first and second light source devices 15 and 17 are irradiated from the first and second light receiving devices 16 and 18 to detect whether the time coincides with each other. And a transfer device 20 for transferring the electron gun to the front, rear, left and right sides of the electron gun support rod 13. An electron gun enclosed device, characterized in that the W.