JPS6326496B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to an alignment measuring device for a cathode ray tube electron gun and a neck portion, which makes it possible to measure the eccentricity, inclination, and rotation angle of the electron gun and neck portion of a cathode ray tube with high accuracy.

FIG. 1 is a side view of essential parts of an example of an in-line electron gun assembly. In the figure, this electron gun assembly includes a stem 2 that holds and fixes the electron gun assembly 1 and is welded to a cathode ray tube bulb (not shown).
, three independent cathodes 3, a G ₁ electrode 4, a G ₂ electrode 5, a G ₃ electrode 6, 7, and a G ₄ electrode 8 formed integrally on the same axis and separated by a predetermined distance. Each of these electrodes is supported and fixed by a plurality of bead glasses 9. 10 is a shield cup, and this shield cup 10 is fixed to the _G4 electrode 8 by welding. 11 is a contact spring whose one end is fixed to the shield cup 10 and the other end is curved; and 12 is a getter.

The electron gun assembly thus constructed is attached to the cathode ray tube bulb in the following manner. That is,
The bulb has an internal conductive film on its inner surface, and the electron gun assembly has the contact spring 11 in contact with this internal conductive film, and the central axis of the electron gun assembly is aligned with the tube axis of the cathode ray tube. Then, the stem 2 is welded to the open end of the neck portion and sealed.

In a cathode ray tube constructed in this way, the electron gun assembly 1 particularly dislikes variations in rotation angle, tilt, eccentricity, etc. with respect to the panel fluorescent surface, so it is desirable that the error in the mounting position be zero. It is rare.

Conventionally, as a means to solve such problems,
Eccentricity and inclination of the electron gun body 1 during assembly of the electron gun are checked by accuracy inspection including both of these by placing a contact rod 13 in contact with the outer peripheral surface of a shield cup 10 having a cylindrical shape as shown in FIG. The stem 2 (see FIG. 1), which does not touch the sensor, is rotated about its axis in the direction of the arrow, and the contact or non-contact of the contact rod 13 is detected. According to this method, the shield cup 10 is the only part with a cylindrical shape, and the measurement position is limited to this one point. It could not be said that a complete accuracy test was carried out, as it only measured the rotational vibration of the machine. Also,
Regarding the rotation angle of the electron gun structure 1, see Fig. 3a,
As shown in Fig. b, a reflecting mirror 14 is placed above the shield cup 10, and the image shown in Fig. b projected onto the reflecting mirror 14 is visually determined using a telescope 15 to detect the rotation angle θ. However, the efficiency is extremely poor,
Moreover, the measurement accuracy was also low. Regarding the rotation of the electron gun assembly 1 in the sealing process, for example, as shown in _FIG . 15 and visually measure the alignment of the holes 7a and 7b to see if they match or don't match, but this method is extremely inefficient and has low measurement accuracy. Regarding the cathode ray tube bulb, the funnel part 16 is fixed with a reference pad 17 as shown in FIG.
However, since the dial gauge 18 has a contact type structure, it is necessary to wait until the temperature of the funnel portion 16 has decreased. Further, there is no means for measuring the eccentricity and inclination of the electron gun assembly 1 and the neck portion 16a of the cathode ray tube.

As described above, eccentricity, inclination, and rotation of the electron gun assembly 1 and the neck portion 16 deteriorate the convergence characteristics and the rotation characteristics, which are the basic characteristics of cathode ray tubes, and thus become extremely important problems in the manufacturing process of cathode ray tubes. Ta.

Therefore, the present invention provides a cathode ray tube electron gun and neck part that completely solves the above-mentioned conventional problems and makes it possible to measure the eccentricity, inclination, and rotation angle of the electron gun and the neck part with high precision and high efficiency. The purpose of the present invention is to provide an alignment measuring device.

In order to achieve such an object, the present invention inserts an electron gun assembly into a cathode ray tube neck, places a parallel light source on one side of the neck, and places an optical line sensor on the other side to detect the parallel light source. The image of the electron gun and the network part formed by parallel light beams is formed on the optical line sensor to measure the position of the reference point of the electron gun and the network part, and then the cathode ray tube is rotated to perform the first measurement. The reference point position is measured at a point symmetrical to the reference point, and the eccentricity, inclination angle, and rotation angle from the reference point of the neck portion and the electron gun are measured from the difference between the two.

The present invention will be explained in detail below using the drawings.

FIG. 7 is a cross-sectional configuration diagram of essential parts for explaining an example of a cathode ray tube electron gun and a neck alignment measuring device according to the present invention. In the figure, the electron gun assembly 1 is housed in the cathode ray tube neck portion 16a, and the electron gun assembly 1 is disposed inside the cathode ray tube neck portion 16a.
A parallel light source 20 such as a tungsten lamp or a laser is fixedly disposed on one side of the neck portion 16a to irradiate parallel light 19 to the neck portion 16a.
On the other side of the neck part 16a facing the electron gun assembly 1, a condensing lens 21 for condensing and receiving parallel light rays 19 transmitted through the electron gun assembly 1 and a line sensor 22 are fixedly arranged on the same axis. There is. In this case, the line sensor 22 is arranged so that the pitch of each sensor element corresponds to the accuracy required for measurement in order to extract the amount of irradiated light as an output voltage.

The alignment measuring device configured as described above is used in the following manner. In other words, the network part 1
A reference point is set as a measurement point of the electron gun assembly 1 housed in the electron gun assembly 6a, and the electron gun assembly 1 is temporarily fixed.
Then, a parallel light beam 1 irradiated from a parallel light source 20
The light beam 9 passes through the neck portion 16a and the electron gun assembly 1, and is received by the line sensor 22 via the condenser lens 21. In this case, each sensor element of the line sensor 22 excites an output voltage corresponding to the amount of light received, and as shown in FIG. The position of each can be detected. This A
and which sensor element the point B corresponds to is first memorized. Next, the valve (not shown) is rotated 180 degrees without changing the positional relationship between the neck portion 16a in which the electron gun assembly 1 is housed.
If the reference points obtained by this are A' and B', then -'/2 is the eccentricity of the neck part 16a at that position, and -'/2 is the eccentricity of the electron gun assembly 1.
It can be detected as the amount of eccentricity at that position. Also, when rotated by 180 degrees, there is only a unidirectional component, but if it is operated at a 90 degree angle, it can be captured as x-y coordinates. Also, if a drive device is provided to move the measuring system or measured system up and down so as to measure at different positions in the height direction, and the points are designated as A'' and B'', respectively, -'' and -'' are the inclinations, respectively. can be obtained as Furthermore, the rotation angle is measured as shown in FIG.
That is, by using the flat electrode surface of the electron gun assembly 1,
For example, the parallel light beam 19 is blocked by the G ₃ electrode 7, and when the electron gun assembly 1 is rotated, the point where the blocking portion A becomes the minimum is determined. At this time, a pulse motor is used as a drive source to rotate the electron gun assembly 1, and the rotation angle can be determined by the drive amount of the pulse motor. In this case, the drive amount of the pulse motor can be determined by detecting a portion corresponding to the shielding portion A as Δl on the line sensor 22 and counting the corresponding output voltage value with a pulse counter.

Note that this device has a funnel neck portion 16a.
and the electron gun assembly stem may be directly attached to a sealing machine for sealing by welding, or the above-mentioned two may be aligned and temporarily fixed before the sealing process without being attached to a sealing machine. The sealing may be performed using a sealing machine. It may also be used to inspect the accuracy of the electron gun itself and the funnel.

As explained above, according to the apparatus according to the present invention, the eccentricity, inclination angle, and rotation angle of the electron gun and the neck part can be measured with high precision within a sufficiently applicable range, so that alignment can be performed with high precision. This makes it possible to obtain an extremely excellent effect that can significantly improve convergence characteristics and purity characteristics.

[Brief explanation of the drawing]

FIG. 1 is a side view of essential parts for explaining an example of an electron gun assembly, FIGS. 2 to 5 are diagrams for explaining a conventional electron gun assembly and alignment means of the funnel neck portion, and FIGS. FIG. 8 is a diagram for explaining an electron gun and a neck alignment measuring device and a measuring method thereof according to the present invention. 1...Electron gun structure, 7... _G3 electrode, 16a...
...Network portion, 19...Parallel light beam, 20...Parallel light source, 21...Condensing lens, 22...Line sensor.

Claims (1)

[Claims] 1. A light source disposed on one side of a cathode ray tube neck portion into which an electron gun is inserted and irradiating the neck portion with parallel light rays, and a light source disposed on the other side of the neck portion facing the light source and parallel light rays passing through the neck portion. An alignment measuring device for a cathode ray tube electron gun and a network portion, characterized in that it is equipped with an optical line sensor that receives light.