KR830000922B1 - Focusing device - Google Patents

Abstract

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Description

Focusing device

1 is a cross-sectional view of a state in which the focusing apparatus according to the present invention is attached to a cathode ray tube.

3 is a perspective view of the device.

3 is an exploded perspective view of the device.

4 to 8 are explanatory diagrams of the apparatus.

The present invention relates to an in-line type focusing device for a cathode ray tube.

In order to reproduce color images accurately in a color television receiver, three electron beams of red, green, and blue must be converged at each point on the screen. In this case, the focusing of the part away from the center of the screen is considered by the deflection coil, and the focusing of the center muscle is performed by a focusing device made of magnet means. This type of focusing apparatus, which is generally used, is a ring-shaped four-pole magnet disposed on the neck of a cathode ray tube, and the outer electron beam is shifted in the reverse direction, and the outer electron beam is cut by a ring-shaped six-pole magnet. To make the transition to

However, in such a conventional apparatus, the direction of movement of the electron beam can be changed by rotating the magnet. However, in order to change the moving distance, the magnets must be installed in pairs to be out of the rotation positions of the paired magnets. As a result, four magnets are required for this device, which inevitably increases production costs.

The present invention provides a focusing apparatus that can achieve static focusing with at least two magnets, and at the same time, allow the outside electron beams to move individually. The first and second means are disposed on the neck of the in-line type cathode ray tube via a holder, and the first means is rotated within a predetermined range on the first outer electron beam side of the three electron beams. The mobile device is disposed vertically with respect to the neck side, and similarly, the second means is arranged on the second outer electron beam side, and the first and second electron beams can be focused on the center beam side, respectively. I did it. Hereinafter, the present invention will be described in detail with reference to the embodiments shown in the drawings. 1 is a cross-sectional view of the apparatus of the present invention attached to the neck portion 2 of the in-line cathode ray tube 1 via a holder 3, and FIG. 2 is a perspective view of a state not attached to the cathode ray tube. And Figure 3 is an exploded perspective view. The holder 3 has a cylindrical portion 4 for supporting each magnet to be described later, and a plurality of tongue pieces for fixing with a band 5 and a screw 6 to the neck portion 2 of the cathode ray tube 1 ( 7) and the edge portion 8, and the cylindrical portion 4 is provided with an elastic piece 10 having a click 9 that prevents the magnet and the like from fitting to the cylindrical portion. In addition, the edge portion 8 has a pair of protrusions 13 so that a part of one of the bent pieces 12 is inserted between the bent pieces 11 of the band 5 for preventing the rotation of the band 5. And (14) are formed. (15) and (16) are first and second rotating bodies which are rotatably attached to the cylindrical portion 4 of the holder 3, and the handles 17 and 18 are magnetic return bodies. Guide protrusions 23 and 24 inserted into the contact holes 21 and 22 of the first means 19 and the second means 20, and the annular portions 25 and 26 are formed. In the first and second means 19, 20, the guides 29 and 30 which allow access to the leg portions 27 and 28 of the first and second means 19 and 20 are installed. Reference numeral 31 denotes a first spacer inserted between the first and second pivots 15 and 16, and the base pieces 32 and 33 for elasticity are mounted. (34) and (35) are magnets for purity adjustment, and these magnets are also disposed in the neck portion of the cathode ray tube and are attached to the holder 3. Reference numeral 36 is a second spacer inserted between the second rotating body 16 and the magnet 34 for purity adjustment. The other magnet 35 for purity adjustment abuts the click 9 of the holder 3, and the pieces 32 of the first, second spacers 31 and 36 in the direction of the edge 8. It is pressed against the elastic force by (33), (37), and (38). The first and second means 19 and 20 are attached to the first and second pivots 15 and 16, respectively, and the neck together with the first and second pivots 15 and 16, respectively. The circumference of (2) is rotated, and the first and second pivots (15) and (16) can be slid so as to be displaced vertically with respect to the neck portion (2). The sliding range is determined according to the lengths of the long holes 21 and 22 formed in the first and second means 19 and 20. Contrary to the case shown in the drawing, the long holes 21 and 22 are formed in the first and second pivots 15 and 16, and the guide protrusions 23 and 24 are first and second. It may be formed in the means 19 and 20.

The first and second means may be magnetic return bodies of three or five poles, but the case of three poles will be described here.

In the case where the first outer electron beam R and the first means 19 are located at the same position as in FIG. 4, the magnetic field acting on the first outer electron beam R becomes left, so that the beam emerges from the ground. If it flows, the force F acting on the 1st outer electron beam R will be upward.

In the state of FIG. 4, since the first means 19 is located at the position closest to the neck 2, the force F is the greatest, but when the first means 19 is dropped to the right direction, Therefore, the force F is weakened.

In this case, the magnetic field acting on the first electron beam R is a magnetic field in which the magnetic fields directed from the N poles to the two S poles are equally synthesized, and the direction of the synthesized magnetic field changes even when the first means 19 are separated. Therefore, the moving direction of the first outer electron R does not change.

5 shows a case in which the first means 19 is rotated to a position where the magnetic field acts downward with respect to the first outer electron beam R, unlike FIG. In this case, the force F acts on the first outer electron beam R in the left direction. However, when spaced apart from the neck 2 of the first means 19 in the position of FIG. 5, not only the strength of the force acting on the first outer electron beam R is reduced, but also the direction of the force changes. Be careful.

FIG. 6 shows the state in this case, and the first electron beam R when the first means 19 is displaced to the first position (a), the second position (b), and the third position (c). Since the directions of the magnetic fields (H ₁ ), (H ₂ ), and (H ₃ ) acting on each other are different, the force acting on them also indicates that the directions are different as in (F ₁ ), (F ₂ ), and (F ₃ ). . 7 shows their forces (F ₁ ), (F ₂ ), (F ₃ ) as vectors with respect to the first outer electron beam (R), and the first means is changed from the first position (a) to the third. If it moves to the position (c), it can be seen that the first outer electron beam R moves on the line 39 connecting their vertices.

8 shows the displacement of the first outer electron beam R in the direction of the center electron beam G when the first outer electron beam R is in an off position as shown with respect to the center electron beam G. The case where the first means 19 is rotated to the position to be shown is indicated.

In the above, only the first means 19 has been described, but it goes without saying that the second outer electron beam B can also be similarly controlled.

In addition, the first and second means 19 and 20 together select the angle θ (see Fig. 4) or the magnetization of the magnetic pole so as not to have a substantial effect on the outer electron beam G on the other side. I shall do it. As described above, according to the present invention, it is possible to move the first and second means of the magnetic return body which acts individually on the first and second outer electron beams in a direction perpendicular to the rotational direction and the neck of the cathode ray tube. In this configuration, the first and second outer electron beams can be converged to the central electron beam. As the first and second means, one magnet for each return shape is sufficient, as shown in the embodiment. There is an advantage that it is significantly reduced.

Claims (1)

A constant focusing device for an in-line cathode ray tube, wherein the first and second means of a three-pole or five-pole magnetic return body are disposed on the neck of an inline-type cathode ray tube via a holder and at the same time. The means are rotated on the first outer electron beam side of the three electron beam, and are disposed to move in the vertical direction with respect to the neck portion. Similarly, the second means are arranged on the second outer electron beam side and each of the first And a second electron beam can be focused on the center beam side.

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