CS243331B1 - Double Magnetic Lens Magnetic Lens Focus Coil with Magnetic Deflection and Focus - Google Patents

Abstract

The solution concerns a focusing coil with a double magnetic lens, which enables beam focusing for screens with magnetic focusing and deflection. The essence of the solution is that it uses the principle of a focusing coil with a main magnetic lens, supplemented by a second centering lens, created by a permanent magnet. Both magnetic lenses are close together and their magnetic effects are added up and are located closer to the screen system. Simple electrical circuits are used to control the focus. The solution can be used in all applications with screens with magnetic focusing, where higher demands are placed on good focusing.

Description

SUMMARY OF THE INVENTION The invention of a double-magnetic focusing coil for magnetic focus and deflection screens.

A single-magnetic focusing coil has a closed housing of magnetically conductive material, where an air gap is defined within the magnetic circuit to the type of screen used. Its normal location is towards the deflection coil.

The principle is that the magnetic field created by the coil in the air gap creates a magnetic lens that concentrates the electron beam of the screen to a narrow point. Focusing is done by changing the direct current, usually from a stabilized current source. The disadvantage of this simple magnetic circuit is that a spot blurs in some corner of the image used.

It is possible to use two permanent magnets for sharpening, where the change of magnetic field is regulated mechanically by changing the distance of these magnets. The disadvantage of this solution is that the external magnetic circuit is open, may itself disturb or be disturbed by other magnetic circuits from other close-to-display screens, and there is also a blurring of a point on some corner of the image used.

The two ferrite magnets are glued together to form a closed external magnetic circuit.

The magnetic field is changed by inserting the magnetic shunt within the magnetic circuit. The disadvantage is again the blurring of the point in some corner of the used display.

The dynamic focusing of the electron beam, when using a focusing coil, places extreme mechanical demands on the precise alignment of the electron beam given by the screen system with the magnetic field axis from the focusing coil.

The DC current flowing through the focusing coil varies according to the position of the screen dot deflection. The current waveform has either an exponential waveform or other suitable function. The advantage of the solution is that dynamic focusing ensures good focusing of the point over the entire screen area of the screen.

The disadvantage of the solution is that the control electrical circuits are complex, a large current is required, changing according to a suitable function, and rapid changes must be achieved, as with deflection circuits, as well as high requirements for precise mechanical design.

The aforementioned drawbacks are eliminated by a double-magnetic focusing coil, which consists in that the encapsulated focusing coil with the main magnetic lens and the permanent magnet form a second centering magnetic lens. The magnetic effects of the two magnetic lenses add up and are located closer to the screen system.

The advantage of this solution is that the external magnetic circuit is closed and thus does not interfere with the magnetic field of the next screen when it is placed near and is not disturbed by the magnetic field from the second near the placed screen. The electrical circuits for controlling the focusing point are simple, even the original ones, which were designed for the focusing coil with one magnetic lens. Said principle of the invention essentially eliminates the disadvantages described above, allows simple solution of electrical circuits and good focusing at all corners of the image used.

An example of one of the possible designs of the double-magnetic focusing coil is shown in the attached sectional side view.

The deflection coil is slid onto the screen 1 as close as possible to its conical portion (not drawn). Behind it there is a sharpening coil holder 6 which is made of magnetically non-conductive metal or plastic and in which the encapsulated sharpening coil 6 with the main magnetic lens 16 is inserted. In a housing 8 of magnetically conductive material, a coil with a winding 6 is inserted. secured by a cap 6 with a thread of magnetically conductive metal.

The terminals of the encapsulated sharpening coil 3 are connected to the terminals 5, there are three angles Ά with holes at the top of the housing 8 and a silicone rubber 9 is glued inside the housing 8, which forms a resilient fit for the neck of the screen.

The second centering magnetic lens 17 consists of a permanent magnet 10 of ferrite or of another material axially magnetized, in the form of an annulus, which itself holds on the lid 6 of the encapsulated focusing coil 6. Due to the fit of the cap 6, it is possible to move the permanent magnet 10 to a limited extent.

Mechanical locking of the magnet against unwanted displacement is ensured by a thrust cap 11 formed by a washer 12 onto which the felt 13 is glued. The thrust cap 11 secures the permanent magnet 10 against unwanted displacement by means of three bolts 14 to three angles 10 positioned 120 ° around the circumference The encapsulated sharpening coils. The screen base 15 is slid onto the screen pins £. It can be clearly seen from the figure that both magnetic lenses are located closer to the screen system.

The main magnetic lens 16 is an encapsulated focusing coil 6 where the point of the screen can be focused by changing the direct current. The second centering lens 17 is an axially magnetized ferrite or other permanent magnet 10 having two functions.

By displacement over the cap 6, it allows alignment of the electron beam from the magnetic field axis display system 6 from the encapsulated focusing coil 6 and forms a second centering magnetic lens 17.

The location of the two magnetic lenses is closer to the screen system. This allows the earlier focusing of the electron beam of the screen to a narrow point, which is then visible on the screen. When using this double-magnetic focusing coil in a stable version, it is not necessary to secure the permanent magnet 10 against adjustment after adjustment, since it retains itself on the cap 6.

For mobile operation, it is suitable to secure the permanent magnet 10 after adjusting the centering by pulling the cap 11 by tightening by means of three bolts 14 to three angles po positioned 120 ° along the circumference of the housing 4 of the encapsulated sharpening coil 4.

This design allows use in difficult mechanical and climatic conditions. Electrically, it is necessary that the current flowing through the encapsulated sharpening coil 6 with the main magnetic lens 16 is consistent with the orientation of the permanent magnet 10 in order to promote both magnetic effects.

The invention can be used in all applications with magnetic focus screens where greater focus is placed on good focusing.

Claims (1)

OBJECT OF THE INVENTION Sharpening coil with double magnetic lens for magnetic deflection and focusing screens, characterized in that it consists of a sealed focusing coil (3) with one main magnetic lens (16) with an additional permanent magnet (10) axially magnetized, which forms the second centering a magnetic lens (17), wherein the two magnetic lenses (16, 17) are placed side by side and are oriented closer to the display system (1), wherein the double magnetic lens focusing coil (3) forms a closed external magnetic circuit,