SU702429A1 - Optoelectronic system "tsilitron" - Google Patents

Description

Information & Goethe refers to the field of epektrovvy technology, in particular, to erectable optical systems (EOS), used, for example, in such electron-receiving devices, such as color kinescopes. An electron-beam instrument is known in which to focus the beam, use cylindrical elektrostaticheskogo doro ny; . However, the use of aerial EOS for focusing several: beams of two doubles inside the color kinescope cannot be done because of the large dimensions of these EOS, on the one hand, and the narrow throat of the C-tube of a C-tube with a C (amosveedness, on the other hand). is an EOS for color kines: a PA with two or more electron beams located in the same plane, containing an electron beam forming system in the form of immersion lenses, as well as an electron focusing system electron beam formed into a cylindrical electrostatic lens. And the lens; The contents for focusing in the plane of the electron beams are: individual, formed by an electrode system, and the focusing systems of the beam in the / 1 | eperidicular direction are common to all beams. One of the cylindrical lenses is made in the form of: parallel 1x: plates, covering each beam. Moreover, in terms of the Crohner circuit, one of the extreme plates has a terminal connected to an additional power source for creeping convergence of the beams on screen 2. The disadvantage of this well-known EOS is the structural complexity in that it is necessary to additionally have electrical insulation elements in the form of plates that serve to ensure the alignment of electron beams in the center of the screen. The need for ethers of insulated plates leads to the need for additional electrical leads in the vacuum shell of the EDP, either on the leg, or on the neck, or on the cone of the kinescope. In addition, the implementation of lenses in the form of individual plates reduces the accuracy of lens manufacturing, which leads to a deterioration in the resolution of the EOS, significantly complicates the technology of manufacturing the EOS, reduces its electrical efficiency because of the above disadvantages. EOS has not found wide application in color mask kinescopes. The purpose of the present invention is to simplify the design of the electron-optical system while simultaneously increasing the resolution of the system and ensuring that all the beams are aligned at one point on the screen. For this, in the system of electrodes with holes forming cylindrical individual lenses j, the last electrode along the electron beams has a parallel displacement of the median planes of the extreme holes from the plane of symmetry of the last but one along the electron beams of the electrode by distance (O, 01 - O, 06) i in the direction from the plane of symmetry, in order to simplify the manufacturing technology, the size of the holes in the last along the electron beams of the electrode in the direction perpendicular to the plane of symmetry of the last one Electrode can make 2i. where i is the size of the hole in the electrode, located along the course of the electron beams in the direction perpendicular to the plane of its symmetry. ; One of the options for performing EOS is shown on. Drawing. EOS contains separate cathodes 1, monolithic common. modulator 2, monolithic common accelerating electrode 3, monolithic electrodes 4 and 5, forming a common cylindrical lens, monolithic electrode 6, which, together with the second along the electron beams, forms a triple cylindrical Liv electrode, i.e. Three ivid lenses for each of the beams. The system operates as follows. Three cathodes emit three electron beams. Three consumable electronic ka. with parallel axes lying in the same plane, the Formergechl, 1x with three Mercy lenses, fall into a circular cylindrical lens. This lens focuses the beams on the screen in the xv plane perpendicular to the plane of the axes of the beams. Next, the beams fall into a triple cylindrical lens, which focuses the beams on the screen in the plane of the beams. To ensure that all three beams hit a single point. On the screen, the extreme (7 and 8) holes, made in the form of rectangles in the last electrode of the triple lens, are offset from the EOS axis relative to the response holes of the five holes. The dipole moments formed in this case are dried; are the deviations of extreme juts to the mean. By displacing the median planes of the outermost orifices relative to the previous ones by (0.01 O, O) t, it is possible to provide the combination of three beams at one point 9 at a given distance from the lens. V - The order of following cylindrical lenses can be changed: a triple cylindrical lens can be placed first after an immersion objective. Both, and common triple, cylindrical, lenses can be either single or double. The shape of the edges of the holes in the electrodes of the triple lens should ensure that an electric focusing device is obtained in the “l s. one plane of symmetry, therefore, the parallel edges of the holes that form the lens must be extended to at least two widths. Two parallel straight lines can be next. closed, straight, perpendicular, semicircle, or other lines. Testing of vacuum prototypes of EOS, according to the invention, made it possible to determine this mode of operation of the EOS: screen potential - 25 kV; by- . electrode potential - 5-9 kV; electrode potential 4–1.8 KBj electrode potential — 3–400 iBj potential to be locked during cathodic modulation –– + 100 V (with grounded modulator 2). Value. t 4 mm; offset value of about 0.15 mM; distance from a triple lens to the screen is 35 mm. The technical and economic effect of the proposed invention is as follows: The resolving power in the line direction is significantly more pronounced compared to those currently used in EOS kinescopes, which