SU888752A1 - Optronic system for receiving and projecting crt with double crossover - Google Patents

Description

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Nd W I The invention relates to electronic devices, in particular, to designs of electron-optical systems (EOS) of receiving and projection cathode-ray tubes (CRT) of high definition, color CRT, oscillographic and laser CRT. An EOS is known that contains a cathode, a modulator, an accelerating electrode, an anode with a cutting diaphragm, and a focusing system l. The potential and potential of the accelerating electrode are selected in such a way that a second crossover is formed in front of the cutting diaphragm. Reducing the size of the second crossover is possible by changing the potential of the accelerating electrode. With a given size and position of the cutting diaphragm due to the increase in the aperture of the electron beam after the second crossover, the beam current decreases. This AIA is only effective for a low-current CRT beam. An increase in the size of the cutting diaphragm leads to an increase in the electron beam aberrations and a deterioration of resolution over the screen field. The closest to the technical essence of the invention is an EOS consisting of a cathode, a modulator, a casing electrode, an additional diaphragm whose potential is less than the potential of the anode, an anode with a cutting diaphragm, and a focusing system 2. When the potential on the additional diaphragm with In order to reduce the size of the second crossover, the beam current is reduced due to an increase in the electron beam in front of the clipping diaphragm. As a result, the luminance of the screen is reduced. Menenius additional capacity on the diaphragm increases the size of the second crossover and hence to a deterioration in resolution. The aim of the invention is to increase the resolution with increasing beam current. The goal is achieved by the fact that in EOS for receiving and projection CRTs with a double crossover, containing a cathode, a modulator, an accelerating electrode, an additional diaphragm, an anode with a cutting diaphragm and a focusing system, two additional electrodes are installed between the secondary diaphragm and the anode. which along the electron beam is electrically connected to the accelerating electrode, and the second is formed by at least one diaphragm. The drawing shows a diagram of one of the variants of EOS according to the invention. EOS consists of cathode 1, modulator 2 and accelerating electrode 3 with holes 4 and 5, respectively, an additional diaphragm 6 with hole 7, the first additional electrode 8 with hole 9 electrically connected to the accelerating electrode 3 of the second part: 1 body electrode 10 s the hole t1, the anode 12 with the hole 13j of the cutting diaphragm C with the hole 15 electrically connected to the anode 12 of the focusing system 16, the screen 17 on which the electron beam 18, forming crossovers 19 and 20, forms an image 21 along the way of its passage. Focus The steering system can be both electrostatic and magnetic. The drawing shows a magnet on an armored focusing system, since such a lens is used in high definition CRT, in microanalyzers, etc.) the AIA works as follows. An immersion lens formed by cathode 1, modulator 2 and electrode 3 accelerates electrons emitted by cathode 1 and forms the first crossover 19. Electron beam 18 is sub-focused by a lens formed by holes 5.8 and 9. electrodes The first additional electrode 8 with a hole 9 limits the beam aperture by cutting out the peripheral part of the beam 18 and keeps it constant regardless of the change in beam current. Electrodes 3 and 8 are electrically interconnected, and the additional diaphragm 6 has an independent lead. The change in potential on the diaphragm 6 makes it possible to control the current transmission of the electron beam 18 through the opening 9 of the first additional electrode 8, keeping its aperture constant. The opening of the first additional electrode serves as a low-voltage cutting diaphragm. The diameter of the aperture .9- is selected depending on the requirements imposed on the aperture of the electron beam at the entrance to the lens formed by electrodes-8 and 10.

The electron beam 18 is limited in current and aperture with a lens formed by the first additional electrode 8 and the second additional electrode. 10, as well as the lens formed by the second additional electrode and the anode 12, forms the second crossover 20.

Change .potentsiala second additional electrode reaches a desired second krosso1vera size and location on the EOS axis and the electron beam aperture to cut high aperture and, electron beam after the second crossover current limited aperture hole 15 and the high-voltage cut aperture Tt, comprised within a the potential of the second anode, and is focused by the magnetic focusing system 16 on the screen 17, forming the image 21. Since the aperture of the electron beam 18 after the cutting aperture 1 is almost constant when the potential on the second auxiliary electrode 10 changes, the image size on the screen will be minimal when the size of the second crossover decreases. Providing the required beam current is achieved by varying the potential at the additional diaphragm 6, i.e. by increasing the current density in the cross section of the electron beam.

Thus, the proposed EOS will increase the resolution while simultaneously increasing the beam current by limiting the electron beam aperture in the low-voltage part of the EOS before the second crossover, reducing the size of the second crossover, and increasing the current density in the beam.

The use of this EOS will improve the quality of the image in the center and across the screen in indicator and color CRTs, as well as in receiving and projection CRTs.

Claims (1)

ELECTRON-OPTICAL SYSTEM. FOR RECEPTION AND PROJECTION DOUBLE CROSSOVER ELECTRON BEAM TUBES containing a cathode, a modulator, an accelerating electrode, an additional diaphragm, an anode with a cutting diaphragm and a focusing system, which reveals itself in order to increase the resolution with increasing beam current? between the additional diaphragm and the anode there are two additional electrodes, the first of which is electrically connected along the electron beam with the accelerating electrode, and the second is formed by at least one diaphragm. * 888752