SU1161999A1 - Method of controlling cut-off voltage in sealed-off cathode-ray device - Google Patents

Abstract

1. METHOD OF REGULATING BATTERY VOLTAGE IN A DRAMMED ELECTRON-BEAM DEVICE, including heating the structural element of the device’s electro-optic system to change the distance between the cathode and the control electrode, characterized in that, in order to eliminate the coaxiality and the alignment and parallelism in the alignment and alignment. and simplifying the control method, the control electrode is heated by electron bombardment from the cathode. 2. A method according to claim 1, wherein the control electrode is heated in a pulsed mode. 3. Method according to paragraphs. 1 and 2, which is due to the fact that the heating of the control electrode is effected by increasing the voltage of the cathode voltage by 20–100%.

Description

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S. co; about 1 1 The invention relates to electronic engineering, in particular to the production of electron-beam devices (ELL). There is a known method for controlling the block voltage U- in an electron beam device by varying the distance between the cathode and the anode with the help of spacer elements 1J. The disadvantage of this method is the impossibility of changing the specified distance in the finished device. There is a known method of controlling the blocking voltage in an open EBT, which involves heating the structural element of the electro-optical system to change the distance between the cathode and the control electrodes. According to this method, the cathode heats up with a heater. When the distance between it and the control electrode is changed, a specified value of blocking voltage is obtained, using a power source located outside the device, to fix the cathode. The cathode is attached with the help of two holders, one of which includes the cathode with a tight fit, while the initial distance is set somewhat more than nominal. The cathode is assembled with a second holder with a gap so that they can move with each other. After pumping out the device, gradually increasing filament voltages are applied to the cathode heater and at the same time control tl. As a result of thermal expansion of the cathode sleeve, the distance 6 decreases, while U increases; When a given value U is obtained, the distance 6 is fixed by welding the cathode sleeve c. holder in which the cathode enters freely. Welding is performed using an external energy source, which can be used, for example, an optical quantum generator zj. The disadvantages of this method are possible disruption of the alignment and parallelism of the emitting surface of the cathode relative to the control electrode, as well as the difficulty of regulating U-j. The coaxiality and parallelism of the emitting surface of the cathode relative to the control electrode may be disturbed in the process of changing the distance 6 and 992 of the subsequent welding of the cathode to the second holder, since the cathode enters this holder with a gap. This can lead to a deterioration of the resolution, and in colored tubes to a violation of the purity of the color. The difficulty of regulating Uj lies, firstly, in the need to use a special cathode design with two holders, which eliminates the use of the known unified designs of cathode-heating nodes used in the PSL, and secondly, in using quite complex equipment for welding the cathode with a holder . The purpose of the invention is to prevent the alignment and parallelism of the emitting surface of the cathode relative to the carbon electrode in the regulation process and to simplify the regulation method. This goal is achieved in that according to the method of regulating the blocking voltage in a discharged electron beam device, including heating the structural element of the device’s electron-optical system, to change the distance between the cathode and the control electrode, the control electrode is heated by electron bombardment the cathode. In this case, the control electrode is heated in a pulsed mode with a cathode filament voltage increased by 20–100%. Regulation of the blocking voltage according to the proposed method is carried out as follows. An EBR is assembled, using, for example, a typical design of an electro-optical system (EOS) containing an end-type cathode with a control electrode coaxially arranged with respect to it, which is a cylinder with a bottom, in the center of which there is an opening. After pumping out and training, the filament voltage is applied to the cathode heater, and after the cathode is heated, a positive voltage is applied to the control electrode. In this case, a current 3 begins to flow in the cathode – control electrode circuit, the value of which depends on the distance B, the voltage U, and the emission current 3 of the cathode. The voltage tl is chosen in such a way that the power provided on the control electrode is equal to the product -U to be sufficient to heat it. In this case, mainly the central part of the control electrode is heated, its area is approximately equal to the emitting surface of the cathode. As a result of the heating, distance 6 is increased, and this increased distance remains after the stress is removed. The change in Uj for different types of ELL can be between 10 and 35 V. The change in distance C is explained as follows. In the manufacture of the control electrode, during the shtampovka process, stresses arise in its flat part. When the central part of the control electrode is locally heated, these voltages are removed, resulting in residual deformation. Heating the entire bottom of the part, for example, by high-frequency currents, does not cause such an effect: the distance b, and therefore also U j, is not changed. In the process of regulating Uj, the emission parameters of the cathode are improved. The locking voltage was controlled on two batches of 15 pieces each of different triode type EOS systems with end unified cathode heating units. Control electrodes are made of stainless steel in the form of a cylinder with a bottom, in the center of which there is a hole. The data of both EOS are given in table. 1. T and l and c and 1

Options

EOS Ln. Type of cathode heating unit KPU-18 KSH-16 55 Distance cathode - control electrode, mm 0.12-0.14 0.14-0.16

Gp-Zap Abs 9 Thickness of the control electrode material, mm 0.2 Distance of the control electrode anode, mm, 1.6 Diameter of the hole in the control electrode, mm 0.67 Internal diameter of the cylindrical part of the control electrode, mm 8.9 The regulation was carried out in a pulsed mode by applying to the control electrode a series of 10 positive pulses with a voltage of 2 seconds and a repetition period of 6 seconds with the cathode 9 V (the nominal voltage is 6.3 V). EOS-type was 5-6, for the second about 7 - 9 watts. Measurement of U before and after adjustment was performed using a standard test bench. The measurement results are shown in Table. 2. Table2 Voltage, In iraiuyuschee before regulation 55 - 70 55 - 82 after regulation 37 - 48 42 - 59 initial 13 - 26 12 - 35

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As can be seen from the table. 2, the change in blocking voltage is 20 to 35% of the initial value. During the adjustment, if necessary, intermediate values of change 1) 3 can be obtained.

The use of a pulsed heating electrode reduces the power consumption and reduces the average current drawn from the cathode. However, due to the increase in the amplitude value of the emission current, the temperature of the cathode must be increased by increasing the filament voltage by 20–100%.

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The upper limit is associated with the natural limitation of the filament current in the preheater. With a smaller increase in the voltage across the pulse, the pulsed J warm-up mode becomes ineffective.

The application of the invention allows to eliminate the distortion of the shape of the electron beam associated with the use of

10 coaxiality and parallelism of the emitting surface of the cathode relative to the control electrode in the process of regulation, to increase the yield in the production of ELL, to regulate the blocking voltage in commercially available ELL.

Claims (3)

1. METHOD FOR REGULATING THE LOCKING VOLTAGE IN A SEPARATED ELECTRON BEAM DEVICE, including heating a structural element of the electron-optical device system for changing the distance between the cathode and the control electrode, characterized in that, in order to avoid disturbance of the alignment and parallelism of the cathode relative to the control electrode control method, the control electrode is heated by electronic bombardment from the cathode. 2. The method according to p. ^ Characterized in that the control electrode is heated in a pulsed mode. '' 3. The method according to PP. 1 and 2, characterized in that the control electrode is heated when the cathode glow voltage is increased by 20-100%. >