SU693469A1 - Device for ageing discharge devices - Google Patents

Claims (1)

(54) DEVICE FOR TRAINING ELECTRIC AND VOLUME DEVICES E; by means of a second source. FIG. Figures 1 and 2 show the controlled voltage source structure,. The device contains the first adjustable source of constant voltage 1, the ballast resistor 2, from 1 test circuit 3. to monitor the first source, diode 4, high voltage cables 5 and 6, terminals 7 and 8 for connecting the trained device 9, protective screen 10 A discharge electrode 11 with an adjustable electrode distance, a measuring unit 12, a diode 13, a capacitor 14, and a second adjustable source 15 for voltage. The measuring unit 12 is placed between the output of the moving discharge electrode and the grounded output of source 15. Such an inclusion allows for the use of highly efficient current measurement through the trained device 9 due to the fact that ions formed at high voltage discharges (for example, air - inflator 11) and deposited on a grounded body get to the voltage source, mine measuring unit. 12. Structurally, the proposed device is implemented in two parts. In order to increase the safety of the service personnel, terminals 7 and 8 for connecting the trained device 9 are referred by means of 5.6 high-voltage cable sections, from the main circuit, placed in a protective screen 10. This design of the device ensures the protection of personnel from the effects of x-ray irradiation, which may occur during the training of Kyo High-Voltage Vacuum Devices. Elements 1, 3, 12, 15 are presented in the form of functional blocks without clarifying their internal structure. In this case, the construction of the element 3 intended for measuring the voltage is not critical to the operation of the device. Measuring unit 12 of the base: for measuring both the current of the instrument 9 and the voltage of the source 15. The combination of the function of the block 12, caused by the urge to reduce the number of dial instruments in the developed device and is achieved by the corresponding switching of the internal circuits of the block. KoHKipreTHoe performance of 15No additional low-voltage source 15 ticKe is not critical. WLAN K-circuit of the high-voltage regulator nafsyeWors source contains a rectifier powered by an alternating current network, voltage converter 17, valve-capacitor voltage multiplier 18, adjustable pulse voltage 19. The maximum value of the output voltage of source 15 is much smaller than the maximum output voltage of the source 1. The last voltage should exceed the maximum required value of the electrical strength of the trained instrument. The breakdown voltage of the discharge voltage 11 at the maximum distance between the electrodes must also exceed the maximum voltage that must be supplied to the vacuum tube during training. The principle of operation of the device is as follows. The trained device 9 is connected to the terminals 7, 8 placed in the protective screen 10 and connected to the main part of the circuit by means of high-voltage cables 5 and 6. At the initial moment, the electrodes of the detector 11 are closed, the measuring unit is set to the current supply through the trained device 9, and adjustable sources 1 and 15 are set to the minimum output voltage. Starting the training, the voltage value corresponding to the pre-breakdown state of the training device is preliminarily determined. To do this, smoothly increase the voltage of source 1, monitor the voltage on device 9 with the help of a measuring circuit 3, and determine its value corresponding to the area of a sharp increase in the pre-, breakdown (dark) current through the device (the current is controlled by unit 12 and closes source 1 through diode 13). When making these measurements, it is necessary to strive for the device 9 to be in the prebreakdown state for the shortest possible time. After this operation, the electrodes of the discharger 11 are possible distances, the voltage of source 1 is set not lower than the value of the voltage of the device 9 The source of the source 15 charges the capacitor 14, and the voltage on the capacitor is monitored by the measuring unit 12. In this state, the voltage of the sources is almost completely applied to the discharge plate 11. Then, the electrodes of the discharge cell 11 are shifted until a breakdown occurs between them. During the breakdown of the discharger 11, the voltage across it drops, and the voltage of sources 1 and 15 turns out to be almost completely applied to the device 9. Since the source voltage 1 is equal to a value not lower than the voltage of the sample 9, the breakdown develops in the latter. As a result, a circuit consisting of a serial connection of the apparatus to be trained 9 and a discharge. 11, is brought into the conducting state, and a discharge current of the capacitor 14, which closes it for 5 s through the diode 4, flows through it. At the same time, part of the energy of the capacitor 14 is fitted in the circuit 9 to facilitate its training. After the current in the circuit under consideration is reduced to a value of a smaller arc extinguishing current (in device 9 or, discharge 11), the conductivity of the circuit decreases sharply and the discharge of capacitor 14 stops. In the next set of listed operations, the source voltage 1 is higher than the higher voltage values. The voltage of the source 15 regulates the energy accumulated by the capacitor 14 and, consequently, the energy of the sample of the device 9. The energy of the device 9 can also be adjusted changes in capacitor 5 capacitor 14 In addition to the described training procedure, the proposed device also provides other additional training modes. When performing the above-mentioned manipulations with source 1 and discharger 11, if the output voltage 15 is equal to zero (the capacitor 14 is not charged), the device 9 is pulsed with a pulse voltage with amplitude exceeding the breakdown voltage, and a duration comparable to the lag time of the sample. In addition, with the closed discharger 11, the device 9 can be trained in advance of the prebreakdown (dark) Currents. The device provides increased training efficiency, reduced power consumption and reduced device dimensions. The effectiveness of training increases: due to the following factors. The breakdown in the device 9 is initiated by a pulsed voltage arising on the device 9 during the breakdown of the discharge element 11. At the same time, the breakdown current does not pass through the device for a longer time, this worsens the state of the device, in particular, due to the release of gases from electrodes ,. The more congenial release of energy from the capacitor 14 in the interelectrode gap of the trained device 9 is provided. . The initial discharge current proportional to the voltage on the storage capacitor is substantially less. Moreover, it can be adjusted, maintaining the same breakdown energy, by appropriately varying the voltage of source 15 and the capacitance value of capacitor 14. Such control is very effective, as it appears that it is possible to release the energy necessary for flashing and evaporating on the electrodes of irregularities, without the danger of the occurrence of explosive processes at excessive values of the instantaneous power of the discharge, T & kimsebrazom, the proposed device has a new quality - the ability w instantaneous power adjustment pazr so that it has oprelel th value to optimize pezhima toenipovki. The reduction in power consumption is due to the fact that the breakdown in the device 9 arises as a result of the redistribution of voltage between the arrester and the training device, and at the time preceding the discharge of the arrester the source 1 is at idle. The downsizing of the device is mainly due to the use of sources of lower motility. In addition, the use of storage capacitors to lower voltages reduces the requirements for the electrical STRENGTH of the switching elements. Claims. 1. A device for training electrovacuum devices containing an adjustable source of constant voltage, a storage capacitor, and. and an adjustable gaiter, characterized in that, in order to increase the efficiency of the training, reduce the size of the device and reduce the power consumption, an additional adjustable source of constant voltage is connected in series with the voltage source, to the output of which is a storage capacitor The terminals of the voltage sources are connected through a ballast resistor to parallel-connected circuits, one of which contains series-connected terminals for connecting a trainee iborada: a voltage with a regulated, liable distance between the electrodes and a measuring unit to control the current through the instrument being trained and the output voltage of the second source, and the other circuit contains at least two diodes connected in series in the direction opposite to polarity sources, and the common output of the DC sources is connected at the junction point of the diodes. 2, The device according to claim 1, 1 and 2, so that the mobile electrode of the arrester is connected to the grounded output of the second source through the measuring unit. Sources of information taken into account during the examination 1. USSR author's certificate No. 390596, cl. ri 01 J 9/42, 1971. 2, USSR Copyright Certificate under Application No. 2438267, cl. rf 01 I 9/42, 05.01.77 (prototype) " j; i --- “. - ...--. J- v ///: /