SU959270A1 - Apparatus for determining parameters of voltage bursts - Google Patents

Description

(kj DEVICE FOR DETERMINATION OF PARAMETERS

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The invention relates to a measurement technique and can find an application in determining the critical parameters of the characteristics of emissions and voltage dips leading to K; malfunctioning of various types of electrical equipment,: gas discharge lamps of 8HSO pressure, power supply units for electronic devices, relay protection devices, automation and mechanics.

A device is known for extracting a single pulse from a continuous sequence containing two 0-flip-flops, CO- - -.,.

The disadvantages of this device ts are the narrow functionality, i.e. the selection of only one pulse from a continuous sequence.

Closest to the proposed invention 20 is a device for forming power supply interruptions containing a former. rectangular impulses, the input of which voltage RESET

connected to the same mains bus, load element, the first output of which is connected to the first bus voltage, element 2 AND-NOT, two triggers, a binary counter, the input of which is connected to the counting input of the first trigger, the synchronizing input of which is connected to the inverse the output of the driver is direct, the polar pulses, and the inverse output is. with the second input 2-NOT, the output of which is connected to the input of the binary counter t2.

The disadvantage of this device is the long time it takes to determine the critical parameters of the characteristics of emissions and power failure due to the manual control of the device. .

Claims (2)

The purpose of the invention is to accelerate the determination of the critical duration of by-drives and voltage dips causing a failure in the operation of the load cell under investigation. The delivered circuit is achieved by the addition of two keys to the device for determining voltage parameters, operation switch jKHMi, match element, repetition period setting, triacs, one-shot, recording gates, information counter, display unit, control trigger, feedback sensor, button , a transformer and an autotransformer, having control windings, shunted by a triac, whose control electrodes are connected to the output of the corresponding key, the key inputs are connected to the plus bus power supply, and the control inputs, via the operation mode switch, are connected, cooTBeTCtno, to the direct and inverse outputs of the second trigger, the second output of the load element is connected to the secondary side of the transformer, the beginning of which is connected to one branch of the autotransformer winding, which source is connected to the second bus mains voltage, and the end through the primary winding of the transformer to the first mains voltage bus, load element. through the feedback sensor is connected to the control trigger input, the input from the throw of which is connected via a button to the common busbar, and the inverse output of the three control spins is connected to the first input of the coincidence element, the second input of which is connected to the forward output of the square pulse former, and the output to the second input of the 2I-HE and the period master input repetition, the output of which is connected to the counting input of the information counter, the direct outputs of which are connected to the display unit, and inverse - to the first inputs of the recording gates, the second inputs of which are connected to the reset input of the first trigger, and through one ovibrator yield setpoint repetition period, outputs Oentiley recording coupled to data inputs of binary score snip. The drawing shows an arrangement diagram for determining voltage emission parameters. The circuit contains a load element 1 transformer 2 containing windings i-l a-1 2. autotransformer 3 with windings W, 3-0. Mistors 4 and 5, square pulse shaper 6, two keys 7 and 8, match element 9, control trigger 10, button T1, feedback sensor 12, work mode switch 13, element 2AND-HE 14, binary counter 15 , the first trigger 1b, the second. trigger 17, the repetition period setting knob 18, the recording gates 19, the one-shot 20, the information counter 21, the display unit 22. The device operates in two modeling modes: dips and voltage spikes. The mode of operation of the device is determined by setting the switch 13 to the first or second position. Consider the operation of the device in the mode of voltage dip modeling. The information counter 21 is in the zero state, all the device triggers are in one, the switch 7 is open, and a sufficient current is applied to the control electrode of the triac 5 to open it. The latter opens and by its low resistance shunts the control winding of the autotransformer 3 which turns out to be practically short-circuited. The resulting transformation ratio of the transformer 2 and autotransport. formator 3 becomes 2.. W., 2nd Voltage .U, on load cell 1 is set by selecting the appropriate tap on the primary winding of transformer 2. When button 11 is pressed, control trigger 10 moves to zero state, the drop elements 9 open and pulses from the direct output the square pulse generator 6 is fed to the input of a repetition period setting unit 18, which is a divider. frequencies. When a pulse appears at the output of the pulse adjuster 18, the one-shot 20 is triggered. The pulse appearing at the output of the one-shot 20 gates all the gates of the record 19. As a result, the number 00 ... Oe of the outputs of the information counter 21 is written to the binary counter 15 in the return code 11 ... 1. On a predetermined front pulse generated by the repetition period setting knob 18, one pulse code 10 ... O is recorded in the information counter 21 and the number 1 is displayed on the digital display of the display unit 22. When gating recording records 19, the first trigger of the control 16 is set to the zero state, and the second trigger 1 7 is transferred along the leading edge of the next pulse generated at the inverse output of the square pulse former 6. When the second trigger 17 is turned into the zero state the keys 7 and 8 are synchronously switched, the triac 5 closes and the triac k opens, the control winding W ,, of the transformer 2 shunts its small resistance. Transformer 2 turns out to be shorted, which leads to a change in transformation effect, which becomes equal to: V2. . -., The voltage across the load cell T becomes equal to U. Thus, on the load element 1, a voltage dip occurs, whose depth is equal to Vy, and, - - and,. Simultaneously with the transfer of the second trigger 17 to the zero position, the element 2I-NOT opens and the pulses from the direct output of the former 6, through the open coincidence circuit 9 arrive at the count input of the binary counter 15. 15 is set to state 11. f. When one more pulse arrives, the binary counter 15 is updated to the state 00,., O and the first trigger 16 is switched to the one state again. On the leading edge of the next synchronizing pulse, the second trigger 17 returns to the initial state, element 2I-NOT closes, switches 7 and 8 synchronously switching to the initial state, Autotransformer 3 is short-circuited, and the initial voltage is again applied to the load element 1. Consequently, the duration of the modulated voltage dip on load cell 1 is determined by the number of pulses needed to update the binary counter. In the described example, the dip gap on load cell 1 is one pulse, t, e, to one half-period of the mains voltage source. Then, after a period of time determined by the operation of the setpoint generator of the repetition period 16, a one-shot 20 is triggered and the number 10 ,,, О from the outputs of the information counter 21 is rewritten into a binary counter 15 in the reverse code 01 ,,. 1, Consequently, in the next operation cycle of the device overflow of the counter 15 will require two pulses, respectively, and the duration of the simulated voltage drop on the load element T is two half-periods of the source of the network: the external voltage, In the subsequent cycles of the device, the duration emogo failure voltage value is automatically incremented by the duration of one half cycle. An increase in the duration of the modulated voltage dip allows determining the critical parameter of the voltage dip characteristic at which the load of test 1 fails. If at a given voltage dip depth failure of the load element 1 does not occur throughout the duration of the duration, then change the depth of the voltage dip by switching to another branch of the winding of the autotransformer 3. The failure of the test load 1 is fixed by the feedback sensor 12 which, depending on the type and traceable load 1 has a different circuit design. For example, if a voltage relay is examined as a load element 1, then its own normally-closed contacts are used as a feedback sensor 12, one of which is connected to the common bus of the device, and the other to Sy, the control trigger input 10, When when reaching the critical value of the voltage dip area, the relay releases and closes its contacts, the control trigger 10 is transferred to the unit state, stopping the operation of the device. The operation of the device in determining the critical parameters of the voltage surge characteristics occurs similarly to the failure mode simulation, with the only difference being that the switch7. the operating mode key 13 is set to the second position. The proposed device, in comparison with the known ones, makes it possible to significantly shorten the time for determining the critical duration of emissions and voltage sags, which is achieved by automating the modeling process. Claim device A device for determining parameters by dropping a voltage, containing a square wiring pulse driver, whose input is connected to a single mains voltage bus, a load cell, the first output of which is connected to the first mains voltage busbar, element 2I-NOT, two triggers, a binary counter, the input of which is connected to the counting input of the first trigger, whose direct output is connected to the 0 input of the second trigger, the synchronization input of which is connected to the inverse output of the square pulse former, and aersny output - to a second input element m "coagulant 2I-NO, whose output podklyuchenEO To the input of a binary counter, which is, so that, in order to accelerate the determination of the critical duration of emissions and voltage dips, two keys are additionally introduced, the operation mode switch, the coincidence element, the repetition period setting device, triacs one-shot, gates, information estimator, display unit, control trigger, feedback sensor, button, transformer and autotransformer, having control windings, shunted by triacs, whose control electrodes the inputs of the recording gates, the second ones, whose inputs are connected to the reset input of the first trigger and through the one-shot. Sources of information taken into account in the examination / 1. Gutnikov V. S; Integrated electronics in measuring devices, Energie, M., 197, p. . 2. USSR author's certificate in application W 2917013 / 18-2, cl. H 03 K 5/156, from 25.0Л.80, 08 are connected to the output of the corresponding key, the key inputs are connected to the positive power bus, and the control inputs are connected to the forward and inverse outputs of the second trigger via the mode switch of the second element load connected to the tap of the secondary winding of the transformer, the beginning of which is. The swarm is connected to one branch of the transformer winding, the beginning of which is connected to the second mains bus, and the end through the transformer primary winding to the first bus of the mains voltage, the load element is connected to the control trigger installation input ,, through the feedback sensor. the reset input of which is connected to the common bus through a button, and the inverted output of the control trigger is connected to the first input of the coincidence element whose second input is connected to the direct input of the square pulse former and the output -. to the second input of element 2И-НЕ and to the input of the repetition period setting knob, the output of which is connected to the counting input of the information counter, the direct outputs of which are connected to the display unit, and the inverse ones to the first