SU558209A1 - Device for diagnosing and predicting the electrical strength of the insulation of current-carrying elements - Google Patents

Description

compare amplitudes 11, time interval meter 12, additional trigger 13, elements AND 14, 15, 16, 17, computing unit 18, and emulsion generator 19.

The device works as follows.

When a mechanical (due to the impact of electrodynamic forces) or electrical (partial breakdown or partial discharge) damage occurs in a controlled area of electrical insulation of a current-carrying element that is located between two sensing elements 1, 2, an elastic wave arises, which from the point of origin to the closest sensing element 1 or 2 is converted last into an electrical signal, which is amplified by an amplifier 3 or 4 and is formed into a pulse formed 5 or 6. After that, the generated pulse goes through the circuit OR 7 on the counting input of the trigger 8. The latter, going to the state “one, allows the passage of the pulses from the generator 19 through the AND 16 element into the time interval meter 12. Simultaneously, the emulsion from the generator output 5 or 6 enters through the corresponding element AND 14 or 15 to one of the single inputs of the additional trigger 13. After the trigger 8 has been triggered, the passage of the signal to the single inputs of the additional trigger 13 through the elements 14 or 15 is prohibited. After the elastic wave reaches the second (far) sensitive element 2 or 1 and travels the same path as described above, i.e., through amplifier 4 or 3, driver 6 or 5, element OR trigger 8 returns to its original (zero) state which prohibits the passage of pulses from the generator 19 through the element AND 16 into the time interval meter 12. Thus, the additional trigger 13 fixes the sign of the defect coordinate relative to the center of the monitored section, the numerical value of which is formed in the time meter ervalov 12 and transmitted to the computing unit 18.

In order to prevent the device from falsely responding to extraneous elastic disturbances, the source of which is outside the monitored area, a comparison of the signals from both sensitive elements 1 and 2 in form and amplitude is provided. The amplified signal from the output of amplifier 3 or 4, which is close to damage to the sensing element 1 or 2, passes through a filter 9 or 10 (simulating the attenuation of an elastic wave going at that time to the furthest sensitive element 1 or 2) at the input of the amplitude comparison element 11. Signal From the remote sensing element, having passed through its amplifier and having got through its filter to the input of the comparison element of amplitudes 11, is compared there, with a certain accuracy, with the damped signal from the near sensitive element. If the signals from both sensitive elements turn out to be odpak, in the time interval defined by trigger 8, allowing comparison after the first and prohibiting after the second signal, the comparison element of amplitudes 11 will allow information transfer from the time interval meter 12 through AND 17 to the computing unit 18. The latter allows does not register electrical and mechanical damage occurring at any points of the controlled section of the current-carrying element, select them, depending on the geometry x occurrence, and build on the basis of a histogram of frequency of occurrence of defects.

Claims (1)

Invention Formula A device for diagnosing and predicting the electrical strength of the insulation of current-carrying elements, containing two sensitive elements, the outputs of which through appropriate amplifiers and drivers are connected to the inputs of the OR element, the output of which is connected to the trigger input, the time interval meter and the computing unit, characterized in that In order to improve the accuracy of determining the coordinates of a site, the isolation section is turned off; it is equipped with a pulse generator, an amplitude comparison element, two filters, four elec And with an additional trigger, the inputs of which are connected via two elements AND to the outputs of two drivers, the other inputs of these elements are connected to the inverse output of a trigger, the pulse output of which is connected to the input of the amplitude comparison element, two other inputs of which are connected to the outputs of two amplifiers, and the output of the amplitude comparison element through the third element is AND, another the input of which is connected to the output of the time interval meter, is connected to the input of the computing unit, another input of which is connected to the output of the additional trigger, and the output of the trigger through the fourth the element And, the other input of which is connected to the output of the pulse generator, is connected to the input of the time interval meter.