SU1525629A1 - Device for checking break of electric circuit - Google Patents

Abstract

The invention can be used to control the breakage of electrical circuits with a high-resistance sensor installed on high-voltage equipment. The purpose of the invention is to increase the sensitivity of monitoring the break of an electrical circuit of a high-resistance sensor. The control device of an electrical circuit is connected to a controlled circuit and due to the introduction, in addition to the threshold organ 15, the indicator 17 and the operating voltage source 8, two storage capacitors (NC) 5 and 6, charge and discharge elements 9 and 18, the indicator 17 and thyristor 16, allows monitoring of an open circuit with a high-resistance sensor. In this case, when the wire is broken, after switching off the key 7, NC 5 and 6 begin to discharge, because the discharge speed of NC 6 is much higher than the discharge speed of NC 5, that a voltage pulse occurs on resistor 14, which, opening the thyristor 16, will trigger the indicator 17, giving a signal of an open circuit of the electric circuit 2. 1 Il.

Description

The invention relates to electrical equipment and can be used to control the breakage of electrical circuits of high-voltage, high-resistance sensors.

The aim of the invention is to increase the sensitive control of an open circuit of a high-resistance sensor by additionally introducing c into the device storage capacitors, a key with a control element, a charging element, a resistor, a threshold element, a thyristor and a resistor with corresponding connections. /

The drawing shows a diagram of the proposed device.

The device contains a high-resistance sensor 1, a controlled electric circuit 2 with terminals 3 and 4, the first 2 (storage capacitor 5, the second storage capacitor 6, including an element - button 7, a constant voltage source 8, a charging element, a chain 9, consisting of two resistor-21 ditch 10 and 11 and two decoupling diodes 12 and 13, a resistor 14, a neon lamp 15 acting as a threshold element, the key is a thyristor 16 with a control element, the actuator is a relay 35, the discharge element is a resistor 18.

An electrical circuit 2 is connected to the high-resistance sensor 1, the break of which must be controlled, at 3, the first storage capacitor I 5 is connected to terminal j 4 of electrical circuit 2 by the first lining and the second lining to the second lining of the second storage capacitor 6, output 41 3 of the electric circuit 2 and through the button 7 to the positive pole of the constant voltage source 8, to the negative pole of the constant voltage source 8 is connected the input of charging 4 of the circuit 9, connected through a series-connected resistor 10 and the negative electrode with the first output of the charging circuit 9, and through the resistor 11 and the negative electrode of the diode 12 connected in series with the second output of the charging chain 9, the first output of which is connected to you, water 3 of electric circuit 2, and its second output is connected to the first the plate of the second storage capacitor 6, between the first plates of the storage capacitors 5 and 6 are connected in series resistor 14 and a neon lamp 15, parallel to the first storage capacitor 5 are connected in series thyristor 16 and the indicator relay 17, and the thyristor control electrode is connected to the midpoint of the series-connected resistor 14 and neon lamp 15, and a discharge resistor 18 is connected in parallel with the second storage capacitor 6.

The device operates as follows.

For manual control of circuit 2, press button 7 for a time sufficient to fully charge the storage capacitors 5 and 6. This time is set by selecting the values of the resistors 10 and 11. After releasing the button 7, the storage capacitor 5 begins to discharge from the controlled circuit 2 through the sensor resistance 1, and the storage capacitor 6 through the discharge resistor 18. Diodes 12 and 13 exclude the discharge of the storage capacitors 3 and 5 through any other circuit of the device.

The ratio between the discharge time constants of these circuits is selected so that the voltage on the neon lamp 15 throughout the entire discharge time of the storage capacitors 5 and 6 does not exceed its ignition threshold. Moreover, if the monitored circuit 2 and the sensor 1 do not have breaks, the indicator relay 17 does not work.

If the electric circuit 2 is broken or the sensor 1 is damaged, for example, the photoresistor is blown (cut off), then the storage capacitor 6 is discharged to the resistor 18 with the same time constant, and the discharge current of the storage capacitor 5 is less and is determined mainly only by the insulation resistance of electric circuit 2 The ratio of the discharge time constants of these circuits changes and, since the voltage at the storage capacitor 5 drops slower than at the storage capacitor 6, there comes a time when the voltage on the neon lamp 15 pr vysit its ignition threshold current pulse and will pass therethrough. A voltage jump occurs on the resistor 14, which opens the thyristor 16. It connects the indicator relay 6 to the storage capacitor 5, which is triggered and signals a break.

With automatic monitoring, instead of button 7, any other switching device, for example, a relay, which can remotely control the operation of the monitoring device according to the necessary program, can be used.

The proposed control device allows you to check the sensor at any time without using any additional devices and turning off the high-voltage equipment on which the sensor is installed.

Claims (1)

A device for an electric circuit containing a threshold element, terminals for connecting to a controlled electric circuit, an actuator, an operating voltage source, characterized in that, in order to increase the sensitivity of monitoring an open circuit of a high-resistance sensor, two storage capacitors, a charging element, are introduced into it a bit element, a key with a control element, and the source is constantly used as a source of continuity of the acquisition circuit of the control circuit breaker voltage, the first lining of the first storage capacitor is connected to the first output of the tested electric circuit, the second lining and the second lining of the second storage capacitor are connected to the second output of the tested electric circuit and through the switching element to the DC voltage between the first lining of the first storage capacitor and the first lining a second storage capacitor connected in series with the key control element and the threshold element, parallel to the first storage capacitor includes a series-connected actuator and a key with a control element, the control electrode of which is connected to the key control element, a discharge element is connected in parallel with the second storage capacitor, the input of the discharge element is connected to a constant voltage source, the first output of the charging element is connected to the first lining of the first storage capacitor, and the second output to the first lining of the second storage capacitor.