RU2448400C1 - Combined protective cutout device - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: combined protective cutout device comprises a leakage current sensor (1), a peak rectifier-amplifier (2), an inertion RC-circuit with a time-setting resistor and a capacitor (3), a threshold element (4), an actuator (5), a source of power supply (6), a stabilitron (7), a comparator (8), an element of logical OR (9), a second time-setting resistor (10), a controlled divider (11), a resistor (12), the first (13) and second (14) thyristors.

EFFECT: expansion of functional capabilities, due to provision of half-wave leakage of current through a load after opening of a circuit with contacts of an actuator.

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Description

The invention relates to electrical engineering, in particular to automatic devices for protecting people from electric shock while reducing the insulation resistance of power consumers and the appearance of leakage current to the ground and when the mains voltage exceeds the permissible voltage according to GOST 220 + 10% = 242B.

A combined residual current device comprising a leakage current sensor, a peak rectifier-amplifier, an inertial RC circuit with a timing resistor and a capacitor, a threshold element with an actuator, and a voltage regulator on a zener diode are connected so that the output of the leakage current sensor is connected to the peak input a rectifier-amplifier, the output of which is connected to a time-setting resistor, and the time-setting capacitor is connected to the input of the threshold element with an actuator, a comparator, logical OR, a second timing resistor, an adjustable divider and a resistor, while the resistor is connected to the anode of the zener diode and the non-inverting input of the comparator with one pin, the other resistor pin is connected to the negative of the power source and one terminal of the adjustable divider, the other terminal of the adjustable divider is connected to the zener diode cathode, the average output of the adjustable divider is connected to the inverted input of the comparator, the outputs of the peak rectifier-amplifier and comparator through the first and second time resistors are connected to the inputs of a logical OR element, and its output is connected to a time-setting capacitor (RF Patent for the invention No. 2214664, m.cl. H02H 3/32, publ. 2002.07.27).

The disadvantage of this device is its underestimated functionality, due to the fact that when the network voltage exceeds the permissible voltage according to GOST 220 + 10% = 242 V, the network is turned off, and not the voltage value decreases.

An object of the invention is to expand the functionality of the device by reducing the voltage when the mains voltage exceeds the permissible voltage according to GOST 220 + 10% = 242 V. The technical result is achieved by ensuring a half-wave current flow through the load after the mains are opened by the contacts of the executive body.

The essence of the claimed invention lies in the fact that the combined protective device containing a leakage current sensor, a peak rectifier-amplifier, an inertial RC circuit with a timing resistor and capacitor, a threshold element with an actuator and a voltage stabilizer on a zener diode, connected so that the output the leakage current sensor is connected to the input of the peak rectifier-amplifier, the output of which is connected to a timing resistor, and the timing of the capacitor is connected to the input of the threshold ele ment with an executive body, a comparator, a logical OR element, a second timing resistor, an adjustable divider and a resistor, while the resistor is connected to the anode of the zener diode and the inverter is not inverting, the other output of the resistor is connected to the negative of the power source and one output of the adjustable divider, another the output of the adjustable divider is connected to the zener diode cathode, the middle output of the adjustable divider is connected to the inverted input of the comparator, the outputs of the peak rectifier-amplifier and the omparator through the first and second timing resistors is connected to the inputs of the logical OR element, and its output is connected to the timing capacitor, additionally contains the first and second thyristors, the control inputs of which are connected to the output of the comparator, the input of the first and output of the second thyristors are connected to the input wires of the network, and the output of the first and the input of the second thyristor are connected to the output wires of the network.

The figure shows a functional diagram of a power line protection device, where: 1 - leakage current sensor; 2 - peak rectifier amplifier; 3 - inertial RC circuit with a first timing resistor R1 and timing capacitor C; 4 - threshold element; 5 - executive body (relay); 6 - power source; 7 - zener diode; 8 - a comparator; 9 - logical OR element; 10 - the second timing resistor; 11 - adjustable divider; 12 - resistor; 13, 14 - thyristors.

The combined circuit breaker contains a leakage current sensor 1, a peak rectifier-amplifier 2, an inertial RC circuit with a timing resistor and a capacitor 3, a threshold element 4, an actuator 5, a power supply 6, a zener diode 7, a comparator 8, a logical OR element 9, the second timing resistor 10, an adjustable divider 11, the resistor 12, the first 13 and second 14 thyristors, and the output of the leakage current sensor 1 is connected to the input of the peak rectifier-amplifier 2, the output of which is connected to the timing resistor, and the time the supply capacitor is connected to the input of the threshold element with an actuator, a comparator, a logical OR element, a second time-setting resistor, an adjustable divider 11 and a resistor 12, while the resistor 12 is connected to the anode of the zener diode 7 by one output and to the non-inverting input of the comparator 8, the other output of the resistor 12 is connected to the minus of the power source 6 and one terminal of the adjustable divider 11, the other terminal of the adjustable divider 11 is connected to the cathode of the zener diode 7, the middle terminal of the adjustable divider 11 is connected to the inverter the input to the comparator 8, the outputs of the peak rectifier-amplifier 2 and the comparator 8 through the first and second timing resistors are connected to the inputs of the logical OR element 9, and its output is connected to the timing capacitor, the control inputs of the first 13 and second 14 thyristors are connected to the output of the comparator 8, the input of the first 13 and the output of the second 14 thyristors are connected to the input wires of the network, and the output of the first 13 and the input of the second 14 thyristors are connected to the output wires of the network.

The device operates as follows. The operation of the device according to the signal from the leakage current sensor is no different from the work of the prototype. The difference is that the device must have an additional channel for measuring the voltage of the network and the formation of a tripping signal. In electronic RCDs, the power of semiconductor devices is carried out from a transformerless power source, so there is no galvanic separation of any point in the circuit from the network. This imposes a requirement that all potentials of a circuit must be measured with respect to a common zero bus. In the inventive device, such a bus is a minus the power source. Therefore, the signal about the voltage of the network must be taken after the power source. It is known that during the operation of the parametric voltage stabilizer, the current through the zener diode 7 is approximately proportional to the mains voltage, i.e. the equalities I ₇ = k · U of the _network hold. Accordingly, the voltage drop across the resistor 12 is also proportional to the network voltage U ₁₂ = R ₁₂ · I ₇ = k · R ₁₂ U _network . If the resistance value of the resistor 12 is of the same order as the differential resistance of the zener diode 7, then the stabilization quality is almost not reduced and a stabilized voltage is supplied to the voltage divider 11, which is practically independent of the mains voltage. Thus, a stable adjustable reference voltage U ₁₁ is supplied from the divider 11 to the inverting input of the comparator 8, and the voltage U ₁₂ = k · U of the _network is supplied to the non-inverting input from the resistor 12. By adjusting the reference voltage U _11, it is possible to configure the comparator 8 so that a voltage will appear on its output when the network voltage reaches 242 V or more. The output voltage of the comparator 8 through the second timing resistor 10 charges the capacitor C to a voltage at which the element 4 and the actuator 5 are triggered. This leads to the disconnection of the contacts of the circuit breaker, which provides protection against high voltage.

To ensure lower voltage supply, the first 13 and second 14 thyristors are used. The voltage from the output of the threshold element 4 is controlled by the executive body 5, the contacts of which disconnect the mains voltage. In this case, a control signal is supplied from the output of comparator 8 to the control inputs of the first 13 and second 14 thyristors, they open and carry out a half-wave current flow through the load, which reduces the network voltage by half.

Claims (1)

Combined residual current device containing a leakage current sensor, a peak rectifier-amplifier, an inertial RC circuit with a timing resistor and a capacitor, a threshold element with an actuator and a voltage stabilizer on a zener diode, connected so that the output of the leakage current sensor is connected to the input of the peak rectifier -amplifier, the output of which is connected to a time-setting resistor, and the time-setting capacitor is connected to the input of a threshold element with an actuator, a comparator, a log element OR, a second timing resistor, an adjustable divider and a resistor, while the resistor is connected to the anode of the zener diode and the non-inverting input of the comparator, one terminal is connected to the negative of the power source and one terminal of the adjustable divider, the other terminal of the adjustable divider is connected to the zener diode, the average output of the adjustable divider is connected to the inverted input of the comparator, the outputs of the peak rectifier-amplifier and comparator through the first and second time-setting resistors s are connected to the inputs of the logical OR element, and its output is connected to a timing capacitor, characterized in that it contains the first and second thyristors, the control inputs of which are connected to the output of the comparator, the input of the first and the output of the second thyristor are connected to the input wires of the network, and the output of the first and the input of the second thyristors is connected to the output wires of the network.