RU2711217C1 - Combined digital protective cut-off device - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: protective shutdown device comprises a leakage current sensor (1), peak rectifier-amplifier (2), resistor (3) and actuating element (7), mechanically connected to RCD (8) contact system, additionally there is synchronization unit (4), pulse counter (5), a digital comparing device (6) and setting unit (14), and the output winding of the leakage current sensor is made two-section, wherein the winding sections have the same number of turns and are connected in series-opposite way.EFFECT: high noise-immunity to influence of higher harmonics of mains voltage at actuation thresholds by current values of leakage current and mains voltage.1 cl, 2 dwg

Description

The invention relates to electrical engineering, in particular to automatic devices for protecting people from electric shock while reducing insulation resistance and the appearance of leakage current to the ground, as well as to turn off consumers when the current value of the phase voltage of the supply network exceeds the maximum permissible level of 242 V, established by GOST 32144 2013. By using discrete signals as the source of information corresponding to spasmodic processes of the magnetization reversal of the core of the leakage current sensor, and introducing additional elements for digital processing of these signals into the device, the influence of higher harmonics of the mains voltage on the response threshold by the effective values of the leakage current and mains voltage is eliminated.

Known electronic protective shutdown devices (RCD), containing the signal amplifier of the leakage current sensor, a power source and a voltage stabilizer [1, 2]. Their disadvantage is the lack of ability to disconnect the protected power consumers with an unacceptable increase in network voltage.

Known protective circuit breakers combined, 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 stabilizer on a zener diode, connected so that the output of the leakage current sensor is connected to the peak input 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 the actuator, comparator, electric 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 non-inverting input of the comparator with one output, the other output of the resistor is connected to the minus of the power supply and the first output of the adjustable divider, the second output of which is connected to the zener diode cathode, and the third to the inverting input of the comparator, the outputs of the peak rectifier-amplifier and the comparator through the first and second timing resistors are connected to the inputs of the logic about OR, and its output is connected to a timing capacitor [3]. The disadvantage of this device is the presence of the influence of higher harmonics of the mains voltage on the response threshold according to the effective values of the leakage current and the mains voltage, due to the analog form of the output signal of the leakage current sensor and the analogue method of processing the mains voltage signal. The presence of higher harmonics of the mains voltage is the result of connecting non-linear loads to the network, which include widespread valve converters for various purposes, for example, controlled rectifiers and frequency converters of electric drives, power supplies for welding machines, drivers of LED lamps, etc.

The aim of the invention is to increase the noise immunity of the RCD to the influence of higher harmonics of the mains voltage. This goal is achieved by the fact that in the RCD, a synchronization unit, a pulse counter, a digital comparison device and a setting block are introduced, and the output winding of the leakage current sensor is made in two sections, and the winding sections have the same number of turns and are connected in series with each other.

In FIG. 1 presents a functional diagram of the inventive device. The following notations are accepted: 1 - leakage current sensor, 2 - peak rectifier-amplifier, 3 - resistor, 4 - synchronization unit, 5 - pulse counter, 6 - digital comparing device, 7 - executive body, 8 - contact UZO system, 9 and 10 - the first and second input wires of the network, 11 and 12 - the first and second output wires of the network, 13 - load, setpoint unit 14. The combined digital protective device contains a leakage current sensor 1 connected in series and a peak rectifier-amplifier 2, the output of which is connected to the sum S input the pulse counter 5, and the zeroing R-input of the pulse counter 5 is connected to the output of the synchronization node 4, the input of which is connected to the output wires of the network 11 and 12, and the resistor 3 is connected between the first input wire of the network 9 and the second output wire of the network 12, and parallel the digital output of the pulse counter 5 is connected to the first parallel input of the digital comparison device 6, the output of which is connected to the actuator 7, mechanically connected to the contact system of the RCD 8, and I compare the second parallel digital input his device 6 is attached to the output setting unit 14.

The device operates as follows. If the current value of the phase voltage of the supply network does not exceed the maximum permissible level of 242 V established by GOST 32144-2013, and there is no leakage current I ₀ (through damaged insulation or as a result of a person touching the current-carrying load elements), the current difference is I ₁ and I ₂ in the wires to which the load 18 is connected is equal to the current I ₃ (Fig. 2). The resistance of the resistor 3 is selected so that the magnetic flux in the core of the leakage current sensor 1, caused by the inequality of the currents I ₁ and I ₂ , magnetizes the core within the initial magnetic permeability region, i.e. in the region where spasmodic changes in magnetization (Barkhausen jumps) are absent. In this case, the harmonic emf the first and higher harmonics induced in the sections of the winding of the leakage current sensor 1 are equal to each other, and the output signal U of the _output sensor is absent regardless of the level of non-sinusoidality of the mains voltage, because sections of the winding have the same number of turns and are connected in series-counter. As a result, the RCD remains in the on state.

When the leakage current I ₀ appears or when the current value of the phase voltage of the supply network exceeds the maximum permissible level of 242 V established by GOST 32144-2013, the difference between the currents I ₁ and I ₂ becomes sufficient for magnetization reversal of the core of the leakage current sensor 1 in the region of irreversible sudden changes in magnetization. In this case, in sections of the output winding of the sensor, in addition to the harmonic components of the emf the first and higher harmonics induce random pulsed signals caused by Barkhausen surges. When the sections of the output winding are counter-connected, the harmonic components are mutually compensated regardless of the level of higher harmonics of the mains voltage, and random pulse signals are added and fed to the input of the peak rectifier-amplifier 2, which forms rectangular pulses of the same amplitude from them. These pulses are fed to the summing input of the counter 5, which is reset to zero with a period of 10 ms (half the period of the mains voltage) by a pulse supplied to the input R (reset) and generated by the synchronization unit 4 when the mains voltage passes through the zero level. Thus, the content of the pulse counter every 10 ms first rises to the maximum value corresponding to the number of Barkhausen jumps in the core of the leakage current sensor 1, and then is reset to zero. The current value of the contents of the pulse counter 5 in binary parallel code is supplied to the first parallel digital input of the digital comparison device 6. If the maximum value of the contents of the pulse counter exceeds the RCD setpoint, presented as a binary number in the parallel code, and fed to the second parallel digital input of the comparison device 6 from the output of the settings block 14, then at the output of the latter a pulse signal is generated that arrives at the actuator 7 and causes the RCD to trip by actions on the contact system 8.

Tests of the prototype digital RCD were carried out with non-sinusoidality of the mains voltage corresponding to the maximum permissible values of the fifth and seventh harmonics, according to GOST 32144-2013, i.e., six and five percent of the effective value of the fundamental harmonic, respectively. During the RCD test, direct measurements were made with multiple (n = 75) observations of leakage currents and mains voltage, at which the RCD actually worked for the 30 mA and 242 V settings, respectively. Statistical processing of the measurement results showed that, with a confidence level of 95%, the confidence limits of the deviation of the effective values of the leakage current, at which the RCD tripped, from the setpoints of 30 mA were ± 1.8%, and the confidence limits of the deviation of the effective values of the mains voltage, at which The RCD was triggered, from the settings of 242 V amounted to ± 1.5%. Thus, the test results indicate a higher noise immunity of the digital RCD to the influence of the non-sinusoidality of the mains voltage in comparison with analogs and prototypes, for which under the same conditions the said confidence limits are 10 and 4%, respectively.

Sources of information

1. Monakov V.K. RCD. Theory and practice. M .: Energoservice. 2007 .-- 368 p. Access Mode: http://dl.lux.booksee.org/genesis/215000/46efdb15c97bfb33676b1dd0117ca554/_as/[Monakov_V._K.†_UZO._Teoriya_i_praktika(BookSee.org).pdf.

2. The device of protective shutdown of a network of alternating current. RF patent for invention №2124795, IPC Н02Н 3/00, publ. 1999.01.10.

3. Residual current circuit breaker combined. RF patent for the invention No. 2214664, IPC Н02Н 3/32, publ. 2002.07.

Claims (1)

Combined digital protective shutdown device containing a leakage current sensor connected in series and a peak rectifier-amplifier, as well as a resistor, characterized in that the output of the peak rectifier-amplifier is connected to the summing input of the pulse counter, and the zeroing input of the pulse counter is connected to the output of the synchronization unit, input which is connected to the output wires of the network, and the resistor is connected between the first input wire of the network and the second output wire of the network, and the parallel digital output account ika pulses coupled to the first parallel input of a digital comparator, which is connected to the output actuator mechanically coupled to the contact system of the RCD, and a second parallel input of a digital comparator connected to the output of the setting unit.

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