PL225005B1 - Residual-current device (RCD) system - Google Patents

Description

The subject of the invention is a residual current device designed to be installed in low voltage power networks, to protect people against electric shock.

In the disclosure of JP 2002191121, Ratio differential relay provided with higher harmonie locking function, the first and second inputs of a RCD with a higher harmonic detection function constitute two circuits for measuring the current of the primary and secondary windings of the monitored transformer, respectively. The current measurement systems are connected with a two-channel analog-to-digital converter system, and an analog-to-digital converter system with a differential input. The digital outputs of analog-to-digital converters are connected to the first and second digital inputs of the microcontroller, respectively. The first digital output of the microcontroller is connected with the control coil of the first relay. The second digital output of the microcontroller is connected to the first logic negation gate, the output of which is connected to the control coil of the second relay. The normally open contacts of the first relay constitute the first control output of the system according to the invention. The first contact of the normally open contact of the second relay is connected to the reference level. The control input of the system according to the invention is connected to the second contact of the normally open contact of the second relay and to the first input of the control coil of the third relay, the second input of the control coil connected to the reference level. The first contact of the normally open contact of the third relay is connected to the positive supply voltage. The second contact of the closing contact of the third relay is connected with the first terminal of the first resistor and the input of the second logic negation gate, the output of which is connected to the third digital input of the microcontroller. The second end of the first resistor is connected to the reference level. The inputs of the AC adapter are the supply inputs of a known residual current device.

In the Direct-current differential device based on embedding technology, known from the CN 202550503 patent, the input of the DC overvoltage protection circuit with the use of embedded technology is connected to the input of the voltage measurement system, the output of which is connected to the input of the analog-to-digital converter of the microcontroller. The first digital output of the microcontroller is connected to the control coil of the relay, the normally open contacts of which are connected in series in the circuit connecting the input with the output of the system according to the invention. The communication port of the microcontroller is connected to the communication port of the embedded system with the attached LCD display. The Ethernet communication port of the embedded system is connected to the LAN network.

Known residual current devices enable the measurement of residual currents of supply lines and disconnection of the monitored power grid circuit in the event of exceeding the permissible leakage current, which results in protection of people against electric shock at direct and indirect contact. It also reduces the effects of damage to devices connected to the power grid. Known residual current protection systems require a guaranteed power supply in the event of a failure of the monitored power lines. Powering known protection systems from the monitored network may cause, in special cases, their switching off before their activation, which disqualifies them as protection devices.

The essence of the residual current device according to the invention consists in the fact that the second input of the first non-isolated power supply with low input impedance is connected to its negative output, to the negative input of the first microcontroller, to the emitter of the second optocoupler and to the first terminal of the first resistor. The second input of the second non-isolated power supply with low input impedance is connected to its negative output, to the negative input of the second microcontroller power supply, to the emitter of the first optocoupler and to the first terminal of the second resistor. The first digital output of the port of the first microcontroller is connected to the cathode of the light-emitting diode of the first optocoupler, the phototransistor's collector of which is connected to the digital input of the port of the second microcontroller. The first digital output of the second microcontroller port is connected to the cathode of the light-emitting diode of the second optocoupler, the phototransistor's collector of which is connected to the digital input of the first microcontroller port. The second digital output of the second microcontroller port is connected to the first terminal of the second control coil of the bistable relay. The first positive supply voltage is connected to the positive output of the first non-isolated power supply, to the anode of the first optocoupler light-emitting diode, to the positive input of the first microcontroller, and to the second end of the first control coil of the bistable relay. The second positive supply voltage is connected to the positive output of the second non-isolated power supply, to the anode of the second optocoupler light-emitting diode, to the positive input of the second microcontroller power supply and to the second end of the second control coil of the bistable relay.

The circuit of the residual current circuit breaker according to the invention allows for any adjustment of the switch-off delay time, which protects the protected installation against accidental switch-offs resulting, for example, from transients when switching on electric energy receivers. The system is also characterized by high reliability and simple construction. The system according to the invention does not require a guaranteed power supply because it uses the current flowing in any supply line. Thanks to the use of two power supplies with low input impedance, the system performs the function of a residual current protection, even if one of the power lines is damaged.

The subject of the invention in an exemplary embodiment is explained in more detail in the drawing showing a schematic diagram of a residual current device.

The first input We1 of the circuit according to the invention is connected to the first input of a low input impedance, uninsulated first power supply Zs1, which occurs when the voltage drop is of the order of 1 V with a current of 10 A flowing through its input. The second input of the non-isolated power supply of the first Zs1 is connected to its negative output, to the negative input of the first microcontroller uP1, to the emitter of the second optocoupler Op2 and to the first terminal of the first resistor R1. The second input We2 of the circuit according to the invention is connected to the first input of the low input impedance second non-isolated power supply Zs2, which occurs when the voltage drop is of the order of 1 V with a current of 10 A flowing through its input. The second input of the non-isolated power supply of the second Zs2 is connected to its negative output, to the negative input of the second microcontroller power supply uP2, to the emitter of the first optocoupler Op1 and to the first terminal of the second resistor R2. The first digital output of the port of the first microcontroller uP1 is connected to the cathode of the light-emitting diode of the first optocoupler Op1, the collector of the phototransistor of which is connected to the digital input of the microcontroller port of the second uP2. The first digital output of the port of the second microcontroller uP2 is connected to the cathode of the light-emitting diode of the second optocoupler Op2, the collector of the phototransistor of which is connected to the digital input of the port of the first microcontroller uP1. The second digital output of the port of the first microcontroller uP1 is connected to the first terminal of the first control coil of the bistable relay S. The second digital output of the port of the second microcontroller uP2 is connected to the first terminal of the second control coil of the bistable relay S. The first positive supply voltage + U1 is connected to the positive output of the non-isolated of the first power supply Zs1, the anode of the light-emitting diode of the first optocoupler Op1, with the positive input of the first microcontroller uP1 and the second end of the first control coil of the bistable relay S. The second positive supply voltage + U2 is connected to the positive output of the non-isolated power supply of the second Zs2, with the anode of the light-emitting diode of the second optocoupler Op2, with the positive input of the second microcontroller uP2 and with the second end of the second control coil of the bistable relay S. The second end of the first resistor R1 is connected to via the analogue-digital converter of the first microcontroller uP1 and with the first contact of the first normally open contact of the bistable relay S, the second contact of which constitutes the first output Wy1 of the system according to the invention. The second end of the second resistor R2 is connected to the analog input of the analog-to-digital converter of the second microcontroller uP2 and to the first contact of the second normally open contact of the bistable relay S, the second contact of which is the second output Wy2 of the system according to the invention.

Inputs: first In1 and second In2 of the system according to the invention are powered from a single-phase low voltage ~ 230V power connection.

In the first operating mode, the first and second normally open contacts of the bistable relay S are closed. The alternating current from the input of the first We1 fed to the first input of the non-isolated first power supply Zs1 flows to its second input, from which, through the first resistor R1 and the closed first contact of the bistable relay S, supplies the first output Wy1 of the system according to the invention. The current from the input of the second We2 fed to the first input of the non-isolated power supply of the second Zs2 flows to its second input, from which, through the second resistor R2 and the closed second contact of the bistable relay S, supplies the second output Wy2 of the system according to the invention. The protected installation with electric energy receivers connected to the outputs of the first Wy1 and the second Wy2 causes the current to flow through: the inputs of the power supplies: the first Zs1 and the second Zs2

At the same time, the current flow through the first and second low-impedance resistors R1 and R2 causes a voltage drop at their terminals proportional to the instantaneous value of the current flowing through them. The voltage from the outputs of the non-isolated power supply of the first Zs1 supplies the microcontroller system of the first uP1. The voltage from the outputs of the non-isolated power supply of the second Zs2 supplies the microcontroller system of the second uP2. Based on the value of the voltage drop across the first resistor R1, in the first microcontroller uP1, the value of the current flowing in the circuit connected to the output of the first Wy1 of the system according to the invention is determined. However, based on the value of the voltage drop across the second resistor R2, in the second microcontroller uP2, the value of the current flowing in the circuit connected to the output of the second Wy2 of the system according to the invention is determined. Then the first microcontroller uP1 sends a message to the second microcontroller uP2 via a galvanically isolated digital line using the op1 op1 optocoupler, and the second microcontroller uP2 sends a message to the first microcontroller uP1 via a galvanically isolated digital line using the second op2 optocoupler. The current value determined in the first microcontroller uP1 is compared with the value sent in the message from the second microcontroller uP2. If the difference in currents recorded in the first microcontroller uP1 exceeds the set threshold or the message from the second microcontroller uP2 is not recorded, then in the first microcontroller uP1 a low state is displayed on the digital line connected to the first coil of the bistable relay S. The current from the digital line of the first microcontroller uP1 starts to supply the first coil of the bistable relay S. At the same time, the current value determined in the second microcontroller uP2 is compared with the value sent in the message from the first microcontroller uP1. If the difference in currents recorded in the second microcontroller uP2 exceeds the set threshold or the message from the first microcontroller uP1 is not registered, then in the second microcontroller uP2 a low state is displayed on the digital line connected to the second coil of the bistable relay S. The current from the digital line of the second microcontroller uP2 starts to power the second coil of the bistable relay S. As a result of powering one of the coils of the bistable relay S, it changes its state, and then the first and second contacts of the normally open contacts of the first and second bistable relay S are opened, breaking the output circuits of the first Wy1 and the second Wy2 of the system according to the invention. The system enters the second operation mode.

In the second operating mode, the power supply circuit of the protected power network is interrupted. The protected network is not powered. The interruption of the power supply circuit of the protected power network also turns off the uninsulated power supplies of the first Zs1 and the second Zs2 and the microcontroller systems: the first uP1 and the second uP2. The system remains in the second mode until the P button of the bistable relay is pressed. Pressing the P button causes the transition to the first mode of the system operation. In the absence of current flow at the outputs of the first Wy1 and the second Wy2 of the system according to the invention, the non-isolated power supplies: the first Zs1 and the second Zs2 remain turned off. Microcontroller systems: the first uP1 and the second uP2 are not powered and remain in the off state, therefore the bistable relay S does not change its state.

Claims (1)

A residual current device in which the second contact of the first make contact of the relay is the first output of the system, and the second contact of the second make contact of the relay is the second output of the system, and the first terminal of the relay's control coil is connected to the digital output of the microcontroller port, characterized in that the second input of the uninsulated The first power supply (Zs1) with low input impedance is connected to its negative output, to the negative input of the first microcontroller power supply (uP1), to the emitter of the second optocoupler (Op2) and to the first end of the first resistor (R1), and the second input of the non-isolated power supply of the second (Zs2) with low input impedance, is connected to its negative output, to the negative input of the second microcontroller power supply (uP2), to the emitter of the first optocoupler (Op1) and to the first terminal of the second resistor (R2), and the first digital output of the first microcontroller port (uP1) ) connected by t with the cathode of the light-emitting diode of the first optocoupler (Op1), whose phototransistor collector is connected to the digital input of the second microcontroller port (uP2), the first digital output of the second microcontroller port (uP2) is connected to the cathode of the light-emitting diode of the second optocoupler (Op2), whose phototransistor collector PL 005 B1 stora is connected to the digital input of the first microcontroller port (uP1) and the second digital output of the second microcontroller port (uP2) is connected to the first terminal of the second control coil of the bistable relay (S), while the first positive supply voltage (+ U1) is connected with the positive output of the first non-isolated power supply (Zs1), with the anode of the light-emitting diode of the first optocoupler (Op1), with the positive input of the first microcontroller power supply (uP1) and with the second end of the first control coil of the bistable relay (S), and the second positive supply voltage (+ U2) ) is connected with the positive output of the second non-isolated power supply (Zs2), with the anode of the second optocoupler light-emitting diode (Op2), with the positive input of the second microcontroller power supply (uP2) and with the second end of the second control coil of the bistable relay (S).