WO2009092509A1

WO2009092509A1 - Control unit for safely re-enabling a ground fault interrupter

Info

Publication number: WO2009092509A1
Application number: PCT/EP2008/068359
Authority: WO
Inventors: Hans-Jürgen Huber; Ludwig Birkl; Johann Herrmann
Original assignee: Siemens Aktiengesellschaft
Priority date: 2008-01-23
Filing date: 2008-12-30
Publication date: 2009-07-30
Also published as: EP2235805A1; CN101926069A; DE102008005687A1; CN101926069B

Abstract

The invention relates to a control unit for safely re-enabling a ground fault interrupter, and a corresponding ground fault interrupter. The control unit (4) for safely re-enabling a ground fault interrupter (1), which has disconnected a load-side power circuit (2), which is to be protected, using a switch element (S1, S2) in a number of current conductors (L) and a neutral conductor (N), safely from the network-side power network (3), has a review unit (41), a re-enable unit (42), and a voltage supply (43), which is electrically isolated from the network-side power and neutral conductors (L, N). Said voltage supply (43) provides a test voltage (U1) for the review unit (41), wherein said review unit (41) applies said test voltage (U1) on the load side between said current conductors (L), said neutral conductor (N), and a ground conductor (PE). The re-enable unit (42) reconnects the load-side power circuit (2) to the network-side power network (3) by closing all switch elements (S1, S2) when the review unit (41) has recognized that a measuring current (I), which is caused by the test voltage (U1), has fallen below a predetermined value.

Description

description

Control device for safe reconnection of a residual current circuit breaker

The invention relates to a control device for safe reconnection of a residual current circuit breaker according to the preamble of claim 1, and a corresponding residual current circuit breaker according to claim 7.

Residual current circuit breakers, also called FI switches, are used wherever it is necessary to make circuits safer for people. If a fault current, such as an earth fault current, occurs in the circuit to be monitored, both the current-carrying phase conductor and the neutral conductor are disconnected and thus the circuit to be protected is completely disconnected from the power supply.

As a rule, the function of current FI switches is based on the principle of summation current transformers, according to which all currents flowing in the circuit to be protected are added with the correct sign. If a current is dissipated to ground somewhere in the circuit due to an earth fault, the sum of the current flowing back and forth is no longer zero in the summation current transformer. The result is a current difference, which leads to the response of the residual current circuit breaker and thus to the separation and disconnection of the load circuit. The shutdown takes place via respective separation sections in the conductors.

The reconnection of the FI-switch, and thus the renewed connection of the load-side circuit, then manually by means of a corresponding handle on the FI switch. However, before restarting, it must be checked whether the error that led to the tripping of the residual current circuit breaker no longer exists.

EP 1569314 A1 shows a FI-switch with an additional circuit device for automatic reconnection of the FI switch. However, this reclosing device has the disadvantage that the isolating sections of the residual current circuit breaker, which safely disconnect the load-side circuit after it has been tripped from the grid-side power supply, are bridged again. As a result, the separation between the load-side circuit and the mains-side power network achieved in the tripping case by the opened separating sections is canceled again.

In EP 1 744 428 A2 a control device for a residual current circuit breaker is described, in which a circuit after a tripping of the circuit breaker, d. H. when open

Contacts of the circuit breaker, an impedance measurement durchfuhrt.

This measurement finds load side among others between one

Phase conductor and a protective conductor or between a neutral conductor and the protective conductor instead. The circuit breaker can be automatically closed again by means of an electric motor.

In DE 24 58 530 T2 an earth fault monitoring device for a three-phase system is described, wherein in a consumer, the three phase conductors of the three-phase system are connected to each other in a neutral point. The earth fault monitoring device detects a short circuit between the neutral point of the load and a protective conductor. Between the star point and the protective conductor to a signal generator is connected, with which a voltage signal is generated. Integrating a current signal caused by the voltage signal causes a short-circuit to be detected. The ground fault monitoring device can be supplied with a battery.

In DE 25 08 979 Al a circuit breaker is described, which has a residual current monitoring unit and a Erdungswiderstand-Uberwachungseinheit. The

Earthing resistance monitoring unit detects when the earth resistance increases to a critical value. The two monitoring units are designed to protect the circuit breaker be triggered independently of each other in a corresponding error case. DE 60 2004 008 573 T2 describes an automatic circuit breaker for a circuit breaker comprising a circuit for checking the connection of the residual current circuit breaker to the power line and a circuit for detecting a leakage current. The circuit for verifying the connection verifies that there is a sufficiently low impedance between two test points, thereby indicating the presence of a consumer.

In US 4,979,070 A a reclosing device for a residual current circuit breaker is described, which performs an impedance measurement between the consumer network and a protective conductor after a tripping of the residual current circuit breaker, whereby an automatic closing of the circuit breaker is prevented in a persisting ground fault.

The object of the invention is to provide a control device for safe reconnection of a residual current circuit breaker and a corresponding residual current circuit breaker.

This object is achieved by the control device for safe reconnection of a residual current circuit breaker according to the features of claim 1, and by the residual current circuit breaker according to the features of claim 6.

Both the inventive control device for safe

Restarting a residual current circuit breaker and the inventive residual current circuit breaker itself allow automatic restart after a tripping of the residual current circuit breaker.

The present invention is characterized in particular by the fact that the control device and the residual current circuit breaker are designed so that by the switching elements of the residual current circuit breaker caused disconnections are not electrically bridged again by the control device. Thus, on the one hand in the discharged state of the residual current circuit breaker, the safe separation of to be monitored from the residual current circuit breaker load side circuit continues to be ensured by the grid-side power grid. On the other hand, by the galvanic isolation of the power supply of the control device of the network-side conductors of the power grid, which required for automatic restart

Insulation measurement between load-side conductor and ground conductor without electrical bridging the separation sections allows. Thus, a safe operation of the residual current circuit breaker is ensured.

The control device also has a checking device, which is connected via a coupling element galvanically isolated to the first checking device according to the preamble of patent claim 1. This further check device sets the network side between the

Neutral conductor and the ground wire to another test voltage. The reclosing device connects the load-side circuit by closing all switching elements again with the grid-side power grid, when one, determined by the further Prufspannung impedance between netzseitigem neutral conductor and ground wire falls below a predetermined value. This ensures that a previously carried out by the first Uberprufeinrichtung insulation measurement between load-side conductor and ground conductor due to a faulty ground connection of the ground conductor provides no false result.

The present invention is suitable both for single-phase power grids with a conductor, as well as for multi-phase power grids, with, for example, three conductors.

Preferably, the voltage supply of the control device is designed as a transformer, the primary side of the network side Power supply is supplied and the secondary side provides the necessary for the insulation measurement Prufspannung on the load side of the residual current circuit breaker. Due to the electrical isolation between the primary and secondary side of the transformer is further ensured that in the triggered state of the residual current circuit breaker whose open separation sections are not bridged by the control device. Thus, in particular, when the control device is integrated in the residual current circuit breaker, a compact design of a residual current circuit breaker with automatic

Reclosing can be achieved without losing the safe separation of the conductors is lost.

In another advantageous embodiment, the power supply of the control device via a, supplied from outside of the residual current circuit breaker power source is achieved. This is particularly advantageous when the control device is attached nachtraglich to a housing of the residual current circuit breaker or installed in this.

In a further advantageous embodiment, the voltage supply of the control device itself is designed as an energy store, which is thus connected to the load-side current and neutral, so that it is charged only in the non-triggered state of the residual current circuit breaker. Thus, a safe, compact, cost-effective integrated solution for a safe residual current circuit breaker can also be achieved here.

Preferably, a further switching element between the ground conductor and the control device is provided, which is in operative connection with the switching elements in the conductors and the neutral conductor. This further switching element activated at the time of tripping the residual current circuit breaker simultaneously with the opening of the

Switching elements, the control device, so that immediately after the triggering the control device can be started with the insulation test. In the following, the invention will be described by way of example with reference to the embodiment shown in the figure.

Shown is a single-phase residual current circuit breaker 1, also called FI-switch, which has interrupted the current conductor L and the neutral conductor N by means of the switch elements Sl and S2. As a result, it has been achieved that a load-side circuit 2 to be protected from the residual-current-operated circuit breaker 1 (with a dashed-line load) is completely and thus safely disconnected from the mains-side power network 3.

The residual current circuit breaker 1 has for this purpose a measuring device 10, which taps and measures the current flowing in the current conductors L and neutral N current load side after the switching elements Sl and S2 on the conductors L and N. In addition, an evaluation device 20 is provided which compares the totality of the measured currents with a reference value. This evaluation device can operate, for example, according to the summation current transformer principle. Depending on the result of this evaluation device 20, a shutdown device 30, as shown, the switching elements Sl and S2 open, or if there is no error, the switching elements Sl and S2 keep closed. This is usually done via a corresponding relay K, which is controlled by the shutdown device 30.

According to the invention, a control device 4 is now additionally provided. This comprises at least one checking device 41, a reclosing device 42 and a voltage supply 43 which is galvanically isolated from the line-side current and neutral conductors L and N. This voltage supply provides a checking voltage U1 for the checking device 41. The Uberprufeinrichtung 41 sets this test voltage Ul load side between the conductor L and the ground conductor PE and between the neutral conductor and the ground conductor PE, so as to measure on the basis of the measuring current I, the impedance between the current L and neutral N and earth conductor PE. This can be advantageous by means of two Resistors 46 and 47, which connect the Uberprufeinrichtung 41 with the conductor L and the neutral conductor N.

The reclosing device 42 will then connect the load-side circuit 2 again by closing the switching elements S1 and S2 to the grid-side power supply 3 when the checking device 41 detects that the measurement current I caused by the test voltage U has fallen below a predetermined value and thus the impedance between current - And neutral conductor or ground conductor PE has exceeded a predetermined value.

The device according to the invention is characterized in that the control device 4 has a voltage supply 43 which is galvanically isolated from the line-side current conductors. This can be achieved in a variety of ways, but not in the figure. For example, this power supply 43 may be designed as an internal or external energy store. In its simplest embodiment, this could be a battery or other battery. If this energy store is arranged externally, appropriate connections must be provided on the control device 4. If the energy store is arranged internally, that is to say in a housing of the control device, the battery could also be connected to the load circuit 2 in such a way that it is charged by the latter. However, this is only possible at the times in which the load circuit 2 is connected to the power grid 3. This means that a charge of the internal energy storage device 43 is only charged in the normal, non-triggered, operating state of the residual current circuit breaker 1. Alternatively, the power supply 43 could also be a transformer whose

Primary side of the grid-side power supply 3 is supplied and its secondary side provides the necessary for the insulation measurement Prufspannung on the load side 2.

In addition to the review 41, the

Wiederereinschalteinrichtung 42 of the power supply 43 has the embodiment shown in the figure additionally still another Uberprufeinrichtung 44. This lays net side between the neutral conductor N and the ground conductor PE another test voltage U2. This test voltage can be derived from the mains 3, with a safe separation between the conductor L and the ground conductor PE, for example by means of a transformer, should be adhered to. About one

Coupling element 45, this further inspection device 44 is electrically isolated connected to the reclosing device 42 and the Uberprufeinrichtung 41. The reclosing device connects the circuit 2 by closing all the switching elements Sl and S2 only with the power grid 3 when the, determined by the further Prufspannung U2 impedance between neutral N and ground conductor PE falls below a predetermined value. This ensures that the load-side measurement does not refer to a faulty earth conductor potential.

For a further improved interaction between the basic functions 10, 20, 30, Sl, S2 and K of the residual current circuit breaker 1 with those of the inventive control device 4, a further switching element S3 between earth conductor PE and control device 4 can also be provided, which with the switching elements Sl and S2 is in active connection. Its contact is closed only when the two other contacts Sl and S2 are opened and vice versa. Thus, the controller 4 is only switched to the basic functions of the residual current circuit breaker 1, if this has been triggered. An activation of the control device 4 for measuring and checking the load-side currents thus takes place only in the cases in which there is a load-side fault current detected by the fault current circuit breaker.

The exemplary embodiments described above using the example of a single-phase network of the control device according to the invention and of the residual current circuit breaker can accordingly also be applied to multi-phase networks with more than one current conductor. The test voltage Ul is then applied via further resistors to the corresponding current conductors.

Claims

claims

1. Control device (4) for safe reconnection of a residual current circuit breaker (1) to be protected load-side circuit (2) by means of one switching element (Sl, S2) in a number of conductors (L) and a neutral conductor (N) safely from the network side Power supply (3) has separated, with a Uberprufeinrichtung (41), a reclosing device (42) and one of the network-side current and neutral conductors (L, N) galvanically isolated

Power supply (43), which provides a Prufspannung (Ul) for the Uberprufeinrichtung (41), wherein the Uberprufeinrichtung (41) this Prufspannung (Ul) on the load side between the conductors (L), the neutral conductor (N) and a ground conductor (PE) applies and the reclosing device (42) reconnects the load-side electric circuit (2) by closing all the switching elements (S1, S2) to the mains-side power supply (3) when the checking device (41) has detected that the one provoked by the test voltage (U1) Measuring current (I) has fallen below a predetermined value, characterized in that a further Uberprufeinrichtung

(44) is provided, the mains side between the neutral conductor

(N) and the earth conductor (PE) another test voltage (U2) applies, and the reclosing device (42) the circuit (2) by closing all the switching elements (Sl, S2) only to the power grid (3) connects, if a, impedance determined by the further test voltage (U2) between the neutral conductor (N) and ground conductor (PE) falls below a predetermined value, a coupling element (45) being provided between the checking device (41) and the further checking device (44), the two checking devices ( 41, 44) is galvanically separated from one another.

2. Control device according to claim 1, characterized in that the power supply (43) is a transformer whose primary circuit is supplied by the power grid (3).

3. Control device according to claim 1, wherein the voltage supply (43) is an energy source arranged outside the control device (4).

4. The control device according to claim 1, wherein the voltage supply is an energy store.

5. Control device according to claim 4, wherein the energy store is charged by the load circuit.

6. Residual current circuit breaker (1) for safe separation of a load-side circuit (2) to be protected from the grid-side power supply (3) with

- Each a switching element (Sl, S2) in a number of

Electricity conductors (L) and a neutral conductor (N) for disconnecting the current and neutral conductors (N) between the electric circuit and the mains,

- A measuring device (10), in the power conductors (L) and

Neutral conductor (N) measures flowing currents,

- an evaluation device (20) which compares the totality of the measured currents with a reference value, - a shutdown device (30) which opens all switching elements (Sl, S2),

- And a control device (4) according to one of the previous

Claims 1 to 5.

7. Residual current circuit breaker according to claim 6, characterized in that a further switching element (S3) between the ground conductor (PE) and control device (4) is provided, with the switching elements (Sl, S2) in the conductors (L) and the neutral conductor (N) in Active compound is.

8. Residual current circuit breaker according to claim 6 or 7 characterized in that the control device (4) is located in the housing of the residual current circuit breaker.

9. Residual-current circuit breaker according to claim 6 or 7 d a d u r c h e k e n e c i n e s, the control device (4) has its own housing, which is attached to a housing of a conventional residual current circuit breaker.