An apparatus for testing an arc fault circuit interrupter includes an AC signal generator circuit configured to be capacitively coupled to an AC power line and to induce an AC signal thereon and a control circuit configured to control the AC signal generator circuit to selectively enable and disable generation of the AC signal responsive to a waveform of an AC power voltage of the AC power line.

The invention relates to a test system and a method to test a circuit breaker (2) of an electrical switchgear assembly. A sub-station battery (3) of the electrical switchgear assembly is used to generate a supply voltage (7) for the circuit breaker (2) for the testing thereof, wherein the sub-station battery (3) is coupled to a test device (1) in order to generate the supply voltage (7) for the circuit breaker (7) [sic] from an input voltage (6) provided by the sub-station battery (3). The supply voltage (7) is stabilised by means of a voltage regulator (11) of the test device (1).

An apparatus for performing measurements on a utility power device that shares a common ground with the apparatus selectively sends a first high voltage signal via a first lead to a first terminal of the utility power device, measures a first corresponding signal returned via a second lead of the apparatus from a second terminal of the utility power device. While the corresponding first lead and the second lead of the apparatus remain electrically coupled to the corresponding first and the second terminal of the utility power device. The apparatus selectively sends a second high voltage signal via the second lead to the second terminal of the utility power device, and measures a second corresponding signal returned via the first lead of the apparatus from the first terminal of the utility power device.

A method for testing multiple spatially distributed protective devices of an energy supply network. Each of the protective devices is configured to, in the event of a fault occurring in the energy supply network, isolate the fault in the energy supply network. The method comprises: producing an initial test sequence; outputting of the test sequence to the protective devices; detecting outputs of the protective devices that the protective devices output on the basis of the test sequence; analyzing the outputs and generation of inputs for the protective devices depending on the outputs. If the inputs are not part of the test sequence, these inputs are incorporated into the test sequence and the outputting step proceeds. Otherwise, all outputs of the protective devices are evaluated. Each test sequence comprises inputs in the form of process variables of the energy supply network for at least one of the protective devices.

A network equipment test device provides a user interface for user specification of a test traffic source, a test traffic destination, SUT and waypoint topology and one or more test cases. In response to receiving the specified input from the user via the interface, the test traffic source is automatically configured to send the test traffic to the destination via the SUT. The waypoint is automatically configured to measure the test traffic. When the test is initiated, test traffic is sent from the test traffic source to the test traffic destination via the SUT and the at least one waypoint. Test traffic is measured at the waypoint, and traffic measurement results are displayed on a visual map of SUT topology.

A testing apparatus for imposing a traveling wave signal on an electric system signal for testing a fault detector is disclosed herein. The fault detector may be configured to simulate a fault at a particular location by controlling the timing of the traveling wave signal. The testing apparatus may be configured to impose multiple traveling wave signals to test the accuracy of the fault location determined by the fault detector. The testing apparatus may be configured to determine the calculation accuracy of the fault detector. The testing apparatus may impose a traveling wave signal on a signal simulating an electrical signal on an electric power delivery system. The testing apparatus may be used to test capabilities of a fault detector of detecting a fault using traveling waves or incremental quantities.

A high speed controllable load uses a voltage waveform synthesizer and a driver circuit to dynamically control an electronically variable load to generate a current though an arc fault circuit interrupter (AFCI) device under test. Sensors may be used to monitor a source voltage and the output current to generate an arbitrary waveform have a range of voltage and current phase shifts. An optical isolation circuit allows separation of grounds between a control stage and the AFCI device under test.

A method and a system (9) for testing a switching installation (30) for power transmission installations are provided. The switching installation (30) comprises a switch (2) which either connects a first side (6) of the switch (2) to a second side (7) of the switch (2) or disconnects it therefrom, and comprises two earthing switches (10, 11). Each of the two earthing switches (10, 11) is provided to either connect the first side (6) or the second side (7) to earth (1) or to disconnect it from earth (1). To test the switching installation (30), a current is generated through the switch (2) and a magnitude of the current through the switch (2) is determined. In this respect, the two earthing switches (10, 11) are closed while the current is generated and while the magnitude of the current is determined.

An apparatus for testing an arc fault circuit interrupter includes an AC signal generator circuit configured to be capacitively coupled to an AC power line and to induce an AC signal thereon and a control circuit configured to control the AC signal generator circuit to selectively enable and disable generation of the AC signal responsive to a waveform of an AC power voltage of the AC power line.

A test device to test a Rogowski coil and an associated protection device connected to the coil via conductors. The test device includes means to generate at least one test voltage, transformation means to transform the test voltage into a voltage representative of a secondary signal generated by the Rogowski coil, the transformation means including output terminals for connection to conductors, and means to process an output voltage of the coil.