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 curren
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.
대표청구항▼
1. A method of testing an arc fault circuit interrupter (AFCI) comprising: storing a waveform representative of an arc fault;coupling the AFCI and a controllable load in series with a power source;retrieving the stored waveform;sensing a current through the controllable load and the AFCI;providing a
1. A method of testing an arc fault circuit interrupter (AFCI) comprising: storing a waveform representative of an arc fault;coupling the AFCI and a controllable load in series with a power source;retrieving the stored waveform;sensing a current through the controllable load and the AFCI;providing a first signal indicative of the sensed current to a first input terminal of a first circuit, the first circuit (i) including the first input terminal and a second input terminal and (ii) being configured to generate difference signals responsive to differences between voltages at the first input terminal and voltages at the second input terminal;providing a second signal indicative of the stored waveform to the second input terminal of the first circuit;generating, by the first circuit, a difference signal responsive to a difference between a voltage of the first signal and a voltage of the second signal; andproviding the difference signal to an input of the controllable load to adjust a resistance in the controllable load such that the current through the controllable load and the AFCI replicates the stored waveform at the AFCI. 2. The method of claim 1, wherein storing the waveform comprises: storing a plurality of waveforms representative of a corresponding plurality of arc faults. 3. The method of claim 2, further comprising: storing an output waveform of one of a voltage or current measured at the AFCI. 4. The method of claim 1, further comprising: determining whether the AFCI correctly responds to the current drawn through the controllable load. 5. A tester for an arc fault circuit interrupter (AFCI) comprising: a power source with a supply connection adapted to be coupled to a first AFCI connection of an AFCI and a return connection adapted to be coupled to a second AFCI connection of an AFCI;a controllable load with an input, an output and a control connection, the input coupled to the second AFCI connection and the output coupled to the return connection of the power source;a waveform generator that reproduces waveforms indicative of an arc fault;a current sensor that senses current through the AFCI and the controllable load; anda control stage coupled to the waveform generator and to the control connection of the controllable load, wherein the control stage includes a first circuit that is coupled to the current sensor and outputs signals indicative of the current through the AFCI,a second circuit that is coupled to the waveform generator and outputs signals indicative of the waveforms reproduced by the waveform generator, anda third circuit that is coupled to the first circuit and the second circuit, and outputs difference signals responsive to differences between voltages of the signals output by the first circuit and voltages of the signals output by the second circuit,wherein the control stage is configured to provide the difference signals to the control connection of the controllable load to adjust a resistance in the controllable load, such that the current through the controllable load and the AFCI replicates the waveforms at the AFCI. 6. The tester of claim 5, further comprising: a voltage sensor to verify a phase angle between current and voltage at the AFCI. 7. The tester of claim 6, further comprising: a zero crossing detector to capture a zero crossing and polarity of a voltage of the power source. 8. The tester of claim 5, wherein the control stage comprises: an optical isolation stage that allows separation of an electrical ground of the power source from an electrical ground of the waveform generator. 9. The tester of claim 5, wherein the controllable load comprises: a high power resistor in series with at least one power field effect transistor (FET). 10. The tester of claim 9, wherein the at least one power FET comprises an array of N-channel power FETs. 11. The tester of claim 10, wherein the at least one power FET has a current rating of 100 amperes. 12. The tester of claim 5, wherein the control stage has an analog bandwidth of about 0.7 Hz to about 200 MHz. 13. The tester of claim 5, further comprising: a waveform library storing a plurality of waveforms indicative of a plurality of corresponding arc faults, and wherein the waveform generator reproduces waveforms indicative of the stored waveforms. 14. The tester of claim 13, wherein each stored waveform is stored as a streaming waveform file. 15. A method of testing an arc fault circuit interrupter (AFCI) comprising: providing a waveform library with a plurality of stored waveforms, each of the plurality of stored waveforms representing a test condition for the AFCI;providing a waveform generator in communication with the waveform library for generating one of the plurality of stored waveforms for performance testing of the AFCI;providing a control stage coupled to the waveform generator, the control stage for outputting a control signal;providing a controllable load that varies its resistance responsive to the control signal;coupling an AFCI to the controllable load and a power source;accepting the one of the plurality of stored waveforms at the control stage;sensing a current through the controllable load and the AFCI;creating the control signal at the control stage, the control signal corresponding to the one of the plurality of stored waveforms, wherein creating the control signal includes amplifying the one of the plurality of stored waveforms to provide a waveform signal,amplifying a signal indicative of the sensed current to provide a current sense signal, andcreating the control signal such that the control signal responsive to a difference between a voltage of the waveform signal and a voltage of the current sense signal;providing the control signal to an input of the controllable load to adjust a resistance in the controllable load proportionally to the control signal such that the current through the controllable load and the AFCI replicates the stored waveforms; anddetermining how the AFCI responds to a current through the controllable load and the AFCI as the resistance is adjusted. 16. The method of claim 15, further comprising: passing the control signal through an optical isolation stage that separates a ground of the control stage and a ground of the controllable load. 17. The method of claim 15, wherein providing the controllable load comprises: providing a controllable load with a current rating of at least 100 amperes and a response time for changing between two current levels of at most 1 microsecond. 18. The method of claim 15, further comprising: determining that the AFCI interrupts current having an arc profile and passes current having a nuisance load profile. 19. A tester for an arc fault circuit interrupter (AFCI) comprising: a power source with a supply connection adapted to be coupled to a first AFCI connection of an AFCI and a return connection adapted to be coupled to a second AFCI connection of the AFCI;a controllable load with an input, an output and a control connection, the input adapted to be coupled to the second AFCI connection and the output coupled to the return connection of the power source;a waveform library storing a plurality of streaming waveforms for reproduction;a waveform generator that reproduces waveforms indicative of an arc fault, wherein the waveform generator reproduces waveforms indicative of the streaming waveforms;a current sensor that senses current through the AFCI and the controllable load; anda control stage coupled to the current sensor, the waveform generator and the control connection of the controllable load, the control stage being configured to amplify the reproduced waveforms to provide waveform signals,amplify current sense signals from the current sensor to provide current sense signals, andprovide, at the control connection, control signals indicative of differences between voltages of the amplified waveform signals and voltages of the current sense signals to adjust a resistance in the controllable load such that the current through the AFCI and the controllable load replicates the reproduced waveforms.
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