초록

The present invention relates to built-in testing of detectors for the detection of electrical arc faults or transients, where the detector is integrated into or electrically coupled to an electrical power supply system.

대표청구항 ▼

1. A method of verifying correct functioning of an arc fault/transient detector, the method comprising: providing an electrical power supply system, which includes: a circuit having: a power source for providing electric power to a load;a breaker switch provided in an electrically conductive path be

1. A method of verifying correct functioning of an arc fault/transient detector, the method comprising: providing an electrical power supply system, which includes: a circuit having: a power source for providing electric power to a load;a breaker switch provided in an electrically conductive path between the power source and the load, the breaker switch having an open position, a closed position, and an output; anda test switch provided between the output of the breaker switch and a ground to form a short circuit loop in the circuit, the test switch having an open position for breaking electrical continuity of the short circuit loop to the ground and a closed position for providing electrical continuity of the short circuit loop to the ground; andan arc fault/transient detector operable to monitor for a rate of change in one or both of a current or a voltage in the circuit, the detector co-operable with the breaker switch to trip the breaker switch from the closed position to the open position if the sensed rate of change exceeds a predetermined value;selectively switching the test and breaker switches so as to: (a) provide electrical continuity of the short circuit loop to the ground thereby establishing a short circuit between the output of the breaker switch and the ground, and thereafter either or both of:(b) inject a flow of current from the power source into the short circuit; and/or(c) terminate an injected flow of current from the power source into the short circuit;monitoring, using the arc fault/transient detector, a rate of change of either or both of a transient current or a transient voltage in the short circuit loop induced by the injecting/terminating of the flow of current from the power source into the short circuit; anddetermining a functional status of the detector based upon the monitoring, wherein faulty functioning of the detector corresponds to the following condition being met: the detector failing to detect the induced rate of change during the monitoring. 2. The method of claim 1, wherein the method further comprises providing a user of the electrical power supply system with a report of a functional health of the detector based upon the functional status determined through the monitoring. 3. The method of claim 2, wherein the electrical power supply system is provided on an aircraft and the user is one or more of: a pilot or other member of an aircrew of the aircraft; and maintenance staff. 4. The method of claim 1, wherein the selective switching of the test and breaker switches comprises the successive steps of: (i) providing the breaker switch in its open position and the test switch in its closed position to thereby respectively (A) break electrical continuity of the electrically conductive path and (B) provide electrical continuity of the short circuit loop to the ground and establish the short circuit;(ii) thereafter switching the breaker switch to its closed position to provide electrical continuity of the electrically conductive path and inject a flow of current from the power source into the short circuit. 5. The method of claim 4, wherein the monitoring comprises monitoring for a rate of change of either or both of a transient current or a transient voltage in the short circuit loop induced by step (ii); wherein faulty functioning of the detector corresponds to the detector failing to detect the rate of change induced by step (ii). 6. The method of claim 4, wherein the selective switching of the test and breaker switches further comprises a first predetermined time interval between commencing step (i) and commencing step (ii), wherein the monitoring covers at least the duration of the first predetermined interval, wherein faulty functioning of the detector corresponds to the detector detecting the presence of a rate of change of current or voltage in the short circuit loop during the first predetermined time interval. 7. The method of claim 4, wherein the selective switching of the test and breaker switches further comprises, following step (ii): (iii) switching the breaker switch to its open position to break electrical continuity of the electrically conductive path and terminate the injection of flow of current from the power source into the short circuit. 8. The method of claim 7, wherein the monitoring comprises monitoring for a rate of change of either or both of a transient current or a transient voltage in the short circuit loop induced by step (iii), wherein faulty functioning of the detector corresponds to the detector failing to detect the rate of change induced by step (iii). 9. The method of claim 7, wherein the monitoring comprises monitoring for a rate of change of either or both of a transient current or a transient voltage in the short circuit loop after elapsing of a second predetermined time interval commencing from switching the breaker switch to its open position in step (iii) and with the test switch remaining in its closed position, the second predetermined time interval having a duration corresponding to a duration for the decay of the rate of change induced by step (iii), wherein faulty functioning of the detector corresponds to the detector detecting the presence of a rate of change of current or voltage in the short circuit loop after elapsing of the second predetermined time interval whilst the test switch remains in its closed position. 10. The method of claim 1, wherein the detector is integrated into the circuit. 11. The method of claim 1, wherein the detector is a solid state power controller and comprises the breaker switch, the test switch and the detector, wherein the solid state power controller has a current limit. 12. The method of any of the preceding claims, wherein the power source comprises one or both of a direct current (DC) power source and an alternating current (AC) power source. 13. An electrical power supply system comprising: a circuit including: a power source for providing electric power to a load;a breaker switch provided in an electrically conductive path between the power source and the load, the breaker switch having an open position, a closed position, and an output; anda test switch provided between the output of the breaker switch and a ground to form a short circuit loop in the circuit, the test switch having an open position for breaking electrical continuity of the short circuit loop to the ground and a closed position for providing electrical continuity of the short circuit loop to the ground;an arc fault/transient detector operable to monitor for a rate of change in one or both of a current or a voltage in the circuit, the detector co-operable with the breaker switch to trip the breaker switch from the closed position to the open position if the sensed rate of change exceeds a predetermined value;wherein the test and breaker switches are selectively switchable for: (a) providing electrical continuity of the short circuit loop to the ground to thereby establish a short circuit between the output of the breaker switch and the ground, and thereafter either or both of:(b) injecting a flow of current from the power source into the short circuit; and/or(c) terminating an injected flow of current from the power source into the short circuit;wherein the detector is operable to monitor a rate of change of either or both of a transient current or a transient voltage in the short circuit loop induced by the injecting/terminating of the flow of current from the power supply into the short circuit;wherein the system is operable to determine a functional status of the detector based upon the monitoring, wherein faulty functioning of the detector corresponds to the detector failing to detect the induced rate of change during monitoring. 14. The system of claim 13, wherein the system comprises an output device coupled to or integrated with the detector and operable to provide a user of the electrical power supply system with a report of a functional health of the detector based upon the functional status determined through the monitoring. 15. The system of claim 14, wherein the output device comprises one or both of a display screen and a speaker. 16. The system of claim 13, wherein the detector is integrated into the circuit. 17. The system of claim 13, wherein the detector is a solid state power controller and comprises the breaker switch, the test switch and the detector, wherein the solid state power controller has a current limit. 18. The system of claim 13, wherein the power source comprises one or both of a direct current (DC) power source and an alternating current (AC) power source.