초록 ▼

A system and method for an arc fault detection system for aircraft wiring system is disclosed. Upon detection of arc fault events, the system transmits a signal that may be sent to an existing circuitry of the aircraft electrical system, which disconnects the power to the circuits, thereby extinguis

A system and method for an arc fault detection system for aircraft wiring system is disclosed. Upon detection of arc fault events, the system transmits a signal that may be sent to an existing circuitry of the aircraft electrical system, which disconnects the power to the circuits, thereby extinguishing the arc. The system can be either utilized as a stand-alone system or incorporated into existing products or systems. When an arc event occurs on a power cable, a broadband noise event is similarly induced upon the affected cable. The system first uses a pick-up coil (15) to sense and pick up this broadband signal from the power cable (5) of the wiring system, and then amplifies (17) the signal. The amplified signal is applied to a high-pass filter (20) to only pass frequency components above a predetermined frequency. The high-passed frequency components are then applied to band-pass filters (32-35), using a plurality of non-harmonically related center frequencies to generate narrow frequency slices of the signal. Each slice of the signal is rectified (42-45) to generate a d.c. level signal. Detection can be made for each d.c. level signal using level detectors (52-55). Power and ground sources are also applied to their narrow band-pass filters (31, 36) , rectifiers (41, 46) and level detectors (51, 56). By using a logic matrix (60), an arc fault can be determined when all d.c. level signals from the event indicate detection, while signals from the power and ground sources indicate no system noise.

대표청구항 ▼

We claim: 1. An arc fault detection system to detect an arc event in aircraft wiring, comprising: a pick-up sensor coupled to said wiring, being adapted to detect an event on said wiring; a differential amplifier coupled to said pick-up sensor, being adapted to amplify an output from said pick-up s

We claim: 1. An arc fault detection system to detect an arc event in aircraft wiring, comprising: a pick-up sensor coupled to said wiring, being adapted to detect an event on said wiring; a differential amplifier coupled to said pick-up sensor, being adapted to amplify an output from said pick-up sensor; a high pass filter coupled to said differential amplifier, being adapted to pass output from said differential amplifier above a predetermined frequency; a plurality of first multi-pole band pass filters coupled to said high pass filter, each of said first multi-pole band pass filters being adapted to pass output from said high pass filter within a predetermined frequency band, each frequency band being non-harmonically related to each other of said first band pass filters; a plurality of first rectifier coupled to said plurality of first multi-pole band pass filters, each of said first rectifiers being adapted to generate a d.c. output based on an arc spectrum from a corresponding one of said first multi-pole band pass filters; a plurality of first level detectors coupled to said plurality of first rectifiers, each of said first level detectors being adapted to generate a logic level output based on an output from a corresponding one of said first rectifiers; a plurality of second multi-pole band pass filters coupled to power and ground terminals, each of said second multi-pole band pass filters being adapted to pass output from said power and ground terminals within a predetermined frequency band; a plurality of second rectifiers coupled to said plurality of second multi-pole band pass filters, each of said second rectifiers being adapted to generate a d.c. output based on an arc spectrum from a corresponding one of said second multi-pole band pass filters; a plurality of second level detectors coupled to said plurality of second rectifiers, each of said second level detectors being adapted to generate a logic level output based on an output from a corresponding one of said second rectifiers; and a decision logic unit coupled to outputs of said plurality of first and second level detectors, being adapted to generate a detection signal only when said first level detectors indicate a valid detection, while said second level detectors indicate no detection. 2. The detection system of claim 1, further comprising: a detection output unit coupled to said decision logic unit, being adapted to generate a control signal based on said detection signal, said control signal being adapted to cause power in the aircraft wiring to shut off. 3. The detection system of claim 2, further comprising: an automatic gain control ("AGC") system coupled to said differential amplifier to prevent saturation; a capacitor coupled to an output of each of said first and second rectifiers. 4. The detection system of claim 2, wherein said high band pass filter is adapted to filter out signal frequency below 800 Hz. 5. The detection system of claim 2, wherein: said pick up sensor is one of a magnetic sensor and a current sensor, coupled to said wiring, being adapted to pick up events within a frequency between 2 KHz and 15 KHz. 6. The detection system of claim 1, wherein said plurality of first multi-pole band pass filters comprises an 8-pole band pass filter, having non-harmonically related center frequency. 7. The detection system of claim 2, wherein said plurality of first multi-pole band pass filters comprises an 8-pole band pass filter, having non-harmonically related center frequency. 8. The detection system of claim 6, wherein said first 8-pole band pass filters have center frequencies at 2, 3, 5, 7 KHz, respectfully. 9. The detection system of claim 1, wherein said first and second rectifiers are adjustable. 10. The detection system of claim 1, wherein said first and second level detectors are adjustable. 11. An arc fault detection system to detect an arc event in aircraft wiring, comprising: a pick-up sensor coupled to said wiring, being adapted to detect an event on said wiring; a differential amplifier coupled to said pick-up sensor, being adapted to amplify an output from said pick-up sensor; an analog-to-digital converter ("ADC") coupled to said differential amplifier, being adapted to convert an analog output from said differential amplifier to a digital signal; a digital signal processor ("DSP") coupled to said ADC, being programmed to perform: high pass filtering by passing output from said differential amplifier above a predetermined frequency; first multi-pole band pass filtering of a plurality of center frequencies by passing output after said high pass filtering within a predetermined frequency band, each frequency band being non-harmonically related to each other in said first filtering; second multi-pole band pass filtering of a plurality of center frequency by passing output from said power and ground terminals within a predetermined frequency band; an integrated circuit coupled to said DSP, being adapted to perform: first rectifying of a plurality of output after said first multi-pole band pass filtering by generating a d.c. output based on a corresponding arc spectrum from said first multi-pole band pass filtering; first level detecting of each output after said first rectifying by generating a logic level output based on a corresponding output from said first rectifying; second rectifying of a plurality of output after said second multi-pole band pass filtering by generating a d.c. output based on a corresponding arc spectrum from said second multi-pole band pass filtering; second level detecting of each output after said second rectifying by generating a logic level output based on a corresponding output from said second rectifying; and generating a detection signal only when said first level-detecting indicates a valid detection, while said second level-detecting indicates no detection. 12. An arc fault detection system of claim 11, wherein said integrated circuit is further adapted to output a control signal based on said detection signal, said control signal being adapted to cause power in the aircraft wiring to shut off. 13. An arc fault detection system of claim 11, wherein each of said plurality of first multi-pole band pass filtering comprises using an 8-pole band pass filter, having non-harmonically related center frequency. 14. An arc fault detection system of claim 12, wherein each of said plurality of first multi-pole band pass filtering comprises using an 8-pole band pass filter, having non-harmonically related center frequency. 15. A method of detecting an arc fault event in aircraft electrical wiring, comprising the steps of: a) sensing a signal in said wiring; b) differentially amplifying the signal picked up from said wiring; c) high-pass filtering an output from said step of differentially amplifying above a predetermined frequency; d) band-pass filtering the signal from said step of high-pass filtering, with a plurality of non-harmonically related center frequencies to generate a plurality of narrow frequency slices that represent a wiring frequency spectrum, and band-pass filtering a power terminal signal and ground signal with non-harmonically related center frequencies to generate narrow frequency slices that represent frequency spectrum for the power terminal and ground signals; e) rectifying each of said frequency slices to generate a d.c. level signal for each frequency slice; f) detecting a logic level for each of said d.c. level signal; and g) determining that an arc fault is present when all logic levels for the wiring frequency spectrum indicate detection and when logic levels for the power terminal and ground signal frequency spectrum indicate no detection. 16. The method of claim 15, further comprising: outputting a detection control signal if arc fault is determined. 17. The method of claim 15, wherein said non-harmonically center frequencies are 2, 3, 5, 7 KHz. 18. The method of claim 16, wherein said non-harmonically center frequencies are 2, 3, 5, 7 KHz. 19. The method of claim 15, wherein said step of band-pass filtering comprises using 8-pole band pass filters. 20. The method of claim 16, wherein said step of band-pass filtering comprises using 8-pole band pass filters.