초록 ▼

A flame detection apparatus is provided that provides low cost fire detection with improved false alarm discrimination and that includes at least two optical sensors, each configured with a Long Wave Pass IR filter with distinct minimum responsive wavelengths and arrayed to broadly sample the MWIR b

A flame detection apparatus is provided that provides low cost fire detection with improved false alarm discrimination and that includes at least two optical sensors, each configured with a Long Wave Pass IR filter with distinct minimum responsive wavelengths and arrayed to broadly sample the MWIR band.

대표청구항 ▼

1. A flame detection apparatus comprising: a first optical sensor comprising a first long wave pass filter, having a first spectral response; a second optical sensor comprising a second long wave pass filter having a second spectral response; and a third optical sensor comprising a third long wave p

1. A flame detection apparatus comprising: a first optical sensor comprising a first long wave pass filter, having a first spectral response; a second optical sensor comprising a second long wave pass filter having a second spectral response; and a third optical sensor comprising a third long wave pass filter having a third spectral response; and wherein said third spectral response is a subset of said second response, and said second response is a subset of said first spectral response. 2. The apparatus of claim 1, further comprising a protective covering. 3. The apparatus of claim 1, wherein said first, second and third spectral responses are specified at respective first, second and third minimum wavelengths above which each said filter responds at least at fifty percent transmittance, and wherein said first minimum wavelength is between about 2.3 μm and about 2.8 μm, said second minimum wavelength is between about 3.2 μm and about 3.8 μm, and said third minimum wavelength is within about 1% of 4.17 μm. 4. The apparatus of claim 1, wherein said first, second and third spectral responses are specified at respective first, second and third minimum wavelengths above which each said filter responds at least at fifty percent transmittance, and wherein said first minimum wavelength is about 3.93 μm, said second minimum wavelength is about 4.17 μm, and said third minimum wavelength is about 4.96 μm. 5. The apparatus of claim 1, wherein said first, second and third spectral responses are specified at respective first, second and third minimum wavelengths above which each said filter responds at least at fifty percent transmittance, and wherein said first minimum wavelength is no more than 25% less than a pre-defined peak wavelength, said second minimum wavelength is within 10% of said peak wavelength, and said third minimum wavelength is no more than 25% greater than said peak wavelength. 6. The apparatus of claim 5, further comprising a protective covering, said protective covering having a spectral transmittance such that only energies of wavelengths below a cutoff wavelength are passed therethrough. 7. The apparatus of claim 6, wherein said cutoff wavelength is no more than 25% greater than said third minimum wavelength. 8. The apparatus of claim 1, further comprising a computer-based processor for analyzing a first, second, and third signal received from said first, second and third sensor, and issuing a command signal, and an output responsive to said command signal. 9. The apparatus of claim 8, wherein said computer-based processor includes a computer-readable medium configured with control logic to command said processor to execute a detection method, said method comprising the steps of: comparing a first ratio to a first threshold, said first ratio being a ratio of said second signal to said first signal; and comparing a second ratio to a second threshold, said second ratio being a ratio of said third signal to said second signal. 10. The apparatus of claim 9, wherein said first, second and third spectral responses are specified at respective first, second and third minimum wavelengths above which each said filter responds at least at fifty percent transmittance, and wherein said first minimum wavelength is no more than 25% less than a pre-defined peak wavelength, said second minimum wavelength is within 10% of said peak wavelength, and said third minimum wavelength is no more than 25% greater than said peak wavelength. 11. The apparatus of claim 10, wherein said method further comprises the steps of: comparing a third ratio to a third threshold, said third ratio being a ratio of said first signal to said first spectral response; comparing a fourth ratio to a fourth threshold, said fourth ratio being a ratio of said second signal to said second spectral response; and comparing a fifth ratio to a fifth threshold, said fifth ratio being a ratio of said third signal to said third spectral response. 12. The apparatus of claim 8, wherein said computer-based processor includes a computer-readable medium configured with control logic to command said processor to execute a detection method, said method comprising the steps of: comparing a first ratio to a first threshold, said first ratio being a ratio of said first signal to said first spectral response; comparing a second ratio to a second threshold, said second ratio being a ratio of said second signal to said second spectral response; and comparing a third ratio to a third threshold, said third ratio being a ratio of said third signal to said third spectral response. 13. The apparatus of claim 12, wherein said first, second and third spectral responses are specified at respective first, second and third minimum wavelengths above which each said filter responds at least at fifty percent transmittance, and wherein said first minimum wavelength is no more than 25% less than a pre-defined peak wavelength, said second minimum wavelength is within 10% of said peak wavelength, and said third minimum wavelength is no more than 25% greater than said peak wavelength. 14. A flame detector comprising: at least three sensors, each of said sensors having a long wave pass filter and a unique spectral response at wavelengths between about 2 μm and 8 μm, wherein one of said sensors has a spectral response above a wavelength of about 4.17 μm, and wherein the spectral response of one sensor is comprised within the spectral responses of the other sensors. 15. The flame detector of claim 14, further comprising a protective covering, said protective covering having a spectral transmittance such that only energies of wavelengths below a cutoff wavelength are passed therethrough.