A method and apparatus for determining the safety of a gas mixture containing flammable components such as methane together with ethane or other hydrocarbon, together with a diluent gas. The method includes the filtered infrared spectroscopy of the gas mixture in a gas cell using a filter. The peak
A method and apparatus for determining the safety of a gas mixture containing flammable components such as methane together with ethane or other hydrocarbon, together with a diluent gas. The method includes the filtered infrared spectroscopy of the gas mixture in a gas cell using a filter. The peak transmission wavelength and bandwidth of the filter are so chosen to provide an output, when an infrared light source having a flat wavelength distribution is used, indicative of the % LEL of the gas mixture, within a predetermined tolerance. The filter may be a gas correlation filter containing a mixture of methane and ethane, together with a diluent gas.
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The invention claimed is: 1. A method for determining the safety of a gas mixture including first and second flammable components together with a diluent gas, comprising: performing infrared spectroscopy of the gas mixture using a filter having a peak transmission wavelength and a bandwidth to prov
The invention claimed is: 1. A method for determining the safety of a gas mixture including first and second flammable components together with a diluent gas, comprising: performing infrared spectroscopy of the gas mixture using a filter having a peak transmission wavelength and a bandwidth to provide an output indicative of a percentage of the lower explosion limit (LEL) of the gas mixture within a predetermined tolerance of the output; and selecting a filter in which the peak transmission wavelength and the band width of the filter, when viewed through said filter, are such that a first intensity of transmission through a gas mixture containing 50% of a LEL of said first flammable component is equal to a second intensity of transmission through a gas mixture containing 50% of a LEL of said second flammable component, within a 30% intensity tolerance. 2. The method according to claim 1, wherein said determining comprises: selecting a filter such that a first rate of change of the first intensity of transmission ∂I1/∂λ through a gas mixture containing 50% of the LEL of said first flammable component is equal to a second rate of change of the second intensity of transmission ∂I2/∂λ through a gas mixture containing 50% of the LEL of said second flammable component, within a tolerance of 100 I/μm. 3. The method according to claim 1, wherein said determining comprises: selecting a filter such that the first intensity for the first flammable component is selected for methane. 4. The method according to claim 3, wherein said determining comprises: selecting a filter such that the second intensity for the second flammable component is selected for at least one of ethane, propane and or mixtures thereof. 5. The method according to any one of claims 1-4, further comprising: producing a signal indicative of the % LEL for the mixture, within 짹3% of the output. 6. An apparatus for determining the safety of a gas mixture including first and second flammable components together with a diluent gas, the apparatus comprising: a gas region configured to receive a gas to be examined; an infrared light source positioned to direct infrared light through said region; a sensor configured to measure the intensity of light passed through said region; and a filter positioned in a light path between said source and said sensor, wherein said filter has a peak transmission wavelength and a bandwidth to provide an output indicative of a percentage of the lower explosion limit (LEL) of the gas mixture, and the peak transmission wavelength and the band width of the filter are such that, when viewed through said filter, a first intensity of transmission through a gas mixture containing 50% of a LEL of said first flammable component is equal to a second intensity of transmission through a gas mixture containing 50% of a LEL of said second flammable component, within a 30% intensity tolerance. 7. The apparatus according to claim 6, wherein the gas region comprises: a gas cell configured to contain a sample of the gas to be examined. 8. The apparatus according to claim 6, wherein the gas region comprises: an open optical path through which the gas to be examined can flow. 9. The apparatus according to claim 6, wherein the filter comprises: a gas correlation filter including a known mixture of said first and second flammable components together with the diluent gas to provide said sensor with an output indicative of the percentage of LEL of the gas mixture, within a predetermined tolerance of the output. 10. The apparatus according to claim 6, wherein, at the peak transmission wavelength of the filter, a first rate of change of intensity with increasing wavelength ∂I1/∂λ for the gas mixture containing 50% of the LEL of said first component is equal to a second rate of change of intensity with increasing wavelength ∂I2/∂λ for the gas mixture containing 50% of the LEL of said second component, within a tolerance of 100 I/μm. 11. A filter for use in the infrared spectroscopy of a gas mixture including methane as a first component and a second component selected from one of ethane, propane or mixtures thereof, together with a diluent gas, comprising: said filter having a peak transmission wavelength and a bandwidth such that an output is provided, when an infrared light source having a flat wavelength distribution is used, indicative of a percentage of the lower explosion limit (LEL) of the gas mixture, within a predetermined tolerance of the outputs, wherein the peak transmission wavelength and the band width of the filter are such that, when viewed through said filter, a first intensity of transmission through a gas mixture containing 50% of a LEL of said first component is equal to a second intensity of transmission through a gas mixture containing 50% of a LEL of said second component, within a 30% intensity tolerance. 12. The filter according to claim 11, wherein said filter has a peak transmission wavelength λmax from 3.265 to 3.269 μm. 13. The filter according to claim 12, wherein said filter has a band width, expressed in terms of a full width at half maximum, of less than 0.9% λmax. 14. The filter according to claim 11, wherein said filter has a peak transmission wavelength λmax from 3.31 to 3.32 μ m. 15. The filter according to claim 14, wherein said filter has a band width, expressed in terms of a full width at half maximum, of less than 0.7% λmax. 16. The filter according to claim 11, wherein said filter has a peak transmission wavelength λmax from 1.673 to 1.675 μm. 17. The filter according to claim 16, wherein said filter has a band width, expressed in terms of a full width at half maximum, of between 0.5% and 6% λmax. 18. A combination of an infrared light source and a filter for use in the infrared spectroscopy of a gas mixture including methane as a first component and a second component selected from ethane, propane, or mixtures thereof together with a diluent gas, comprising: said filter having a peak transmission wavelength and a bandwidth such that an output is provided when said light source is used indicative of a percentage of the lower explosion limit (LEL) of the gas mixture, within a predetermined tolerance, wherein the peak transmission wavelength and the band width of the filter, when viewed through said filter, are such that a first intensity of transmission through a gas mixture containing 50% of a LEL of said first flammable component is equal to a second intensity of transmission through a gas mixture containing 50% of a LEL of said second flammable component, within a 30% intensity tolerance. 19. A gas correlation filter for use in the infrared spectroscopy of natural gas, said filter comprising: a mixture of methane and a second flammable component selected from ethane, propane or a mixture thereof, together with a diluent gas, in quantities that give equal signals from a mixture of methane/air at 50% of the lower explosion limit (LEL) and from a mixture of the second flammable component and air at 50% of the LEL, within a tolerance of 10% of the signal.
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