초록 ▼

Leaks in natural gas pipelines are detected by an airborne gas cell correlation radiometer having two channels, one to detect methane and the other to detect nitrous oxide. The channel outputs are compared in order to detect anomalies in their relative magnitude, an increase in methane concentration

Leaks in natural gas pipelines are detected by an airborne gas cell correlation radiometer having two channels, one to detect methane and the other to detect nitrous oxide. The channel outputs are compared in order to detect anomalies in their relative magnitude, an increase in methane concentration relative to nitrous oxide concentration being indicative of a gas leakage in the area from which the radiometer receives radiation.

대표청구항 ▼

1. A method of detecting leaks in a gas pipeline; comprising conveying an airborne radiometer along the route of the pipeline, focusing radiation from the vicinity of the pipeline upon the radiometer, sensing components of the radiation characteristic of two different gases, both of which are diffus

1. A method of detecting leaks in a gas pipeline; comprising conveying an airborne radiometer along the route of the pipeline, focusing radiation from the vicinity of the pipeline upon the radiometer, sensing components of the radiation characteristic of two different gases, both of which are diffused through the atmosphere in low concentrations, but only one of which is present in the pipeline, determining the ratio of these components, and detecting and recording changes in said ratio as an indication of the presence of leaks. 2. A method according to claim 1, further comprising simultaneously focusing radiation, from the same vicinity as the radiation focused upon the radiometer, to form images upon the pickup device at a television camera, and recording signals representing said images upon the same medium as said changes in ratio, whereby to facilitate subsequent location of leaks indicated by such changes. 3. A method according to claim 1, wherein the gases detected are CH 4 and N 2 O. 4. Apparatus for detecting leaks in a gas pipeline, comprising a multiple channel radiometer mountable in or on an aircraft, means for focusing radiation on the radiometer from a defined direction beneath the aircraft, means for comparing two outputs of the channels of the radiometer to provide signals representative of changes in the ratio of said outputs, and means to record said signals, one of said two channels being sensitive to radiation components characteristic of a first gas diffused at a low concentration through the atmosphere and also present in the pipeline, and the second channel being sensitive to radiation components characteristic of a second gas diffused at a low concentration through the atmosphere but not present in the pipeline. 5. Apparatus according to claim 4, further comprising means for focusing radiation from said direction to form images upon the pickup device of a television camera whereby to generate an image signal output and means to record said image signal output on the same medium as said signals representative of the ratio of the radiometer channel outputs. 6. Apparatus according to claim 4, wherein the radiometer is a correlation gas filter cell radiometer having channels for the detection of at least two different gases. 7. Apparatus according to claim 6, wherein the correlation gas filter cell radiometer has two channels, one for detection of absorption at a wavelength characteristic of CH 4 and the other for the detection of absorption at a wavelength characteristic of N 2 O. 8. Apparatus according to claim 6, wherein the radiometer defines two independent optical paths for the radiance focused upon the radiometer, the two paths intersecting a chopper wheel at different radial distances from its rotational axis, and the chopper wheel comprising a ring of gas cells disposed in successive sectors of the wheel, which successively intersect the optical paths as the wheel rotates, together with a mask such that each optical path intersects only selected cells and is cut off by the mask from intersecting the other cells, the cells comprising cells containing respectively a first gas to be detected by a first channel, a second gas to be detected by a second channel, and an optically neutral gas, and the mask being disposed so one optical path intersects only the cells containing the first gas and the neutral gas, and the second optical path intersects only the cells containing the second gas and the neutral gas. 9. Apparatus according to claim 8, wherein there is a plurality of cells of each type. 10. Apparatus according to claim 8, wherein the first gas is CH 4 and the second gas is N 2 O. 11. Apparatus according to claim 8, wherein the optical paths extend from an input lens and through the chopper wheel on parallel and nominally upwardly extending axes, and then in opposite directions on a common horizontal axis to independent detectors, one for radiance at a wavelength at which the first gas has an absorption maximum, and the other for radiance at a wavelength at which the second gas exhibits an absorption maximum. 12. Apparatus according to claim 11, wherein the radiometer is enclosed within a housing having stationary journals mounting it for pivotal motion about said horizontal axis, whereby to direct said lenses in a desired direction, the detectors being supported on said journals whereby to maintain their orientation during pivotal movement of the housing. 13. Apparatus according to claim 12, wherein the detectors are cryogenically cooled. 14. Apparatus according to claim 12, wherein the housing also contains a television camera, lenses of the television camera and the optical paths of the radiometer being directed in the same direction. 15. In a correlation gas filter cell radiometer in which the radiometer defines two independent optical paths for the radiance focused upon the radiometer, the two paths intersecting a chopper wheel a different radial distances from its rotational axis, and the chopper wheel comprising a ring of gas cells disposed in successive sectors of the wheel, which successively intersect the optical paths as the wheel rotates, together with a mask such that each optical path intersects only selected cells and is cut off by the mask from intersecting the other cells, the cells comprising cells containing respectively a first gas to be detected by a first channel, a second gas to be detected by a second channel, and an optically neutral gas, and the mask being disposed so one optical path intersects only the cells containing the first gas and the neutral gas, and the second optical path intersects only the cells containing the second gas and the neutral gas, the improvement wherein the optical paths extend from an input lens and through the chopper wheel on parallel and nominally upwardly extending axes, and then in opposite directions on a common horizontal axis to independent detectors, one for radiance at a wavelength at which the first gas has an absorption maximum, and the other for radiance at a wavelength at which the second gas exhibits an absorption maximum. 16. A radiometer according to claim 14, wherein the radiometer is enclosed within a housing having stationary journals mounting it for pivotal motion about said horizontal axis, whereby to direct said lenses in a desired direction, the detectors being supported on said journals whereby to maintain their orientation during pivotal movement of the housing. 17. A radiometer according to claim 14, wherein the first gas is CH 4 and the second gas is N 2 O. 18. A radiometer according to claim 14, wherein there is a plurality of cells of each type.