Method and apparatus for storage tank leak detection
원문보기
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
G01M-003/02
G01M-003/26
출원번호
US-0614748
(2003-07-07)
발명자
/ 주소
Wolford, Jimmy
Wolford, Bernie
Lockerd, Clark
Slaughter, Ricky
인용정보
피인용 횟수 :
5인용 특허 :
2
초록▼
An intrinsically safe, precise, and cost effective storage tank leak detection system. Embodiments include a highly precise quartz crystal type pressure transducer, secured in a vacuum and held at a constant temperature. Said transducer is used in combination with data correction and regression tech
An intrinsically safe, precise, and cost effective storage tank leak detection system. Embodiments include a highly precise quartz crystal type pressure transducer, secured in a vacuum and held at a constant temperature. Said transducer is used in combination with data correction and regression techniques to yield a storage tank leak detection system with an extremely low leak detection threshold. The storage tank leak detection system is thought to be most useful for detecting very small leaks in very large storage tanks, most likely above ground storage tanks.
대표청구항▼
1. An apparatus for detecting leaks in a liquid storage tank comprising:differential pressure sensor means having a low pressure measurement component and a high pressure measurement component; protective enclosure means for protecting said differential pressure sensor means from materials and condi
1. An apparatus for detecting leaks in a liquid storage tank comprising:differential pressure sensor means having a low pressure measurement component and a high pressure measurement component; protective enclosure means for protecting said differential pressure sensor means from materials and conditions when immersed in liquid contents of said storage tank; said high pressure measurement component being configured for measuring tank bottom pressure within a liquid in which said protective enclosure means is immersed; said low pressure measurement component being configured for receiving data indicative of atmospheric pressure substantially at the surface of said liquid; barometric pressure measuring means configured for measuring atmospheric pressure substantially at the surface of said liquid when said protective enclosure means is immersed therein; barometric pressure and differential pressure calculation means configured for receiving first and second data reflecting, respectively, said tank bottom pressure and of said barometric pressure substantially at said surface of said liquid, and for adjusting said first data to substantially eliminate variations upon said measurements of said tank bottom pressure caused solely from atmospheric pressure variations to yield an atmospheric pressure adjusted tank bottom pressure; ambient temperature measurement means for measuring ambient temperature near said storage tank; tank dynamic and barometric pressure adjusted tank bottom pressure calculation means configured for receiving third data indicative of said atmospheric pressure adjusted tank bottom pressure, for receiving fourth data indicative of ambient temperature measurements by said ambient temperature measurement means, for receiving fifth data indicative of expansion characteristics of said storage tank, and for adjusting said third data with reference to said fourth and fifth data to substantially eliminate variations upon measurements and calculations of said barometric pressure adjusted tank bottom pressure, caused solely by dimensional changes in said storage tank resulting from atmospheric temperature variations, to yield a tank dynamic adjusted tank bottom pressure; and tank content mass calculation means for calculating mass contents of said storage tank substantially based on said tank dynamic adjusted tank bottom pressure and user input data reflecting physical characteristics of said contents of said storage tank. 2. The apparatus of claim 1 wherein said protective enclosure means is configured for maintaining at least some components of said apparatus, including said differential pressure sensor, but excepting said low pressure measurement component and said high pressure measurement component, in a substantial vacuum.3. The apparatus of claim 2 further comprising protective enclosure temperature management means configured for maintaining the temperature of said protective enclosure substantially at a user-specified temperature.4. The apparatus of claim 1 further comprising protective enclosure temperature management means configured for maintaining the temperature of said protective enclosure substantially at a user-specified temperature.5. An, apparatus for detecting leaks in a liquid storage tank comprising:differential pressure sensor means having a low pressure measurement component and a high pressure measurement component; protective enclosure means for protecting said differential pressure sensor means from materials and conditions when immersed in liquid contents of said storage tank; said high pressure measurement component being configured for measuring tank bottom pressure within a liquid in which said differential pressure sensor means is immersed; said low pressure measurement component being configured for receiving data indicative of atmospheric pressure substantially at the surface of said liquid; first barometric pressure measuring means configured for measuring atmospheric pressure substantially at the surface of said liquid when said protective enclosure means is immersed therein and for communicating such measurement to said low pressure measurement component of said differential pressure sensor means; second barometric pressure measuring means configured for measuring atmospheric pressure substantially at the surface of said liquid when said protective enclosure means is immersed therein; barometric pressure and differential pressure calculation means configured for receiving first and second data reflecting, respectively, said tank bottom pressure and of said barometric pressure as measured by said first barometric pressure measuring means and for calculating pressure attributable to liquid content of said storage tank, and receiving third data from said second barometric measuring means and, based thereon, adjusting said pressure attributable to said contents of said storage tank to substantially eliminate variations upon said measurements thereof caused solely from atmospheric pressure variations to yield an atmospheric pressure adjusted tank bottom pressure; ambient temperature measurement means for measuring ambient temperature near said storage tank; tank dynamic and barometric pressure adjusted tank bottom pressure calculation means configured for receiving fourth data indicative of said atmospheric pressure adjusted tank bottom pressure, for receiving fifth data indicative of ambient temperature measurements by said ambient temperature measurement means, for receiving sixth data indicative of expansion characteristics of said storage tank, and for adjusting said fourth data with reference to said fifth and sixth data to substantially eliminate variations upon measurements and calculations of said barometric pressure adjusted tank bottom pressure, caused solely by dimensional changes in said storage tank resulting from atmospheric temperature variations, to yield a tank dynamic adjusted tank bottom pressure; and tank content mass calculation means for calculating mass contents of said storage tank substantially based on said tank dynamic adjusted tank bottom pressure and user input data reflecting physical characteristics of said contents of said storage tank. 6. The apparatus of claim 5 wherein said protective enclosure means is configured for maintaining at least some components of said apparatus, including said differential pressure sensor means, but excepting said low pressure measurement component and said high pressure measurement component, in a substantial vacuum.7. The apparatus of claim 6 further comprising protective enclosure temperature management means configured for maintaining the temperature of said protective enclosure substantially at a user-specified temperature.8. The apparatus of claim 5 further comprising protective enclosure temperature management means configured for maintaining the temperature of said protective enclosure substantially at a user-specified temperature.9. A method for detecting leaks in a storage tank; comprising the steps of:selecting a mass detection system comprising: differential pressure sensor means having a low pressure measurement component and a high pressure measurement component; protective enclosure means for protecting said differential pressure sensor means from materials and conditions when immersed in liquid contents of said storage tank; said high pressure measurement component being configured for tank bottom pressure within a liquid in which said differential pressure sensor means is immersed; said low pressure measurement component being configured for receiving data indicative of atmospheric pressure substantially at the surface of said liquid; barometric pressure measuring means configured for measuring atmospheric pressure substantially at the surface of said liquid when said protective enclosure means is immersed therein; barometric pressure and differential pressure calculation means configured for receiving first and second data reflecting, respectively, tank bottom pressure and of said barometric pressure substantially at said surface of said liquid, and for adjusting said first data to substantially eliminate variations upon said measurements of said tank bottom pressure caused solely from atmospheric pressure variations to yield an atmospheric pressure adjusted tank bottom pressure; ambient temperature measurement means for measuring ambient temperature near said storage tank; tank dynamic and barometric pressure adjusted tank bottom pressure calculation means configured for receiving third data indicative of said atmospheric pressure adjusted tank bottom pressure, for receiving fourth data indicative of ambient temperature measurements by said ambient temperature measurement means, for receiving fifth data indicative of expansion characteristics of said storage tank, and for adjusting said third data with reference to said fourth and fifth data to substantially eliminate variations upon measurements and calculations of said barometric pressure adjusted tank bottom pressure, caused solely by dimensional changes in said storage tank resulting from atmospheric temperature variations, to yield a tank dynamic adjusted tank bottom pressure; and tank content mass calculation means for calculating mass content data representative of the contents of said storage tank substantially based on said tank dynamic adjusted tank bottom pressure and user input data reflecting physical characteristics of said contents of said storage tank; selecting data storage means for collecting a plurality of mass content data as generated by said tank content mass calculation means over a plurality of points in time; selecting computing means configured for generating a human perceptible indicating of changes in said mass content data between a plurality of said points in time; placing said protective enclosure means substantially at a bottom interior surface of said storage tank; actuating said mass detection system; and observing data indicative of changes in said mass content data attributable to leakage of said storage tank to detect of such leakage. 10. The method of claim 9 further comprising the steps of:securing all input and outflow orifices of said storage tank before said actuation of said mass detection system; and substantially selectively processing said mass content data which were generated approximately between sunset and sunrise at an installation site of said system. 11. The method of claim 10 wherein said protective enclosure means is configured for maintaining at least some components of said system, including said differential pressure sensor means, but excepting said low pressure measurement component and said high pressure measurement component, in a substantial vacuum.12. The method of claim 11 further comprising protective enclosure temperature management means configured for maintaining the temperature of said protective enclosure substantially at a user-specified temperature.13. The method of claim 9 wherein said protective enclosure means is configured for maintaining at least some components of said system, including said differential pressure sensor means, but excepting said low pressure measurement component and said high pressure measurement component, in a substantial vacuum.14. The method of claim 11 further comprising protective enclosure temperature management means configured for maintaining the temperature of said protective enclosure substantially at a user-specified temperature.15. The method of claim 9 further comprising protective enclosure temperature management means configured for maintaining the temperature of said protective enclosure substantially at a user-specified temperature.16. A method for detecting leaks in a storage tank; comprising the steps ofselecting a mass detection system comprising: differential pressure sensor means having a low pressure measurement component and a high pressure measurement component; protective enclosure means for protecting said differential pressure sensor means from materials and conditions when immersed in liquid contents of said storage tank; said high pressure measurement component being configured for measuring tank bottom pressure within a liquid in which said differential pressure sensor means is immersed; said low pressure measurement component being configured for receiving data indicative of atmospheric pressure substantially at the surface of said liquid; first barometric pressure measuring means configured for measuring atmospheric pressure substantially at the surface of said liquid when said protective enclosure means is immersed therein and for communicating such measurement to said low pressure measurement component of said differential pressure sensor means; second barometric pressure measuring means configured for measuring atmospheric pressure substantially at the surface of said liquid when said protective enclosure means is immersed therein; barometric pressure and differential pressure calculation means configured for receiving first and second data reflecting, respectively, said tank bottom pressure and of said barometric pressure as measured by said first barometric pressure measuring means and for calculating pressure attributable to liquid content of said storage tank, and receiving third data from said second barometric measuring means and, based thereon, adjusting said pressure attributable to said contents of said storage tank to substantially eliminate variations upon said measurements thereof caused solely from atmospheric pressure variations to yield an atmospheric pressure adjusted tank bottom pressure; ambient temperature measurement means for measuring ambient temperature near said storage tank; tank dynamic and barometric pressure adjusted tank bottom pressure calculation means configured for receiving fourth data indicative of said atmospheric pressure adjusted tank bottom pressure, for receiving fifth data indicative of ambient temperature measurements by said ambient temperature measurement means, for receiving sixth data indicative of expansion characteristics of said storage tank, and for adjusting said fourth data with reference to said fifth and sixth data to substantially eliminate variations upon measurements and calculations of said barometric pressure adjusted tank bottom pressure, caused solely by dimensional changes in said storage tank resulting from atmospheric temperature variations, to yield a tank dynamic adjusted tank bottom pressure; and tank content mass calculation means for calculating mass contents of said storage tank substantially based on said tank dynamic adjusted tank bottom pressure and user input data reflecting physical characteristics of said contents of said storage tank; selecting data storage means for collecting a plurality of mass content data as generated by said tank content mass calculation means over a plurality of points in time; selecting computing means configured for generating a human perceptible indicating of changes in said mass content data between a plurality of said points in time; placing said protective enclosure means substantially at a bottom interior surface of said storage tank; actuating said mass detection system; and observing data indicative of changes in said mass content data attributable to leakage of said storage tank to detect of such leakage. 17. The method of claim 16 further comprising the steps of:securing all input and outflow orifices of said storage tank before said actuation of said mass detection system; and substantially selectively processing said mass content data which were generated approximately between sunset and sunrise at an installation site of said system. 18. The method of claim 17 wherein said protective enclosure means is configured for maintaining at least some components of said system, including said differential pressure sensor means, but excepting said low pressure measurement component and said high pressure measurement component, in a substantial vacuum.19. The method of claim 17 further comprising protective enclosure temperature management means configured for maintaining the temperature of said protective enclosure substantially at a user-specified temperature.20. The method of claim 16 wherein said protective enclosure means is configured for maintaining at least some components of said system within said canister, including said differential pressure sensor means, but excepting said low pressure measurement component and said high pressure measurement component, in a substantial vacuum.21. The method of claim 20 further comprising protective enclosure temperature management means configured for maintaining the temperature of said protective enclosure substantially at a user-specified temperature.22. The method of claim 16 further comprising protective enclosure temperature management means configured for maintaining the temperature of said protective enclosure substantially at a user-specified temperature.
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이 특허에 인용된 특허 (2)
Williams Barry N. (Rosharan TX), Line leak detector and method.
Hyfantis ; Jr. George J. (346 Fallen Oak Cir. Seymour TN 37865) Ellis Richard A. (1913 Red Fox La. Hixson TN 37343) McCulloch Reg W. (321 W. Heritage Dr. Farragut TN 37922), Method and apparatus for detecting leaks in a liquid-containing tank.
Chu,Richard C.; Ellsworth, Jr.,Michael J.; Schmidt,Roger R.; Simons,Robert E.; Zoodsma,Randy J., Method, system and program product for monitoring rate of volume change of coolant within a cooling system.
Wolford, Jimmy; Wolford, Bernie; Lockerd, Clark; Slaughter, Ricky, System and method for detecting and quantifying changes in the mass content of liquid storage containers.
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