초록 ▼

A leak detection system includes a pressure system that requires leak and/or pressure testing. A pressure sensor coupled to the pressure system senses a first pressure at time t0, after which fluid pumping system provides a selected volume of test fluid to the pressure system. The pressure sensor se

A leak detection system includes a pressure system that requires leak and/or pressure testing. A pressure sensor coupled to the pressure system senses a first pressure at time t0, after which fluid pumping system provides a selected volume of test fluid to the pressure system. The pressure sensor senses a test pressure at time t1 and at selected intervals ‘n’ to time t(n+1) and transmits a signal reflective of the pressures at each time to a computer system for recording and storage on a computer readable medium. A software application operating on the computer system is configured to calculate a leak detection value, which is a function of a ratio of the first pressure at time t0 and the test pressure at time t1; the test pressure at time t1 and the test pressure at time t2; and so on to a test pressure at the timen and the test pressure at the time t(n+1). A graphical output displays the leak detection value as a function of time.

대표청구항 ▼

1. A method for testing the integrity of a pressure system, said pressure system having a plurality of fluid control components, a plurality of fluid pathways defined by said fluid control components, and at least one pressure sensor in fluid communication with said plurality of fluid pathways, said

1. A method for testing the integrity of a pressure system, said pressure system having a plurality of fluid control components, a plurality of fluid pathways defined by said fluid control components, and at least one pressure sensor in fluid communication with said plurality of fluid pathways, said method comprising: forming, on an output device of a computer system, an illustration representative of said pressure system, said illustration including a plurality of fluid control symbols reflective of said plurality of fluid control components, said fluid control symbols reflecting at least one of an operating position and a test status of a fluid control component;receiving, by the computer system, a selection of an operating position for a first plurality of fluid control symbols to define a first fluid pathway within said illustration;receiving, by the computer system, a selection of an operating position for a second plurality of fluid control symbols to define a second fluid pathway within said illustration;receiving, by the computer system, a signal reflective of a pressure sensed by said pressure sensor;positioning a first plurality of fluid control components to form said first fluid pathway within said pressure system, said first fluid pathway configured to be individually pressurized and including said pressure sensor;pressurizing said first fluid pathway to a first test pressure, causing said pressure sensor to generate a signal reflective of a first pathway pressure;receiving, by the computer system, said signal reflective of said first pathway pressure at time t1 and at time t2;comparing, by the computer system, said first pathway pressure at time t1 and at time t2 and calculating, by the computer system, a first test status of said first fluid pathway from a difference in said first pathway pressure from time t1 to time t2;displaying on the output device said first test status;positioning a second plurality of fluid control components to form said second fluid pathway within said pressure system, said second fluid pathway configured to be individually pressurized and including said pressure sensor;pressurizing said second fluid pathway to a second test pressure, causing said pressure sensor to generate a signal reflective of a second pathway pressure;receiving, by the computer system, said signal reflective of said second pathway pressure at time t3 and at time t4;comparing, by the computer system, said second pathway pressure at time t3 and at time t4 and calculating, by the computer system, a second test status for said second fluid pathway from a difference in said second pathway pressure from time t3 to time t4;displaying on the output device said second test status;positioning a third plurality of fluid control components to form a third fluid pathway within said pressure system, said third fluid pathway being configured to receive said pressurized fluid if said first fluid pathway fails to maintain said first test pressure; andventing said third fluid pathway to atmosphere. 2. The method of claim 1, wherein said first plurality of fluid control components and said second plurality of fluid control components share at least one common fluid control component with a corresponding common fluid control symbol in said illustration. 3. The method of claim 2, further comprising operating said computer system to reflect a passing status onto said common fluid control symbol when at least one of said first test status and said second test status is a passing status. 4. The method of claim 1, wherein said second fluid pathway is contained entirely within said first fluid pathway. 5. The method of claim 1, wherein said second fluid pathway includes at least one fluid control component not included within said first fluid pathway. 6. The method of claim 1, wherein at least one of said plurality of fluid control components is a blowout preventer (BOP). 7. The method of claim 6, wherein said blowout preventer is selected from the group consisting of a test ram BOP, a blind ram BOP, a shear ram BOP, a pipe ram BOP, a variable pipe ram BOP, and an annular BOP. 8. The method of claim 1, wherein at least one of said plurality of fluid control components is selected from the group consisting of a rigid tubular conduit, a flexible tubular conduit, a valve, a fitting, and a fluid-tight seal. 9. The method of claim 1, wherein at least one of said plurality of fluid control components is a valve having a first side and a second side opposite said first side. 10. The method of claim 9, wherein: causing said first fluid pathway to be pressurized applies said first pathway pressure to said first side of said valve; andcausing said second fluid pathway to be pressurized applies said second pathway pressure to said second side of said valve. 11. The method of claim 1, wherein calculating a first test status of said first fluid pathway from a difference in said first pathway pressure from time t1 to time t2 further comprises: calculating a leak detection value that is the absolute value of a ratio of said pressure at time t1 and said pressure at time t2 subtracted from unity;comparing said leak detection value against a leak threshold; andrecording said first test status as a passing status when said leak detection value meets said leak threshold. 12. A method for testing the pressure integrity of a pressure system, said pressure system having a plurality of fluid control components configured to be operated to define a plurality of fluid pathways, and at least one pressure sensor in fluid communication with said plurality of fluid pathways, said method comprising: generating a schematic illustration of said pressure system on an output device of a computer system, said schematic illustration including symbols reflective of each of said plurality of fluid control components and each of said plurality of fluid pathways;receiving, by the computer system, a signal reflective of a pressure sensed by said pressure sensor;positioning a first plurality of fluid control components to form a first fluid pathway, said first fluid pathway configured to be individually pressurized and including said pressure sensor;pressurizing said first fluid pathway to a first test pressure;monitoring with said computer system a first pathway pressure for a first period of time;calculating with said computer system a first test status of said first fluid pathway from a variance in said first pathway pressure during said first period of time, said first test status being selected from a passing status and a fail status;positioning a second plurality of fluid control components to form a second fluid pathway, said second fluid pathway configured to be individually pressurized and including said pressure sensor and at least one tested fluid control component in common with said first fluid pathway;pressurizing said second fluid pathway to a second test pressure;monitoring with said computer system a second pathway pressure for a second period of time;calculating with said computer system a second test status of said second fluid pathway from a variance in said second pathway pressure during said second period of time, said second test status being selected from a passing status and a fail status;displaying on the output device a passing status for said tested fluid control component when at least one of said first test status and said second test status is a passing status;positioning a third plurality of fluid control components to form a third fluid pathway within said pressure system, said third fluid pathway being configured to receive said pressurized fluid if said first fluid pathway fails to maintain said first test pressure; andventing said third fluid pathway to atmosphere. 13. The method of claim 12, wherein said second fluid pathway is contained entirely within said first fluid pathway. 14. The method of claim 12, wherein said second fluid pathway includes at least one fluid control component not included within said first fluid pathway. 15. The method of claim 12, wherein said tested fluid control component is a blowout preventer (BOP) selected from the group consisting of a test ram BOP, a blind ram BOP, a shear ram BOP, a pipe ram BOP, a variable pipe ram BOP, and an annular BOP. 16. The method of claim 12, wherein monitoring with said computer system said first pathway pressure for a first period of time comprises: sensing said first pathway pressure with said pressure sensor at time t0;recording data reflective of said first pathway pressure at time t0 on said computer system;sensing said first pathway pressure with said pressure sensor at time t1;recording data reflective of said first pathway pressure at time t1 on said computer system;calculating a leak detection value that is the ratio of said first pathway pressure at time t0 and said first pathway pressure at time t1 subtracted from unity;generating a leak detection signal reflective of said leak detection value; anddisplaying said leak detection value as a function of time on the output device. 17. The method of claim 12, further comprising: pressurizing said first fluid pathway to a first reduced pathway pressure prior to said first period of time, said first reduced pathway pressure being less than one fifth of said first pathway pressure; andmonitoring with said computer system said first pathway pressure for said additional period of time; andcalculating with said computer system a first reduced pressure test status of said first fluid pathway from a variance in said first reduced pathway pressure during said first period of time, said first reduced pressure test status being selected from a passing status and a fail status. 18. A leak detection system comprising: a pressure system having a plurality of fluid control components, said fluid control components configured to be operated to form a first fluid pathway and a second fluid pathway, said first fluid pathway and said second fluid pathway each configured to be separately pressurized and each including at least one tested fluid control component contained within both said first fluid pathway and said second fluid pathway, the fluid control components further configured to be operated to form a third fluid pathway within said pressure system, said third fluid pathway being configured to receive a pressurized fluid if said first fluid pathway fails to maintain a test pressure and vent to atmosphere;a computer system to display a schematic illustration of said pressure system, said schematic illustration including a plurality of fluid control symbols reflective of said fluid control components forming said first fluid pathway and said second fluid pathway;a source of pressurized fluid in fluid communication with said pressure system, said source of pressurized fluid configured to be operated to separately supply said pressurized fluid to each of said first fluid pathway and said second fluid pathway; andat least one pressure sensor in fluid communication with said first fluid pathway and said second fluid pathway and in electrical communication with said computer system, said at least one pressure sensor being configured to generate and transmit a signal reflective of a pressure sensed by said pressure sensor to said computer system;said computer system configured to monitor a first pathway pressure within first fluid pathway when pressurized to a first test pressure, and to calculate a first test status of said first fluid pathway from a variance in said first pathway pressure during a first period of time, said first test status being selected from a passing status and a fail status;said computer system configured to monitor a second pathway pressure within second fluid pathway when pressurized to a second test pressure, and to calculate a second test status of said second fluid pathway from a variance in said second pathway pressure during a second period of time, said second test status being selected from a passing status and a fail status, and said computer system configured to be operated to display a passing status for said tested fluid control component with said schematic illustration when at least one of said first test status and said second test status is a passing status.