Method and system for monitoring smart structures utilizing distributed optical sensors
IPC분류정보
국가/구분
United States(US) Patent
등록
국제특허분류(IPC7판)
E21B-047/00
G01V-008/16
G01N-021/84
출원번호
US-0312235
(2001-06-26)
국제출원번호
PCT//US01/41165
(2002-12-23)
§371/§102 date
20021223
(20021223)
국제공개번호
WO02//05780
(2002-07-25)
발명자
/ 주소
Tubel, Paulo S.
대리인 / 주소
Duane Morris LLP
인용정보
피인용 횟수 :
294인용 특허 :
10
초록▼
A monitoring system and method for monitoring a predetermined set of physical characteristics associated with a structure using the monitoring system. The system is distributed in the structure and comprises a distributed optical sensing device (30), further comprising a fiber optic cable (20, 22);
A monitoring system and method for monitoring a predetermined set of physical characteristics associated with a structure using the monitoring system. The system is distributed in the structure and comprises a distributed optical sensing device (30), further comprising a fiber optic cable (20, 22); a light source (18a) operatively in communication with the fiber optic cable (20, 22); a light detection device (18b), operatively in communication with the fiber optic cable (20, 22), for measuring the light received at the light detection device (18b) from the fiber optic cable (20, 22); and a data processor (18) capable of using the light measured to calculate a predetermined set of physical parameters describing the predetermined set of physical characteristics.
대표청구항▼
1. A system for monitoring physical parameters distributed in a structure, comprising:a. a distributed optical sensing device (30), comprising a fiber optic cable (20,22), deployed proximate a predetermined structure, the fiber optic cable (20,22) being encapsulated in a jacket; b. a light source (1
1. A system for monitoring physical parameters distributed in a structure, comprising:a. a distributed optical sensing device (30), comprising a fiber optic cable (20,22), deployed proximate a predetermined structure, the fiber optic cable (20,22) being encapsulated in a jacket; b. a light source (18a) operatively in communication with the fiber optic cable (20,22); c. a light detection device (18b), operatively in communication with the fiber optic cable (20,22), for measuring the light received at the light detection device (18b) from the fiber optic cable (20,22); and d. a data processor (18) operatively connected to the light detection device (18b); e. wherein: (i) the data processor (18) uses light measured at the light detection device (18b) to calculate a desired physical parameter distributed in the structure; (ii) the structure is a downhole structure comprising at least one of (a) a wellbore (10), (b) production tubing, (b) casing (12), and (d) non-production tubing; (iii) the physical parameter comprises parameters of at least one of (a) the wellbore (10), (b) production tubing, (c) non-production tubing, (d) a geological formation, and (e) casing (12); and (iv) the distributed optical sensing device (30) is integrated within a downhole component deployed permanently or temporarily in the wellbore (10) to measure at least one of (a) a physical parameter of the well, (b) drilling of and production from the well, or (c) geological formation parameters. 2. The system of claim 1 wherein at least one fiber optic cable (20,22) comprises fiber optic cable (20,22) optimized for use undersea and capable of measuring physical parameters over a predetermined portion of a length of the fiber optic cable (20,22).3. The system of claim 2 wherein the fiber optic cable (20,22) is deployed undersea.4. The system of claim 3 wherein the physical parameters comprise predetermined physical characteristics of methane hydrate.5. A method for monitoring a predetermined set of physical characteristics associated with a structure or a process involving the structure, for a monitoring system, distributed in the structure, the method comprising:a. deploying a distributed optical sensing device (30) proximate a structure; b. providing light to the distributed optical sensing device (30) from a light source (18a); c. providing continuous light from a source of continuous light; d. providing pulsed light from a pulsed light probe beam; e. measuring light from the distributed optical sensing device (30) incident at a light detection device (18b) with the light detection device (18b); f. using a data processor (18) to substantially simultaneously obtain and continuously monitor a plurality of measurements from the distributed optical sensing device (30) at a plurality of locations along the distributed optical sensing device (30) using the measured light incident at the light detection device (18b); g. determining Brillouin loss; h. using the Brillouin loss to obtain the desired physical parameter measurements; and i. calculating a predetermined set of physical characteristics for a desired physical parameter using the plurality of measurements. 6. The method of claim 5 further comprising:i. stepping the continuous light source and the pulsed light probe beam through a range of frequencies around an anticipated Brillouin frequency and measuring power loss at each frequency; ii. determining a Brillouin shift at a frequency where a highest power loss is encountered; and iii. determining a desired physical parameter measurement by using a predetermined relationship between power loss and desired signal amplitude. 7. The method of claim 5, further comprising monitoring construction processes of the structure wherein step (e) further comprises calculating a progression of the construction of the structure using the one or more desired physical parameters.8. The method of claim 5, wherein the structure is a downhole structure, further comprising:a. deploying the distributed optical sensing device (30) in the downhole structure in conjunction with a drilling, production, or fishing apparatus; and b. obtaining measurements using the distributed optical sensing device (30), the measurements comprising measurements of: i. parameters comprising borehole and geological parameters as a drilling or hydrocarbon production apparatus traverses formations during construction of a wellbore (10) wherein the borehole and geological parameters comprise pressures of formations through which the borehole proceeds and temperature of the formations; ii. production of fluids from formations in the wellbore (10) wherein the parameters comprise pressures of the formations and temperature of the formations; iii. strain on drilling pipe deployed in the structure; iv. parameters calculated from data obtained while drilling wherein noise created by a drilling process or external acoustic source located at a remote location generates an acoustic signal capable of traveling through geological formations proximate the structure, the noise being detected by the fiber optic cable (20,22) as the light from the light source (18a) travels through the fiber optic cable (20,22) by using reflected phonos or photons to determine information related to temperature, strain, pressure, and acoustic disturbances; v. corrosion of casing (12) or tubing deployed within the structure; vi. parameters comprising production parameters required to optimize production in intelligent wells; vii. parameters comprising production and physical parameters in laterals to determine optimum parameters, the optimum parameters further comprising pressure and flow, useful for production of hydrocarbons; viii. parameters comprising production and physical parameters in laterals to monitor production in the laterals where at least one lateral is divided in multiple zones isolated by downhole hardware including Intelligent Completion Systems; ix. parameters obtained from data measurements in abandoned wells useful to determine presence of leaks within formations in the well; x. parameters obtained from data measurements in wells useful to monitor compaction and subsidence of formations through which the structure passes; xi. parameters obtained from data measurements during artificial lift applications, the parameters comprising pressure, strain, flow, fluid identification, and temperature, the parameters useful to optimize production in gas lift, rod pump, progressive cavity pump, and electrical submersible pump applications; xii. parameters obtained from data measurements in injector wells to monitor movement of injected fluid or steam into the structure to assure that injected fluid reaches its proper destination in the structure; xiii. parameters obtained from data measurements in geothermal wells, the parameters comprising pressure, strain, and temperature; and xiv. parameters obtained from data measurements in multilateral wells comprising laterals wherein each lateral is monitored. 9. The method of claim 5 wherein the distributed optical sensing device (30) is deployed on a seabed to monitor a desired set of physical characteristics of the seabed, the set of physical characteristics comprising movement of the seabed, temperature of the seabed, and predetermined characteristics of methane hydrate present proximate the seabed useful in evaluating methane hydrate stability subsea.10. The method of claim 5, wherein the structure is a downhole structure, further comprising:a. deploying the distributed optical sensing device (30) in the downhole structure in conjunction with a drilling, production, or fishing apparatus; and b. obtaining measurements using the distributed optical sensing device (30), the measurements comprising measurements of at least one of: i. parameters comprising borehole and geological parameters as a drilling or hydrocarbon production apparatus traverses formations during construction of a wellbore (10) wherein the borehole and geological parameters comprise pressures of formations through which the borehole proceeds and temperature of the formations; ii. production of fluids from formations in the wellbore (10) wherein the parameters comprise pressures of the formations and temperature of the formations; iii. strain on drilling pipe deployed in the structure; iv. parameters calculated from data obtained while drilling wherein noise created by a drilling process or external acoustic source located at a remote location generates an acoustic signal capable of traveling through geological formations proximate the structure, the noise being detected by the fiber optic cable (20,22) as the light from the light source (18a) travels through the fiber optic cable (20,22) by using reflected photons to determine information related to temperature, strain, pressure, and acoustic disturbances; v. corrosion of casing (12) or tubing deployed within the structure; vi. parameters comprising production parameters required to optimize production in intelligent wells; vii. parameters comprising production and physical parameters in laterals to determine optimum parameters, the optimum parameters further comprising pressure and flow, useful for production of hydrocarbons; viii. parameters comprising production and physical parameters in laterals to monitor production in the laterals where at least one lateral is divided in multiple zones isolated by downhole hardware including Intelligent Completion Systems; ix. parameters obtained from data measurements in abandoned wells useful to determine presence of leaks within formations in the well; x. parameters obtained from data measurements in wells useful to monitor compaction and subsidence of formations through which the structure passes; xi. parameters obtained from data measurements during artificial lift applications, the parameters comprising pressure, strain, flow, fluid identification, and temperature, the parameters useful to optimize production in gas lift, rod pump, progressive cavity pump, and electrical submersible pump applications; xii. parameters obtained from data measurements in injector wells to monitor movement of injected fluid or steam into the structure to assure that injected fluid reaches its proper destination in the structure; xiii. parameters obtained from data measurements in geothermal wells, the parameters comprising pressure, strain, and temperature; or xiv. parameters obtained from data measurements in multilateral wells comprising laterals wherein each lateral is monitored.
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이 특허에 인용된 특허 (10)
D\Agostino William L. (Irving TX) Barrick Michael D. (Arlington TX) Williams Glen R. (Arlington TX), Device, system and process for detecting tensile loads on a rope having an optical fiber incorporated therein.
Jackson David A. (Canterbury IL GB2) Corke Michael (Wheaton IL) Kersey Alan D. (Washington DC), Fiber optical interferometric temperature sensor with ramp modulation.
Salour Michael M. (Carlsbad CA) Schoner Gerhard (Graz CA ATX) Bechtel James H. (San Diego CA) Kull Martin (Stockholm SEX), Fiber-optic sensor with two different wavelengths of light traveling together through the sensor head.
Brady, Michael Patrick; Horton, Jr., Joseph Arno; Vitek, John Michael, Adjusting alloy compositions for selected properties in temperature limited heaters.
Zediker, Mark S.; Land, Mark S.; Rinzler, Charles C.; Faircloth, Brian O.; Koblick, Yeshaya; Moxley, Joel F., Apparatus for advancing a wellbore using high power laser energy.
Dykstra, Jason D.; Fripp, Michael Linley; DeJesus, Orlando; Gano, John C.; Holderman, Luke, Apparatus for autonomous downhole fluid selection with pathway dependent resistance system.
Ocampos, Ernesto Rafael Fonseca; Venditto, James Joseph; Cao, Renfeng Richard; Bass, Ronald Marshall; Nguyen, Scott Vinh; Cruz, Antonio Maria Guimaraes Leite; Raghu, Damodaran; Son, Jaime Santos, Circulated heated transfer fluid systems used to treat a subsurface formation.
Roes, Augustinus Wilhelmus Maria; Nair, Vijay; Munsterman, Erwin Henh; Van Bergen, Petrus Franciscus; Van Den Berg, Franciscus Gondulfus Antonius, Compositions produced using an in situ heat treatment process.
Zediker, Mark S.; Makki, Siamak; Faircloth, Brian O.; DeWitt, Ronald A.; Allen, Erik C.; Underwood, Lance D., Control system for high power laser drilling workover and completion unit.
Coates, Richard T.; Miller, Douglas E.; Hartog, Arthur H.; Wilson, Colin A.; Brady, Dominic; Menkiti, Henry; Auzerais, Francois M.; Bradford, Ian David Richard, Detection of seismic signals using fiber optic distributed sensors.
Coates, Richard T.; Miller, Douglas E.; Hartog, Arthur H.; Wilson, Colin A.; Brady, Dominic; Menkiti, Henry; Auzerais, Francois M.; Bradford, Ian David Richard, Detection of seismic signals using fiber optic distributed sensors.
Coates, Richard T.; Miller, Douglas E.; Hartog, Arthur H.; Wilson, Colin A.; Brady, Dominic; Menkiti, Henry; Auzerais, Francois M.; Bradford, Ian David Richard, Detection of seismic signals using fiber optic distributed sensors.
Burns, David Booth; Hwang, Horng Jye (Jay); Marwede, Jochen; MacDonald, Duncan Charles; Prince-Wright, Robert George, Electrical current flow between tunnels for use in heating subsurface hydrocarbon containing formations.
Taverner, Domino; Grunbeck, John J.; Dunphy, James R.; Dowd, Edward M.; Kuczma, Andrew S.; Bostick, III, Francis X.; Labella, David; Baker, Mark, Fiber optic cable for distributed acoustic sensing with increased acoustic sensitivity.
Taverner, Domino; Grunbeck, John J.; Dunphy, James R.; Dowd, Edward M.; LaBella, David; Baker, Mark; Kuczma, Andrew S.; Bostick, III, Francis X., Fiber optic cable for distributed acoustic sensing with increased acoustic sensitivity.
Dykstra, Jason D.; Fripp, Michael L.; Hamid, Syed, Flow path control based on fluid characteristics to thereby variably resist flow in a subterranean well.
Dykstra, Jason D.; Fripp, Michael L.; Hamid, Syed, Flow path control based on fluid characteristics to thereby variably resist flow in a subterranean well.
Karanikas, John Michael; Beer, Gary Lee; Marino, Marian; McNeil, III, Robert Irving; Roes, Augustinus Wilhelmus Maria; Ryan, Robert Charles; Pollard, Richard, Forming bitumen barriers in subsurface hydrocarbon formations.
Cavender, Travis W.; Pipkin, Robert L.; Hunter, Timothy; Schultz, Roger L., Forming inclusions in selected azimuthal orientations from a casing section.
Cavender, Travis W.; Pipkin, Robert L.; Hunter, Timothy; Schultz, Roger L., Forming inclusions in selected azimuthal orientations from a casing section.
Kuhlman, Myron Ira; Vinegar, Harold J.; Baker, Ralph Sterman; Heron, Goren, Gas injection to inhibit migration during an in situ heat treatment process.
Vinegar, Harold J.; Coit, William George; Griffin, Peter Terry; Hamilton, Paul Taylor; Hsu, Chia-Fu; Mason, Stanley Leroy; Samuel, Allan James; Watkins, Ronnie Wade, Grouped exposed metal heaters.
Vinegar, Harold J.; Coit, William George; Griffin, Peter Terry; Hamilton, Paul Taylor; Hsu, Chia-Fu; Mason, Stanley Leroy; Samuel, Allan James; Watkins, Ronnie Wade, Grouped exposed metal heaters.
Burns, David Booth; Hwang, Horng Jye (Jay); Marwede, Jochen; MacDonald, Duncan Charles; Prince-Wright, Robert George, Heated fluid flow in mines and tunnels used in heating subsurface hydrocarbon containing formations.
Ayodele, Oluropo Rufus; Colmenares, Tulio Rafael; Dindoruk, Deniz Sumnu; Karanikas, John Michael; Pino, Sr., Henry Eduardo, Heater assisted fluid treatment of a subsurface formation.
Burns, David Booth; Hwang, Horng Jye (Jay); Marwede, Jochen; MacDonald, Duncan Charles; Prince-Wright, Robert George, Heater connections in mines and tunnels for use in treating subsurface hydrocarbon containing formations.
de Rouffignac, Eric Pierre; Pingo Almada, Monica M.; Miller, David Scott, Heating hydrocarbon containing formations in a checkerboard pattern staged process.
Deutch, Paul D.; Marshall, Scott A.; Grubb, Daryl L.; De Witt, Ronald A.; Zediker, Mark S.; Faircloth, Brian O., High power laser decomissioning of multistring and damaged wells.
Faircloth, Brian O.; Zediker, Mark S.; Rinzler, Charles C.; Koblick, Yeshaya; Moxley, Joel F., High power laser energy distribution patterns, apparatus and methods for creating wells.
Linyaev, Eugene J.; Marshall, Scott A.; Grubb, Daryl L.; De Witt, Ronald A.; Deutch, Paul D.; Faircloth, Brian O.; Fraze, Jason D.; Zediker, Mark S., High power laser offshore decommissioning tool, system and methods of use.
Linyaev, Eugene J.; Zediker, Mark S.; Grubb, Daryl L.; Schroit, Sam N.; De Witt, Ronald A.; Kolachalam, Sharath K; Deutch, Paul D.; Faircloth, Brian O., High power laser perforating and laser fracturing tools and methods of use.
Zediker, Mark S.; Jones-Albertus, Rebecca; Faircloth, Brian O.; Rinzler, Charles C.; Moxley, Joel F., High power laser photo-conversion assemblies, apparatuses and methods of use.
McKay, Ryan P.; Rinzler, Charles C.; Moxley, Joel F.; Deutch, Paul D.; Zediker, Mark S.; DeWitt, Ronald A.; Faircloth, Brian O., High power laser pipeline tool and methods of use.
Zediker, Mark S.; Rinzler, Charles C.; Faircloth, Brian O.; Koblick, Yeshaya; Moxley, Joel F., High power laser workover and completion tools and systems.
Grubb, Daryl L.; Kolachalam, Sharath K.; Faircloth, Brian O.; Rinzler, Charles C.; Allen, Erik C.; Underwood, Lance D.; Zediker, Mark S., High power laser-mechanical drilling bit and methods of use.
Maziasz, Phillip James; Shingledecker, John Paul; Santella, Michael Leonard; Schneibel, Joachim Hugo; Sikka, Vinod Kumar; Vinegar, Harold J.; John, Randy Carl; Kim, Dong Sub, High strength alloys.
Maziasz, Phillip James; Shingledecker, John Paul; Santella, Michael Leonard; Schneibel, Joachim Hugo; Sikka, Vinod Kumar; Vinegar, Harold J.; John, Randy Carl; Kim, Dong Sub, High strength alloys.
Sandberg, Chester Ledlie; Vinegar, Harold J.; Harris, Christopher Kelvin; Son, Jaime Santos; Carl, Jr., Fredrick Gordon, High voltage temperature limited heaters.
Burns, David Booth; Hwang, Horng Jye (Jay); Marwede, Jochen; MacDonald, Duncan Charles; Prince-Wright, Robert George, Hydrocarbon production from mines and tunnels used in treating subsurface hydrocarbon containing formations.
Vinegar, Harold J.; Sumnu-Dindoruk, Meliha Deniz; Wellington, Scott Lee; Maher, Kevin Albert; Karanikas, John Michael; de Rouffignac, Eric Pierre; Messier, Margaret Ann; Roberts, Bruce Edmunds; Crane, Steven Dexter, In situ recovery from a hydrocarbon containing formation.
de Rouffignac, Eric Pierre; Berchenko, Ilya Emil; Fowler, Thomas David; Ryan, Robert Charles; Shahin, Jr., Gordon Thomas; Stegemeier, George Leo; Vinegar, Harold J.; Wellington, Scott Lee; Zhang, Etuan, In situ recovery from a hydrocarbon containing formation.
de Rouffignac, Eric Pierre; Berchenko, Ilya Emil; Fowler, Thomas David; Ryan, Robert Charles; Shahin, Jr., Gordon Thomas; Stegemeier, George Leo; Vinegar, Harold J.; Wellington, Scott Lee; Zhang, Etuan, In situ recovery from a hydrocarbon containing formation.
de Rouffignac, Eric Pierre; Berchenko, Ilya Emil; Fowler, Thomas David; Ryan, Robert Charles; Shahin, Jr., Gordon Thomas; Stegemeier, George Leo; Vinegar, Harold J.; Wellington, Scott Lee; Zhang, Etuan, In situ recovery from a hydrocarbon containing formation.
Vinegar, Harold J.; Karanikas, John Michael; Ryan, Robert Charles, In situ recovery from residually heated sections in a hydrocarbon containing formation.
Vinegar, Harold J.; de Rouffignac, Eric Pierre; Maher, Kevin Albert; Schoeling, Lanny Gene; Wellington, Scott Lee, In situ thermal processing of an oil shale formation.
Vinegar, Harold J.; Sandberg, Chester Ledlie, Insulated conductor temperature limited heater for subsurface heating coupled in a three-phase WYE configuration.
Zediker, Mark S.; Bergeron, Henry A.; Clark, Philip V.; Moxley, Joel F.; Deutch, Paul D.; Underwood, Lance D.; Rinzler, Charles C.; De Witt, Ronald A.; Kolachalam, Sharath K.; Grubb, Daryl L., Laser assisted blowout preventer and methods of use.
Zediker, Mark S.; Bergeron, Henry A.; Clark, Philip V.; Faircloth, Brian O.; Moxley, Joel F.; Deutch, Paul D.; Rinzler, Charles C., Laser assisted riser disconnect and method of use.
Underwood, Lance D.; Norton, Ryan J.; McKay, Ryan P.; Mesnard, David R.; Fraze, Jason D.; Zediker, Mark S.; Faircloth, Brian O., Laser bottom hole assembly.
Zediker, Mark S.; Grubb, Daryl L.; De Witt, Ronald A.; Deutch, Paul D.; Moxley, Joel F.; Marshall, Scott A.; Linyaev, Eugene J.; Schroit, Sam N.; Kolachalam, Sharath K., Laser systems and methods for the removal of structures.
Rinzler, Charles C.; Gray, William C.; Faircloth, Brian O.; Zediker, Mark S., Long distance high power optical laser fiber break detection and continuity monitoring systems and methods.
Konopczynski, Michael R.; Davis, Eric; Maida, Jr., John L.; Samson, Etienne M.; Leblanc, Michel J.; Jones, Christopher M.; Pelletier, Michael T.; Fripp, Michael L., Maximizing hydrocarbon production while controlling phase behavior or precipitation of reservoir impairing liquids or solids.
Wilson, Brown Lyle; Brookbank, Earl Bruce; Sheth, Ketankumar K.; O'Bryan, Suresha R.; Tetzlaff, Steven K.; Rutter, Risa, Measuring operational parameters in an ESP seal with fiber optic sensors.
Dykstra, Jason D.; Fripp, Michael Linley; DeJesus, Orlando; Gano, John C; Holderman, Luke, Method and apparatus for autonomous downhole fluid selection with pathway dependent resistance system.
Dykstra, Jason D.; Fripp, Michael Linley; DeJesus, Orlando; Gano, John C; Holderman, Luke, Method and apparatus for autonomous downhole fluid selection with pathway dependent resistance system.
Dykstra, Jason D; Fripp, Michael Linley; DeJesus, Orlando; Gano, John C.; Holderman, Luke, Method and apparatus for autonomous downhole fluid selection with pathway dependent resistance system.
Dykstra, Jason D; Fripp, Michael Linley; DeJesus, Orlando; Gano, John C.; Holderman, Luke, Method and apparatus for autonomous downhole fluid selection with pathway dependent resistance system.
Fripp, Michael Linley; Dykstra, Jason D.; DeJesus, Orlando, Method and apparatus for autonomous downhole fluid selection with pathway dependent resistance system.
Zediker, Mark S.; Rinzler, Charles C.; Faircloth, Brian O.; Koblick, Yeshaya; Moxley, Joel F., Method and apparatus for delivering high power laser energy over long distances.
Zediker, Mark S.; Rinzler, Charles C.; Faircloth, Brian O.; Koblick, Yeshaya; Moxley, Joel F., Method and apparatus for delivering high power laser energy over long distances.
Moxley, Joel F.; Land, Mark S.; Rinzler, Charles C.; Faircloth, Brian O.; Zediker, Mark S., Method and system for advancement of a borehole using a high power laser.
Faircloth, Brian O.; Zediker, Mark S.; Rinzler, Charles C.; Koblick, Yeshaya; Moxley, Joel F., Methods and apparatus for delivering high power laser energy to a surface.
Rinzler, Charles C.; Zediker, Mark S.; Faircloth, Brian O.; Moxley, Joel F., Methods and apparatus for removal and control of material in laser drilling of a borehole.
Fairbanks, Michael David; Keltner, Thomas Joseph; McKinzie, II, Billy John; Hirshblond, Stephen Palmer, Methods and systems for producing fluid from an in situ conversion process.
Zediker, Mark S.; Rinzler, Charles C.; Faircloth, Brian O.; Koblick, Yeshaya; Moxley, Joel F., Methods for enhancing the efficiency of creating a borehole using high power laser systems.
Ocampos, Ernesto Rafael Fonseca; Karanikas, John Michael; MacDonald, Duncan Charles; Carter, Jr., Ernest E., Methods for heating with slots in hydrocarbon formations.
Minderhoud, Johannes Kornelis; Nelson, Richard Gene; Roes, Augustinus Wilhelmus Maria; Ryan, Robert Charles; Nair, Vijay, Methods of hydrotreating a liquid stream to remove clogging compounds.
Roes, Augustinus Wilhelmus Maria; Mo, Weijian; Muylle, Michel Serge Marie; Mandema, Remco Hugo; Nair, Vijay, Methods of producing alkylated hydrocarbons from an in situ heat treatment process liquid.
Prince-Wright, Robert George; Marwede, Jochen; Hwang, Horng Jye (Jay); MacDonald, Duncan Charles; Burns, David Booth, Mines and tunnels for use in treating subsurface hydrocarbon containing formations.
Stegemeier, George Leo; Mudunuri, Ramesh Raju; Vinegar, Harold J.; Karanikas, John Michael; Jaiswal, Namit; Mo, Weijian, Moving hydrocarbons through portions of tar sands formations with a fluid.
Zediker, Mark S.; Rinzler, Charles C.; Faircloth, Brian O.; Moxley, Joel F.; Koblick, Yeshaya, Optical fiber cable for transmission of high power laser energy over great distances.
Arias Vidal,Jose Luiz; da Silva J첬nior,Manoel Felician; Freitas,Ricardo Munoz; Barbosa Braga,Arthur Martins; Guedes Valente,Luiz Carlos; Regazzi,Rog챕rio Dias; Ribeiro,Alexandre Sant'Anna; Ferreira,Lincoln Homero Thom챕; dos Santos Lorenzo,Joao Luiz, Optical transducer and method for the simultaneous measurement of pressure and temperature in oil and gas wells.
Daub, Gerald Jacob; Keedy, Charles Robert; Fresky, Mariela Gertrudis Araujo; Fowler, Thomas David; Holman, Matthew Lee, Partial solution mining of hydrocarbon containing layers prior to in situ heat treatment.
Wolfe, Daniel L.; Bailey, Andyle G.; Grubb, Daryl L.; Kolachalam, Sharath K.; Zediker, Mark S.; Deutch, Paul D., Reduced mechanical energy well control systems and methods of use.
Rinzler, Charles C.; Gray, William C.; Fraze, Jason D.; Faircloth, Brian O.; Zediker, Mark S.; McKay, Ryan P., Rugged passively cooled high power laser fiber optic connectors and methods of use.
Kragh, Ed; Muyzert, Everhard; Robertsson, Johan; Miller, Douglas E.; Hartog, Arthur H., Seismic acquisition system including a distributed sensor having an optical fiber.
Kragh, Ed; Muyzert, Everhard; Robertsson, Johan; Miller, Douglas E.; Hartog, Arthur H., Seismic acquisition system including a distributed sensor having an optical fiber.
Zediker, Mark S.; Bergeron, Henry A.; Clark, Philip V.; Moxley, Joel F.; Deutch, Paul D.; Rinzler, Charles C., Shear laser module and method of retrofitting and use.
Vinegar, Harold J.; de Rouffignac, Eric Pierre; Schoeling, Lanny Gene, Solution mining systems and methods for treating hydrocarbon containing formations.
Vinegar, Harold J.; Bass, Ronald Marshall; Kim, Dong Sub; Mason, Stanley Leroy; Stegemeier, George Leo; Keltner, Thomas Joseph; Carl, Jr., Frederick Gordon, Subsurface connection methods for subsurface heaters.
Koelman, Johannes Maria Vianney Antonius; Wills, Peter Berkeley; Molenaar, Menno Mathieu; Cox, Barbara Ellen; Joinson, Daniel, System and method for making distributed measurements using fiber optic cable.
Vidal,Jose Luiz Arias; J��nior,Manoel Feliciano da Silva; Freitas,Ricardo Munoz; Ferreira,Lincoln Homero Thom��, System for the measurement and data acquisition for optical fiber sensors.
Norton, Ryan J.; McKay, Ryan P.; Fraze, Jason D.; Rinzler, Charles C.; Grubb, Daryl L.; Faircloth, Brian O.; Zediker, Mark S., Systems and assemblies for transferring high power laser energy through a rotating junction.
DeWitt, Ronald A.; Zediker, Mark S.; Faircloth, Brian O.; Grubb, Daryl L.; McKay, Ryan P.; Gray, William C.; Moxley, Joel F.; Rinzler, Charles C.; Underwood, Lance D.; Deutch, Paul D., Systems and conveyance structures for high power long distance laser transmission.
DeWitt, Ronald A.; Zediker, Mark S.; Faircloth, Brian O.; Grubb, Daryl L.; McKay, Ryan P.; Gray, William C.; Moxley, Joel F.; Rinzler, Charles C.; Underwood, Lance D.; Deutch, Paul D., Systems and conveyance structures for high power long distance laser transmission.
Hartog, Arthur H.; Brown, J. Ernest; Cook, John; Elphick, Jonathan James; Hammond, Paul Simon; Johnson, Ashley, Systems and methods for distributed interferometric acoustic monitoring.
Hartog, Arthur H; Brown, J Ernest; Cook, John Mervyn; Elphick, Jonathan; Hammond, Paul S; Johnson, Ashley Bernard, Systems and methods for distributed interferometric acoustic monitoring.
Xie, Xueying; Ayodele, Oluropo Rufus; Vinegar, Harold J.; Harris, Christopher Kelvin; Karanikas, John Michael; Sandberg, Chester Ledlie; Arora, Dhruv, Systems and methods for treating a subsurface formation with electrical conductors.
Vitek, John Michael; Brady, Michael Patrick; Horton, Jr., Joseph Arno, Temperature limited heaters using phase transformation of ferromagnetic material.
Gonzalez, Manuel Alberto; Cruz, Antonio Maria Guimaraes Leite; Jung, Gonghyun; Noel, Justin Michael; Ocampos, Ernesto Rafael Fonseca; Penso, Jorge Antonio; Horwege, Jason Andrew; Levy, Stephen Michael; Raghu, Damodaran, Thermal expansion accommodation for circulated fluid systems used to heat subsurface formations.
Goldberg, Bernard; Hale, Arthur Herman; Miller, David Scott; Vinegar, Harold J., Time sequenced heating of multiple layers in a hydrocarbon containing formation.
Pieterson, Roelof; Boyles, Joseph Michael; Diebold, Peter Ulrich, Using geothermal energy to heat a portion of a formation for an in situ heat treatment process.
Vinegar, Harold J.; Carter, Ernest E.; Son, Jaime Santos; Bai, Taixu; Khoda Verdian, Mohamad Fereydoon, Wax barrier for use with in situ processes for treating formations.
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