Patents by Inventor Ian Mitchell
Ian Mitchell has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Patent number: 10125569Abstract: A fluid monitoring system comprises a data acquisition and control interface and one or more fluid measurement devices communicatively coupled to the data acquisition and control interface. The one or more fluid measurement devices are configured to detect amounts of fluids pumped into or exiting the well bore during cementing. The data acquisition and control interface receives a first set of data comprising calculated volumes and/or pressures of a flow of one or more fluids exiting a model well bore over a predetermined period of time based in part on a heat of reaction produced by the curing of a cement composition, and a second set of data comprising volumes and/or pressures of a flow of one or more fluids pumped into or exiting the well bore from the one or more fluid measurement devices. The data acquisition and control interface uses the first and second sets of data received to determine one or more characteristics of the cement composition.Type: GrantFiled: January 28, 2013Date of Patent: November 13, 2018Assignee: Halliburton Energy Services, Inc.Inventors: Christopher Marland, Ian Mitchell, James Randolph Lovorn
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Publication number: 20180283163Abstract: A subsea pump system includes a subsea pump, a fluid conditioner tank arranged upstream of the subsea pump, a liquid conservation tank arranged downstream of the subsea pump, a line arranged to recirculate a liquid from the liquid conservation tank to upstream of the subsea pump, an umbilical which provides power, a monitoring and a control, a first buoyancy element suspended in the fluid conditioner tank, a second buoyancy element suspended in the liquid conservation tank, optical fiber sensors which are arranged at least to a suspension of the first buoyancy element in the fluid conditioner tank and to a suspension of the second buoyancy element in the liquid conservation tank, and electronics.Type: ApplicationFiled: September 22, 2016Publication date: October 4, 2018Applicants: AKER SOLUTIONS INC., BAKER HUGHES, A GE COMPANY, LLCInventors: ROBIN SLATER, WILLIAM JOHNSTON, IAN MITCHELL, ALEXANDER BARRY
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Publication number: 20180256728Abstract: In some embodiments, a lipofullerene-saccharide compound and a method of inhibiting and/or ameliorating metastasis of neoplastic cells using said compound is disclosed herein. The lipofullerene-saccharide compound may be used in therapeutically effective doses to inhibit the metastasis of neoplasms in mammals. In some embodiments, the method may include administering to a subject an effective amount of a pharmaceutically acceptable formulation including a lipofullerene-saccharide compound. In some embodiments, the lipofullerene-saccharide compound may be formed by reacting (e.g., coupling) a lipid and a saccharide with a fullerene. In some embodiments, neoplastic cells may include pancreatic cancer cells, prostate cancer cells, lung cancer cells, breast cancer cells, colon cancer cells, and/or brain cancer cells.Type: ApplicationFiled: February 23, 2018Publication date: September 13, 2018Inventors: Ian Mitchell, Ayyappan Subbiah, Daniel David Bensimon
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Patent number: 10036247Abstract: An embodiment of a system for performing a downhole operation includes a carrier having an isolation assembly including at least one packer having a deformable element configured to isolate a section of a borehole in the earth formation, and an injection assembly configured to inject a fluid into the isolated section and pressurize the isolated section. The system also includes a measurement assembly including an interrogation unit coupled to at least one optical fiber having a length disposed at the deformable element that includes a plurality of measurement locations, and a processor configured to receive signals reflected by the plurality of measurement locations in real time during the downhole operation, calculate an amount of deformation of the deformable packer element, and estimate at least one property of the formation based on the deformation, the at least one property including a strain of the formation in response to injection of fluid.Type: GrantFiled: November 16, 2015Date of Patent: July 31, 2018Assignee: BAKER HUGHES, A GE COMPANY, LLCInventors: Dee Adedotun Moronkeji, Javier Alejandro Franquet, Ian Mitchell
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Patent number: 9989425Abstract: A distributed temperature sensor, a method of determining temperature, and a processing system to compute temperature are described. The sensor includes an optical fiber disposed in an area where temperature is to be measured, a primary light source to inject light into the optical fiber, and a secondary light source to inject light into the optical fiber. The sensor additionally includes a photodetector to detect backscatter light energy from the optical fiber the backscatter light energy including Stokes Raman scatter or anti-Stokes Raman scatter and primary Rayleigh scatter resulting from the primary light source and secondary Rayleigh scatter resulting from the secondary light source, and a processor to determine temperature based on a ratio of the Stokes Raman scatter or the anti-Stokes Raman scatter and a combination of the primary Rayleigh scatter and the secondary Rayleigh scatter.Type: GrantFiled: March 20, 2015Date of Patent: June 5, 2018Assignee: BAKER HUGHES, A GE COMPANY, LLCInventors: Ian Mitchell, William Johnston, Ashwin Chandran
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Patent number: 9797783Abstract: A distributed temperature sensor (DTS) system includes a light source; a length of fiber filter having been hydrogen darkened prior to assembly of the system; and a DTS fiber. A method for making a filter for a DTS system.Type: GrantFiled: May 19, 2016Date of Patent: October 24, 2017Assignee: BAKER HUGHES INCORPORATEDInventors: William Albert Johnston, Ian Mitchell
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Patent number: 9678044Abstract: A method of measuring acoustic energy impinging upon a cable includes, interrogating at least one optical fiber of the cable with electromagnetic energy, the at least one optical fiber is nonconcentrically surrounded by and strain locked to a sheath of the cable, monitoring electromagnetic energy returned in the at least one optical fiber, and determining acoustic energy impinging on the cable.Type: GrantFiled: March 18, 2015Date of Patent: June 13, 2017Assignee: BAKER HUGHES INCORPORATEDInventors: Paul F. Wysocki, Ian Mitchell, Matthew Thomas Raum
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Publication number: 20170138187Abstract: An embodiment of a system for performing a downhole operation includes a carrier having an isolation assembly including at least one packer having a deformable element configured to isolate a section of a borehole in the earth formation, and an injection assembly configured to inject a fluid into the isolated section and pressurize the isolated section. The system also includes a measurement assembly including an interrogation unit coupled to at least one optical fiber having a length disposed at the deformable element that includes a plurality of measurement locations, and a processor configured to receive signals reflected by the plurality of measurement locations in real time during the downhole operation, calculate an amount of deformation of the deformable packer element, and estimate at least one property of the formation based on the deformation, the at least one property including a strain of the formation in response to injection of fluid.Type: ApplicationFiled: November 16, 2015Publication date: May 18, 2017Applicant: Baker Hughes IncorporatedInventors: Dee Adedotun Moronkeji, Javier Alejandro Franquet, Ian Mitchell
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Publication number: 20160370235Abstract: A distributed temperature sensor (DTS) system includes a light source; a length of fiber filter having been hydrogen darkened prior to assembly of the system; and a DTS fiber. A method for making a filter for a DTS system.Type: ApplicationFiled: May 19, 2016Publication date: December 22, 2016Applicant: Baker Hughes IncorporatedInventors: William Albert Johnston, Ian Mitchell
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Publication number: 20160274064Abstract: A method of measuring acoustic energy impinging upon a cable includes, interrogating at least one optical fiber of the cable with electromagnetic energy, the at least one optical fiber is nonconcentrically surrounded by and strain locked to a sheath of the cable, monitoring electromagnetic energy returned in the at least one optical fiber, and determining acoustic energy impinging on the cable.Type: ApplicationFiled: March 18, 2015Publication date: September 22, 2016Applicant: Baker Hughes IncorporatedInventors: Paul F. Wysocki, Ian Mitchell, Matthew Thomas Raum
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Patent number: 9404831Abstract: An apparatus for performing a measurement of a downhole property includes an optical fiber having a first section that has a first set of fiber Bragg gratings with a first resonant wavelength inscribed therein and a second section that has a second set of fiber Bragg gratings with a second resonant wavelength different from the first resonant wavelength inscribed therein. The second section is in series with the first section. An optical interrogator emits a swept-wavelength frequency domain light signal having varying wavelength amplitude modulation into the optical fiber, receives a frequency domain return light signal, and transforms the frequency domain return signal into a time domain to determine a resonant wavelength shift of each fiber Bragg grating and the corresponding location of each interrogated fiber Bragg grating. A processor converts the resonant wavelength shift of each interrogated fiber Bragg grating into the downhole property measurement.Type: GrantFiled: October 27, 2014Date of Patent: August 2, 2016Assignee: Baker Hughes IncorporatedInventors: Alexander M. Barry, Karl Kai Ku, Ian Mitchell, William Johnston
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Publication number: 20160116369Abstract: An apparatus for performing a measurement of a downhole property includes an optical fiber having a first section that has a first set of fiber Bragg gratings with a first resonant wavelength inscribed therein and a second section that has a second set of fiber Bragg gratings with a second resonant wavelength different from the first resonant wavelength inscribed therein. The second section is in series with the first section. An optical interrogator emits a swept-wavelength frequency domain light signal having varying wavelength amplitude modulation into the optical fiber, receives a frequency domain return light signal, and transforms the frequency domain return signal into a time domain to determine a resonant wavelength shift of each fiber Bragg grating and the corresponding location of each interrogated fiber Bragg grating. A processor converts the resonant wavelength shift of each interrogated fiber Bragg grating into the downhole property measurement.Type: ApplicationFiled: October 27, 2014Publication date: April 28, 2016Applicant: BAKER HUGHES INCORPORATEDInventors: Alexander M. Barry, Karl Kai Ku, Ian Mitchell, William Johnston
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Patent number: 9308243Abstract: In some embodiments, a chemical composition may include C60, serrapeptase, or a tetrapeptide. The tetrapeptide may include ALA,GLU,ASP,GLY. In some embodiments, the chemical composition may include a dipeptide. The dipeptide may include carnosine or camatine. In some embodiments, the chemical composition may include at least one lipid. One or more components of the chemical composition may be suspended in and/or dissolved in the at least one lipid. At least one lipid may include olive oil or mussel oil. In some embodiments, a method may include administering to a subject an effective amount of a pharmaceutically acceptable formulation comprising the chemical composition. The method may include inhibiting and/or ameliorating inflammation and/or a malady associated with inflammation. In some embodiments, the subject may include a human or a nonhuman mammal. Nonhuman mammals may include equines, canines, or felines.Type: GrantFiled: March 12, 2015Date of Patent: April 12, 2016Assignee: LivePet, LLCInventors: Ian Mitchell, Ayyappan Subbiah, Daniel David Bensimon
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Patent number: 9234396Abstract: Systems and methods for monitoring and characterizing fluids in a subterranean formation are provided. In one embodiment, a method for monitoring fluids in a well bore penetrating a subterranean formation is provided, the method comprising: determining an actual buoyed hookload of an apparatus at least partially disposed in the well bore wherein a first set of fluids are present therein; comparing the actual buoyed hookload to a calculated buoyed hookload of the apparatus, wherein the calculated buoyed hookload is based in part on the unbuoyed hookload of the apparatus, and the properties of a second set of fluids that are assumed to be present in the well bore; and determining at least one property of the first set of fluids based in part on the comparison of the actual buoyed hookload to the calculated buoyed hookload.Type: GrantFiled: January 28, 2013Date of Patent: January 12, 2016Assignee: Halliburton Energy Services, Inc.Inventors: Christopher Marland, Ian Mitchell, James Randolph Lovorn
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Publication number: 20150330167Abstract: Systems and methods for monitoring and characterizing fluids in a subterranean formation are provided. In one embodiment, a method for monitoring fluids in a well bore penetrating a subterranean formation is provided, the method comprising: determining an actual buoyed hookload of an apparatus at least partially disposed in the well bore wherein a first set of fluids are present therein; comparing the actual buoyed hookload to a calculated buoyed hookload of the apparatus, wherein the calculated buoyed hookload is based in part on the unbuoyed hookload of the apparatus, and the properties of a second set of fluids that are assumed to be present in the well bore; and determining at least one property of the first set of fluids based in part on the comparison of the actual buoyed hookload to the calculated buoyed hookload.Type: ApplicationFiled: January 28, 2013Publication date: November 19, 2015Inventors: Christopher Marland, Ian Mitchell, James Randolph Lovorn
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Publication number: 20150322775Abstract: Systems and methods for obtaining information about one or more fluids in a wellbore in a subterranean formation are disclosed herein. A fluid monitoring system comprises a fluid measurement device and a data system that receives a first and second set of data. A first set of data and second set of data may be obtained and compared to determine the location of one or more fluids in a wellbore in real time.Type: ApplicationFiled: January 28, 2013Publication date: November 12, 2015Inventors: Christopher MARLAND, Ian MITCHELL, James Randolph LOVORN
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Publication number: 20150315898Abstract: A fluid monitoring system comprises a data acquisition and control interface and one or more fluid measurement devices communicatively coupled to the data acquisition and control interface. The one or more fluid measurement devices are configured to detect amounts of fluids pumped into or exiting the well bore during cementing. The data acquisition and control interface receives a first set of data comprising calculated volumes and/or pressures of a flow of one or more fluids exiting a model well bore over a predetermined period of time based in part on a heat of reaction produced by the curing of a cement composition, and a second set of data comprising volumes and/or pressures of a flow of one or more fluids pumped into or exiting the well bore from the one or more fluid measurement devices. The data acquisition and control interface uses the first and second sets of data received to determine one or more characteristics of the cement composition.Type: ApplicationFiled: January 28, 2013Publication date: November 5, 2015Inventors: Christopher Marland, Ian Mitchell, James Randolph Lovorn
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Publication number: 20150300891Abstract: A distributed temperature sensor, a method of determining temperature, and a processing system to compute temperature are described. The sensor includes an optical fiber disposed in an area where temperature is to be measured, a primary light source to inject light into the optical fiber, and a secondary light source to inject light into the optical fiber. The sensor additionally includes a photodetector to detect backscatter light energy from the optical fiber the backscatter light energy including Stokes Raman scatter or anti-Stokes Raman scatter and primary Rayleigh scatter resulting from the primary light source and secondary Rayleigh scatter resulting from the secondary light source, and a processor to determine temperature based on a ratio of the Stokes Raman scatter or the anti-Stokes Raman scatter and a combination of the primary Rayleigh scatter and the secondary Rayleigh scatter.Type: ApplicationFiled: March 20, 2015Publication date: October 22, 2015Applicant: BAKER HUGHES INCORPORATEDInventors: Ian Mitchell, William Johnston, Ashwin Chandran
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Publication number: 20150292956Abstract: A distributed temperature sensor and a method of determining temperature are described. The distributed temperature sensor includes an optical fiber to filter or remove Stokes Raman scatter and prevent stimulated Raman scatter and a light source to inject light into the optical fiber. The distributed temperature sensor also includes a photodetector to detect light energy resulting from the light injected into the optical fiber, the light energy including anti-Stokes Raman scatter and Rayleigh scatter; and a processor to determine temperature based on a ratio of the anti-Stokes Raman scatter and the Rayleigh scatter.Type: ApplicationFiled: March 20, 2015Publication date: October 15, 2015Applicant: Baker Hughes IncorporatedInventors: Ian Mitchell, William Johnston, Ashwin Chandran
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Patent number: 9157317Abstract: According to aspects of the present disclosure, a magnetic ranging system is described herein. The magnetic ranging system may comprise a downhole apparatus tool (350) that is sized to couple to a drill string (375). The downhole apparatus (350) may be included, for example, near-bit within the bottom assembly (BHA). A transmitter (302) and a receiver (304) may be coupled to the downhole apparatus (350). The system may also comprise a power management system (308) coupled to the downhole apparatus (350). In certain embodiments, the power management system (308) may selectively provide power to the transmitter (302) from a first power source (316) or a second power source (318) based, at least in part, on an estimated distance to a target well.Type: GrantFiled: November 29, 2012Date of Patent: October 13, 2015Assignee: Halliburton Energy Services, Inc.Inventors: Ian Mitchell, Malcolm Upshall