Patents by Inventor Johanna Haggstrom

Johanna Haggstrom 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).

  • Patent number: 9441149
    Abstract: In or near real-time monitoring of fluids can take place using an opticoanalytical device that is configured for monitoring the fluid. Fluids can be monitored prior to or during their introduction into a subterranean formation using the opticoanalytical devices. Produced fluids from a subterranean formation can be monitored in a like manner. The methods can comprise providing at least one source material; combining the at least one source material with a base fluid to form a treatment fluid; and monitoring a characteristic of the treatment fluid using a first opticoanalytical device that is in optical communication with a flow pathway for transporting the treatment fluid.
    Type: Grant
    Filed: August 5, 2011
    Date of Patent: September 13, 2016
    Assignee: Halliburton Energy Services, Inc.
    Inventors: Robert P. Freese, Christopher M. Jones, Michael T. Pelletier, Rory D. Daussin, David M. Loveless, Johanna Haggstrom
  • Patent number: 9297254
    Abstract: In or near real-time monitoring of fluids can take place using an opticoanalytical device that is configured for monitoring the fluid. Fluids can be monitored prior to or during their introduction into a subterranean formation using the opticoanalytical devices. Produced fluids from a subterranean formation can be monitored in a like manner. The methods can comprise providing a treatment fluid comprising a base fluid and at least one additional component; introducing the treatment fluid into a subterranean formation; allowing the treatment fluid to perform a treatment operation in the subterranean formation; and monitoring a characteristic of the treatment fluid or a formation fluid using at least a first opticoanalytical device within the subterranean formation, during a flow back of the treatment fluid produced from the subterranean formation, or both.
    Type: Grant
    Filed: August 5, 2011
    Date of Patent: March 29, 2016
    Assignee: Halliburton Energy Services, Inc.
    Inventors: Robert P. Freese, Christopher M. Jones, Michael T. Pelletier, Rory D. Daussin, David M. Loveless, Johanna Haggstrom
  • Patent number: 9256701
    Abstract: Techniques for modeling a wellbore fluid that includes a base fluid and one or more fluid additives includes identifying a target viscosity profile of the wellbore fluid; determining an initial set of values of the fluid additives that are based at least in part on the target viscosity profile; determining, with one or more non-linear predictive models, a computed viscosity profile of the wellbore fluid and a computed set of values of the fluid additives based, at least in part, on the initial set of values of the fluid additives; comparing the computed viscosity profile and at least one of the computed set of values with a specified criteria of the wellbore fluid; and preparing, based on the comparison, an output including the computed viscosity profile and at least one of the computed set of values of a resultant wellbore fluid.
    Type: Grant
    Filed: January 7, 2013
    Date of Patent: February 9, 2016
    Assignee: Halliburton Energy Services, Inc.
    Inventors: Dingding Chen, David L. Perkins, Christopher Michael Jones, Li Gao, Lucas Fontenelle, Johanna Haggstrom
  • Patent number: 9217705
    Abstract: The binding state of ionic materials, including metal ions, in a fluid phase can be determined using an integrated computational element. Methods for determining the binding state of an ionic material in a fluid phase can comprise optically interacting electromagnetic radiation with an ionic material and one or more integrated computational elements, the ionic material being located in a fluid phase while being optically interacted with the electromagnetic radiation; and determining one or more binding states of the ionic material in the fluid phase, using the one or more integrated computational elements.
    Type: Grant
    Filed: September 30, 2013
    Date of Patent: December 22, 2015
    Assignee: Halliburton Energy Services, Inc.
    Inventors: Aaron Gene Russell, Johanna Haggstrom, Robert P. Freese
  • Publication number: 20150346084
    Abstract: The binding state of ionic materials, including metal ions, in a fluid phase can be determined using an integrated computational element. Methods for determining the binding state of an ionic material in a fluid phase can comprise optically interacting electromagnetic radiation with an ionic material and one or more integrated computational elements, the ionic material being located in a fluid phase while being optically interacted with the electromagnetic radiation; and determining one or more binding states of the ionic material in the fluid phase, using the one or more integrated computational elements.
    Type: Application
    Filed: September 30, 2013
    Publication date: December 3, 2015
    Inventors: Aaron Gene Russell, Johanna Haggstrom, Robert P. Freese
  • Patent number: 9103720
    Abstract: Various molecular characteristics of a polymer may be determined using an integrated computational element to assay the polymer. Methods for assaying a polymer can comprise optically interacting electromagnetic radiation with a polymer and an integrated computational element; and determining a molecular characteristic of the polymer, using the integrated computational element. The molecular characteristic of the polymer may be used to determine a bulk characteristic of a fluid phase in which the polymer may be disposed.
    Type: Grant
    Filed: July 10, 2013
    Date of Patent: August 11, 2015
    Assignee: Halliburton Energy Services, Inc.
    Inventors: Aaron Gene Russell, Johanna Haggstrom, Robert P. Freese
  • Patent number: 8997860
    Abstract: In or near real-time monitoring of fluids can take place using an opticoanalytical device that is configured for monitoring the fluid. Fluids can be monitored prior to or during their introduction into a subterranean formation using the opticoanalytical devices. Produced fluids from a subterranean formation can be monitored in a like manner. The methods can comprise providing at least one fracturing fluid component; combining the at least one fracturing fluid component with a base fluid to form a fracturing fluid; and monitoring a characteristic of the fracturing fluid using a first opticoanalytical device that is in optical communication with a flow pathway for transporting the fracturing fluid.
    Type: Grant
    Filed: August 5, 2011
    Date of Patent: April 7, 2015
    Assignee: Halliburton Energy Services, Inc.
    Inventors: Robert P. Freese, Christopher M. Jones, Michael T. Pelletier, Rory D. Daussin, David M. Loveless, Johanna Haggstrom
  • Patent number: 8960294
    Abstract: In or near real-time monitoring of fluids can take place using an opticoanalytical device that is configured for monitoring the fluid. Fluids can be monitored prior to or during their introduction into a subterranean formation using the opticoanalytical devices. Produced fluids from a subterranean formation can be monitored in a like manner. The methods can comprise providing a fracturing fluid comprising a base fluid and at least one fracturing fluid component; introducing the fracturing fluid into a subterranean formation at a pressure sufficient to create or enhance at least one fracture therein, thereby performing a fracturing operation in the subterranean formation; and monitoring a characteristic of the fracturing fluid or a formation fluid using at least a first opticoanalytical device within the subterranean formation, during a flow back of the fracturing fluid produced from the subterranean formation, or both.
    Type: Grant
    Filed: August 5, 2011
    Date of Patent: February 24, 2015
    Assignee: Halliburton Energy Services, Inc.
    Inventors: Robert P. Freese, Christopher M. Jones, Michael T. Pelletier, Rory D. Daussin, David M. Loveless, Johanna Haggstrom
  • Publication number: 20150015884
    Abstract: Various molecular characteristics of a polymer may be determined using an integrated computational element to assay the polymer. Methods for assaying a polymer can comprise optically interacting electromagnetic radiation with a polymer and an integrated computational element; and determining a molecular characteristic of the polymer, using the integrated computational element. The molecular characteristic of the polymer may be used to determine a bulk characteristic of a fluid phase in which the polymer may be disposed.
    Type: Application
    Filed: July 10, 2013
    Publication date: January 15, 2015
    Inventors: Aaron Gene Russell, Johanna Haggstrom, Robert P. Freese
  • Publication number: 20140195215
    Abstract: Techniques for modeling a wellbore fluid that includes a base fluid and one or more fluid additives includes identifying a target viscosity profile of the wellbore fluid; determining an initial set of values of the fluid additives that are based at least in part on the target viscosity profile; determining, with one or more non-linear predictive models, a computed viscosity profile of the wellbore fluid and a computed set of values of the fluid additives based, at least in part, on the initial set of values of the fluid additives; comparing the computed viscosity profile and at least one of the computed set of values with a specified criteria of the wellbore fluid; and preparing, based on the comparison, an output including the computed viscosity profile and at least one of the computed set of values of a resultant wellbore fluid.
    Type: Application
    Filed: January 7, 2013
    Publication date: July 10, 2014
    Applicant: HALLIBURTON ENERGY SERVICES, INC.
    Inventors: Dingding Chen, David L. Perkins, Christopher Michael Jones, Li Gao, Lucas Fontenelle, Johanna Haggstrom
  • Publication number: 20130312956
    Abstract: Spectroscopic analyses of complex mixtures within a fluid phase can oftentimes be complicated by spectral overlap, making it difficult to analyze for each constituent therein. Methods for analyzing a treatment fluid can comprise: providing a treatment fluid comprising a fluid phase and one or more constituents therein; exposing the treatment fluid to electromagnetic radiation in a spectral region where the fluid phase optically interacts with the electromagnetic radiation, so as to acquire a spectrum of the fluid phase; analyzing the spectrum of the fluid phase to determine at least one property of the treatment fluid, the at least one property of the treatment fluid being selected from the group consisting of a concentration of at least one constituent in the treatment fluid, at least one characteristic of the treatment fluid, and any combination thereof; and introducing the treatment fluid into a subterranean formation.
    Type: Application
    Filed: May 24, 2012
    Publication date: November 28, 2013
    Applicant: Halliburton Energy Services, Inc.
    Inventors: Melissa Weston, Kurt Hoeman, Robert P. Freese, Johanna Haggstrom
  • Publication number: 20130314695
    Abstract: Spectroscopic analyses of complex mixtures within the matrix of a sample can oftentimes be complicated by spectral overlap of the constituents and/or the matrix, making it difficult to quantitatively assay each constituent therein. Methods for analyzing a sample can comprise: providing a sample comprising a matrix and one or more constituents therein; exposing the sample to electromagnetic radiation in a spectral region where the matrix optically interacts with the electromagnetic radiation, so as to acquire a spectrum of the matrix; and analyzing the spectrum of the matrix within a wavelength range where the matrix has a molar extinction coefficient of at least about 0.01 M?1mm?1 to determine at least one property of the sample, the at least one property of the sample being selected from the group consisting of a concentration of at least one constituent in the sample, at least one characteristic of the sample, and any combination thereof.
    Type: Application
    Filed: May 24, 2012
    Publication date: November 28, 2013
    Applicant: Halliburton Energy Services, Inc.
    Inventors: Melissa Weston, Kurt Hoeman, Robert P. Freese, Johanna Haggstrom
  • Publication number: 20130031970
    Abstract: In or near real-time monitoring of fluids can take place using an opticoanalytical device that is configured for monitoring the fluid. Fluids can be monitored prior to or during their introduction into a subterranean formation using the opticoanalytical devices. Produced fluids from a subterranean formation can be monitored in a like manner. The methods can comprise providing at least one fracturing fluid component; combining the at least one fracturing fluid component with a base fluid to form a fracturing fluid; and monitoring a characteristic of the fracturing fluid using a first opticoanalytical device that is in optical communication with a flow pathway for transporting the fracturing fluid.
    Type: Application
    Filed: August 5, 2011
    Publication date: February 7, 2013
    Applicant: Halliburton Energy Services, Inc.
    Inventors: Robert P. Freese, Christopher M. Jones, Michael T. Pelletier, Rory D. Daussin, David M. Loveless, Johanna Haggstrom
  • Publication number: 20130032344
    Abstract: In or near real-time monitoring of fluids can take place using an opticoanalytical device that is configured for monitoring the fluid. Fluids can be monitored prior to or during their introduction into a subterranean formation using the opticoanalytical devices. Produced fluids from a subterranean formation can be monitored in a like manner. The methods can comprise providing a treatment fluid comprising a base fluid and at least one additional component; introducing the treatment fluid into a subterranean formation; allowing the treatment fluid to perform a treatment operation in the subterranean formation; and monitoring a characteristic of the treatment fluid or a formation fluid using at least a first opticoanalytical device within the subterranean formation, during a flow back of the treatment fluid produced from the subterranean formation, or both.
    Type: Application
    Filed: August 5, 2011
    Publication date: February 7, 2013
    Applicant: Halliburton Energy Services, Inc.
    Inventors: Robert P. Freese, Christopher M. Jones, Michael T. Pelletier, Rory D. Daussin, David M. Loveless, Johanna Haggstrom
  • Publication number: 20130031972
    Abstract: In or near real-time monitoring of fluids can take place using an opticoanalytical device that is configured for monitoring the fluid. Fluids can be monitored prior to or during their introduction into a subterranean formation using the opticoanalytical devices. Produced fluids from a subterranean formation can be monitored in a like manner. The methods can comprise providing water from a water source; monitoring a characteristic of the water using a first opticoanalytical device that is in optical communication with a flow pathway for transporting the water; and introducing the water into a subterranean formation.
    Type: Application
    Filed: August 5, 2011
    Publication date: February 7, 2013
    Applicant: Halliburton Energy Services, Inc.
    Inventors: Robert P. Freese, David M. Loveless, Rory D. Daussin, Christopher M. Jones, Melissa C. Weston, Lucas K. Fontenelle, Johanna Haggstrom
  • Publication number: 20130032334
    Abstract: In or near real-time monitoring of fluids can take place using an opticoanalytical device that is configured for monitoring the fluid. Fluids can be monitored prior to or during their introduction into a subterranean formation using the opticoanalytical devices. Produced fluids from a subterranean formation can be monitored in a like manner. The methods can comprise providing at least one source material; combining the at least one source material with a base fluid to form a treatment fluid; and monitoring a characteristic of the treatment fluid using a first opticoanalytical device that is in optical communication with a flow pathway for transporting the treatment fluid.
    Type: Application
    Filed: August 5, 2011
    Publication date: February 7, 2013
    Applicant: Halliburton Energy Services, Inc.
    Inventors: Robert P. Freese, Christopher M. Jones, Michael T. Pelletier, Rory D. Daussin, David M. Loveless, Johanna Haggstrom
  • Publication number: 20130031971
    Abstract: In or near real-time monitoring of fluids can take place using an opticoanalytical device that is configured for monitoring the fluid. Fluids can be monitored prior to or during their introduction into a subterranean formation using the opticoanalytical devices. Produced fluids from a subterranean formation can be monitored in a like manner. The methods can comprise providing a fracturing fluid comprising a base fluid and at least one fracturing fluid component; introducing the fracturing fluid into a subterranean formation at a pressure sufficient to create or enhance at least one fracture therein, thereby performing a fracturing operation in the subterranean formation; and monitoring a characteristic of the fracturing fluid or a formation fluid using at least a first opticoanalytical device within the subterranean formation, during a flow back of the fracturing fluid produced from the subterranean formation, or both.
    Type: Application
    Filed: August 5, 2011
    Publication date: February 7, 2013
    Applicant: Halliburton Energy Services, Inc.
    Inventors: Robert P. Freese, Christopher M. Jones, Michael T. Pelletier, Rory D. Daussin, David M. Loveless, Johanna Haggstrom
  • Publication number: 20130032545
    Abstract: In or near real-time monitoring of fluids can take place using an opticoanalytical device that is configured for monitoring the fluid. The opticoanalytical devices can be used for monitoring various processes in which fluids are used. The methods can comprise providing a fluid in a fluid stream and monitoring a characteristic of the fluid using a first opticoarialytical device that is in optical communication with the fluid in the fluid stream.
    Type: Application
    Filed: August 5, 2011
    Publication date: February 7, 2013
    Inventors: Robert P. Freese, Christopher M. Jones, Michael T. Pelletier, Rory D. Daussin, Valerie J. Yeager, Melissa C. Weston, Lucas K. Fontenelle, David M. Loveless, Johanna Haggstrom, Cory D. Hillis
  • Publication number: 20130035262
    Abstract: Determining the microorganism load of a substance may be conducted readily using one or more integrated computational elements. By determining a substance's microorganism load, the substance's suitability for a variety of applications may be ascertained. Methods for determining the microorganism load of a substance using one or more integrated computational elements can comprise: providing a substance comprising a plurality of viable microorganisms; exposing the substance to a pulsed light source for a sufficient length of time to form at least some non-viable microorganisms; and determining a microorganism load of the substance using one or more integrated computational elements.
    Type: Application
    Filed: July 10, 2012
    Publication date: February 7, 2013
    Inventors: Robert P. Freese, Johanna A. Haggstrom, Jason E. Bryant, Rory D. Daussin
  • Publication number: 20120205303
    Abstract: Systems and methods for treating aqueous fluids and their associated methods of use are disclosed. In one embodiment, a system for treating an untreated aqueous fluid with a first concentration of a contaminant to produce a treated water with a second concentration of the contaminant, is provided, wherein the system comprises a chemical treatment subsystem comprising a chemical agent, wherein the chemical treatment subsystem precipitates at least a portion of the contaminant from the aqueous fluid; and a mechanical treatment subsystem comprising a centrifugal separator, wherein the mechanical treatment subsystem removes at least a portion of the precipitated contaminant from the aqueous fluid.
    Type: Application
    Filed: April 23, 2012
    Publication date: August 16, 2012
    Inventors: Randy Rosine, Johanna Haggstrom, Michael McCabe