Patents by Inventor Jordi Estevadeordal
Jordi Estevadeordal 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: 10132688Abstract: In one embodiment, a system includes a multi-spectral pyrometry system configured to receive a broad wavelength band radiation signal from a turbine component, to split the broad wavelength band radiation signal into multiple narrow wavelength band radiation signals, to determine emissivity of the turbine component based on the narrow wavelength band radiation signals, and to detect spall on a surface of the turbine component based on the emissivity.Type: GrantFiled: December 17, 2010Date of Patent: November 20, 2018Assignee: General Electric CompanyInventors: Jordi Estevadeordal, Guanghua Wang, Lucy Joelle Summerville, Nirm Velumylum Nirmalan
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Patent number: 9599514Abstract: A multi-color pyrometry imaging system for a high-temperature asset includes at least one viewing port in optical communication with at least one high-temperature component of the high-temperature asset. The system also includes at least one camera device in optical communication with the at least one viewing port. The at least one camera device includes a camera enclosure and at least one camera aperture defined in the camera enclosure, The at least one camera aperture is in optical communication with the at least one viewing port. The at least one camera device also includes a multi-color filtering mechanism coupled to the enclosure. The multi-color filtering mechanism is configured to sequentially transmit photons within a first predetermined wavelength band and transmit photons within a second predetermined wavelength band that is different than the first predetermined wavelength band.Type: GrantFiled: January 24, 2013Date of Patent: March 21, 2017Assignee: General Electric CompanyInventors: Jordi Estevadeordal, Nirm Velumylum Nirmalan, Nilesh Tralshawala, Jeremy Clyde Bailey
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Patent number: 9250136Abstract: A pyrometry imaging system for monitoring a high-temperature asset which includes at least one component is provided. The system includes a lens element in optical communication with the at least one component. The lens element is configured to receive at least a portion of thermal radiation emitted from the at least one component. The system also includes a view limiting device positioned between the lens element and a dispersive element. The dispersive element is configured to split the at least a portion of thermal radiation emitted into a plurality of wavelengths. The system further includes at least one camera device in optical communication with the dispersive element. The at least one camera device is configured to receive at least one wavelength from the dispersive element.Type: GrantFiled: August 29, 2014Date of Patent: February 2, 2016Assignee: General Electric CompanyInventors: Jonas Patrik Richard Gustavsson, Vivek Venugopal Badami, Nilesh Tralshawala, Jordi Estevadeordal
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Patent number: 9046411Abstract: An optical sensor system includes a multi-color pyrometer in optical communication with a component. The pyrometer generates signals at least partially representative of radiation received from the component and from soot particles. The system includes at least one processing unit coupled to the pyrometer. The processing unit is programmed to receive the signals and distinguish portions of radiation received between at least two wavelength bands. The processing unit is also programmed to determine that a first portion of radiation within a first of the wavelength bands is representative of a temperature of soot particles and that a second portion of radiation within a second of the wavelength bands is representative of a temperature of the component. The processing unit is further programmed to filter out signals representative of the first portion of the radiation.Type: GrantFiled: November 14, 2011Date of Patent: June 2, 2015Assignee: General Electric CompanyInventors: Guanghua Wang, Anquan Wang, Nirm Velumylum Nirmalan, Jordi Estevadeordal, Sean Patrick Harper, Bradford Allen Lewandowski
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Publication number: 20140202130Abstract: A multi-color pyrometry imaging system for a high-temperature asset includes at least one viewing port in optical communication with at least one high-temperature component of the high-temperature asset. The system also includes at least one camera device in optical communication with the at least one viewing port. The at least one camera device includes a camera enclosure and at least one camera aperture defined in the camera enclosure, The at least one camera aperture is in optical communication with the at least one viewing port. The at least one camera device also includes a multi-color filtering mechanism coupled to the enclosure. The multi-color filtering mechanism is configured to sequentially transmit photons within a first predetermined wavelength band and transmit photons within a second predetermined wavelength band that is different than the first predetermined wavelength band.Type: ApplicationFiled: January 24, 2013Publication date: July 24, 2014Applicant: GENERAL ELECTRIC COMPANYInventors: Jordi Estevadeordal, Nirm Velumylum Nirmalan, Nilesh Tralshawala, Jeremy Clyde Bailey
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Patent number: 8629978Abstract: Three-dimensional surface illumination using curved laser sheets is described for optical flow measurements over conformal curved surfaces. The illumination method is applicable to many different optical-based flow visualization and measurement techniques, particularly for particle image velocimetry. An alignment sheet increases the accuracy of determining the position and movement of particles used in optical-base fluid flow techniques.Type: GrantFiled: January 5, 2011Date of Patent: January 14, 2014Assignee: The United States of America as represented by the Secretary of the Air ForceInventors: Jordi Estevadeordal, Christopher Marks, Rolf Sondergaard, James M. Wolff
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Publication number: 20130118183Abstract: An optical sensor system includes a multi-color pyrometer in optical communication with a component. The pyrometer generates signals at least partially representative of radiation received from the component and from soot particles. The system includes at least one processing unit coupled to the pyrometer. The processing unit is programmed to receive the signals and distinguish portions of radiation received between at least two wavelength bands. The processing unit is also programmed to determine that a first portion of radiation within a first of the wavelength bands is representative of a temperature of soot particles and that a second portion of radiation within a second of the wavelength bands is representative of a temperature of the component. The processing unit is further programmed to filter out signals representative of the first portion of the radiation.Type: ApplicationFiled: November 14, 2011Publication date: May 16, 2013Applicant: General Electric CompanyInventors: Guanghua Wang, Anquan Wang, Nirm Velumylum Nirmalan, Jordi Estevadeordal, Sean Patrick Harper, Bradford Allen Lewandowski
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Publication number: 20120170611Abstract: A smart radiation thermometry system including a turbine component is provided. The thermometry system also includes at least one smart real time processing sub-system electrically coupled to at least one detector array via at least one high-speed multi-channel ADC. The at least one smart real time processing sub-system calculates temperature and emissivity of the turbine component based upon a computed radiance temperature, reflection correction and multi-wavelength algorithm. The smart real time processing sub-system also transmits data indicative of the temperature, emissivity and other plurality of parameters within a pre-determined time period to a communication unit. The smart real time processing sub-system also outputs emergency alarm signals and controls either directly or via a controller one or more actuators coupled to the gas turbine based upon the data to ensure optimum operation of the gas turbine within safe operating limits.Type: ApplicationFiled: October 28, 2010Publication date: July 5, 2012Applicant: GENERAL ELECTRIC COMPANYInventors: Guanghua Wang, Nirm Velumylum Nirmalan, Jordi Estevadeordal, Sean Patrick Harper
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Publication number: 20120153157Abstract: In one embodiment, a system includes a multi-spectral pyrometry system configured to receive a broad wavelength band radiation signal from a turbine component, to split the broad wavelength band radiation signal into multiple narrow wavelength band radiation signals, to determine emissivity of the turbine component based on the narrow wavelength band radiation signals, and to detect spall on a surface of the turbine component based on the emissivity.Type: ApplicationFiled: December 17, 2010Publication date: June 21, 2012Applicant: General Electric CompanyInventors: Jordi Estevadeordal, Guanghua Wang, Lucy Joelle Summerville, Nirm Velumylum Nirmalan
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Publication number: 20110240858Abstract: In one embodiment, a system includes a turbine including multiple components in fluid communication with a working fluid that provides power or thrust. The system also includes an imaging system in optical communication with at least one component. The imaging system is configured to receive a broad wavelength band image of the at least one component during operation of the turbine, to split the broad wavelength band image into multiple narrow wavelength band images, and to output a signal indicative of a two-dimensional intensity map of each narrow wavelength band image.Type: ApplicationFiled: March 30, 2010Publication date: October 6, 2011Applicant: General Electric CompanyInventors: Jordi Estevadeordal, Nirm Velumylum Nirmalan, Guanghua Wang, Mohamed Sakami
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Publication number: 20060175561Abstract: A method of measuring fluid flow including the steps of providing a light source including at least one LED, providing an image detecting element and defining an illuminated measurement space with an optical element located between the measurement space and the image detecting element. The measurement space is located optically in-line between the light source and the image detecting element. The method further includes the steps of providing a fluid flow through the measurement space, the fluid flow including particles, and illuminating the measurement space with the light source to induce light extinction from the particles comprising shadow markers of the position of the particles within the fluid flow. The image detecting element is used to detect the shadow markers produced by the particles to record displacement of the particles as a function of time corresponding to movement of the fluid flow. In a further aspect, the light source includes plural LEDs emitting different colors.Type: ApplicationFiled: February 9, 2006Publication date: August 10, 2006Applicant: Innovative Scientific Solutions, Inc.Inventors: Jordi Estevadeordal, Larry Goss