Patents by Inventor Wayne W. Weaver
Wayne W. Weaver 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: 12051906Abstract: A DC bus collection system for a wind farm reduces the overall required number of converters and minimizes the energy storage system requirements. The DC bus collection system implements a power phasing control method between wind turbines that filters the variations and improves power quality. The phasing control method takes advantage of a novel power packet network concept with nonlinear power flow control design techniques that guarantees both stable and enhanced dynamic performance.Type: GrantFiled: March 2, 2022Date of Patent: July 30, 2024Assignees: National Technology & Engineering Solutions of Sandia, LLC, Michigan Technological UniversityInventors: Wayne W. Weaver, David G. Wilson, Rush D. Robinett, III
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Publication number: 20230283079Abstract: A DC bus collection system for a wind farm reduces the overall required number of converters and minimizes the energy storage system requirements. The DC bus collection system implements a power phasing control method between wind turbines that filters the variations and improves power quality. The phasing control method takes advantage of a novel power packet network concept with nonlinear power flow control design techniques that guarantees both stable and enhanced dynamic performance.Type: ApplicationFiled: March 2, 2022Publication date: September 7, 2023Inventors: Wayne W. Weaver, David G. Wilson, Rush D. Robinett, III
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Publication number: 20230265822Abstract: One of the biggest challenges for all renewable energy sources (RES) is that they are variable power generators which will require reactive power or energy storage systems (ESS) to provide reliable power quality (ideally power factor of one) at the power grid generation side. The present invention is directed to a power packet network (PPN) for integrating wave energy converter (WEC) arrays into microgrids. Specifically, an array of WECs can be physically positioned such that the incoming regular waves will produce an output emulating an N-phase AC system such that the PPN output power is constant. ESS requirements are thereby minimized whilst maintaining grid stability with high power quality. This will enable RES integration onto a future smart grid for large-scale adoption and cost reduction while preserving high efficiency, reliability, and resiliency.Type: ApplicationFiled: February 18, 2022Publication date: August 24, 2023Inventors: David G. Wilson, Raymond H. Byrne, Steven F. Glover, Tu Anh Nguyen, Rush D. Robinett, III, Wayne W. Weaver, Madelyn G. Veurink
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Patent number: 11725622Abstract: One of the biggest challenges for all renewable energy sources (RES) is that they are variable power generators which will require reactive power or energy storage systems (ESS) to provide reliable power quality (ideally power factor of one) at the power grid generation side. The present invention is directed to a power packet network (PPN) for integrating wave energy converter (WEC) arrays into microgrids. Specifically, an array of WECs can be physically positioned such that the incoming regular waves will produce an output emulating an N-phase AC system such that the PPN output power is constant. ESS requirements are thereby minimized whilst maintaining grid stability with high power quality. This will enable RES integration onto a future smart grid for large-scale adoption and cost reduction while preserving high efficiency, reliability, and resiliency.Type: GrantFiled: February 18, 2022Date of Patent: August 15, 2023Assignees: National Technology & Engineering Solutions of Sandia, LLC, Michigan Technological UniversityInventors: David G. Wilson, Raymond H. Byrne, Steven F. Glover, Tu Anh Nguyen, Rush D. Robinett, III, Wayne W. Weaver, Madelyn G. Veurink
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Patent number: 11536243Abstract: A nonlinear control design technique capitalizes on a wave energy converter comprising a shaped buoy having a variable geometry wave energy. For example, the shaped buoy can have an hourglass (HG) geometry having a variable cone or steepness angle. The HG buoy is assumed to operate in the heave motion of the wave. The unique interaction between the HG buoy and the wave creates a nonlinear cubic storage effect that produces actual energy storage or reactive power during operation. A multi-frequency Bretschneider spectrum wave excitation input was simulated for the HG design both with constant and varying steepness angle profiles which demonstrated further increased power generation with changing sea states for the variable design.Type: GrantFiled: April 19, 2022Date of Patent: December 27, 2022Assignee: National Technology & Engineering Solutions of Sandia, LLCInventors: David G. Wilson, Rush D. Robinett, III, Wayne W. Weaver, Steven F. Glover
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Publication number: 20220252039Abstract: A nonlinear control design technique capitalizes on a wave energy converter comprising a shaped buoy having a variable geometry wave energy. For example, the shaped buoy can have an hourglass (HG) geometry having a variable cone or steepness angle. The HG buoy is assumed to operate in the heave motion of the wave. The unique interaction between the HG buoy and the wave creates a nonlinear cubic storage effect that produces actual energy storage or reactive power during operation. A multi-frequency Bretschneider spectrum wave excitation input was simulated for the HG design both with constant and varying steepness angle profiles which demonstrated further increased power generation with changing sea states for the variable design.Type: ApplicationFiled: April 19, 2022Publication date: August 11, 2022Inventors: David G. Wilson, Rush D. Robinett, III, Wayne W. Weaver, Steven F. Glover
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Patent number: 11316363Abstract: Pulsed power loads (PPLs) are highly non-linear and can cause significant stability and power quality issues in an electrical microgrid. According to the present invention, many of these issues can be mitigated by an Energy Storage System (ESS) that offsets the PPL. The ESS can maintain a constant bus voltage and decouple the generation sources from the PPL. For example, the ESS specifications can be obtained with an ideal, band-limited hybrid battery and flywheel system.Type: GrantFiled: September 30, 2020Date of Patent: April 26, 2022Assignees: National Technology & Engineering Solutions of Sandia, LLC, Michigan Technological UniversityInventors: Wayne W. Weaver, Rush D. Robinett, III, David G. Wilson
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Publication number: 20210119452Abstract: Pulsed power loads (PPLs) are highly non-linear and can cause significant stability and power quality issues in an electrical microgrid. According to the present invention, many of these issues can be mitigated by an Energy Storage System (ESS) that offsets the PPL. The ESS can maintain a constant bus voltage and decouple the generation sources from the PPL. For example, the ESS specifications can be obtained with an ideal, band-limited hybrid battery and flywheel system.Type: ApplicationFiled: September 30, 2020Publication date: April 22, 2021Inventors: Wayne W. Weaver, Rush D. Robinett, III, David G. Wilson
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Publication number: 20210079918Abstract: This invention is directed to exergy surface shaping and thermodynamic flow control (ESSTFC) for electro-mechanical-thermal (EMT) systems (i.e., irreversible work processes with heat and mass flows). Extended irreversible thermodynamics are utilized to produce consistent thermal equations-of-motion that directly include the exergy destruction terms. A simplified EMT system that models the EMT dynamics of a ship equipped with a railgun is used to demonstrate the application of ESSTFC for designing high performance, stable nonlinear controllers for EMT systems.Type: ApplicationFiled: September 12, 2020Publication date: March 18, 2021Inventors: Wayne W. Weaver, Rush D. Robinett, III, David G. Wilson
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Patent number: 10666054Abstract: A method for designing feedforward and feedback controllers for integration of stochastic sources and loads into a nonlinear networked AC/DC microgrid system is provided. A reduced order model for general networked AC/DC microgrid systems is suitable for HSSPFC control design. A simple feedforward steady state solution is utilized for the feedforward controls block. Feedback control laws are provided for the energy storage systems. A HSSPFC controller design is implemented that incorporates energy storage systems that provides static and dynamic stability conditions for both the DC random stochastic input side and the AC random stochastic load side. Transient performance was investigated for the feedforward/feedback control case. Numerical simulations were performed and provided power and energy storage profile requirements for the networked AC/DC microgrid system overall performance.Type: GrantFiled: May 17, 2018Date of Patent: May 26, 2020Assignees: National Technology & Engineering Solutions of Sandia, LLC, Michigan Technological UniversityInventors: David G. Wilson, Rush D. Robinett, III, Wayne W. Weaver, Steven F. Glover
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Publication number: 20180366952Abstract: A method for designing feedforward and feedback controllers for integration of stochastic sources and loads into a nonlinear networked AC/DC microgrid system is provided. A reduced order model for general networked AC/DC microgrid systems is suitable for HSSPFC control design. A simple feedforward steady state solution is utilized for the feedforward controls block. Feedback control laws are provided for the energy storage systems. A HSSPFC controller design is implemented that incorporates energy storage systems that provides static and dynamic stability conditions for both the DC random stochastic input side and the AC random stochastic load side. Transient performance was investigated for the feedforward/feedback control case. Numerical simulations were performed and provided power and energy storage profile requirements for the networked AC/DC microgrid system overall performance.Type: ApplicationFiled: May 17, 2018Publication date: December 20, 2018Inventors: David G. Wilson, Rush D. Robinett, III, Wayne W. Weaver, Steven F. Glover
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Patent number: 10090764Abstract: A Hamiltonian surface shaping power flow control (HSSPFC) method is used to analyze the meta-stability and adjust pulsed power loads on a DC electric power distribution network. Pulsed power loads are nonlinear, time-variant systems that cause nonlinear limit-cycles. During the on periods of a pulsed load, the system can be in an unstable state and is damped back to stability during the off state of the load. Therefore, over the entire period of the pulse the system may only be assessed as meta-stable. As shown through simulation, HIL and hardware results, the HSSPFC method is more accurate than the other small-signal approaches, such as Eigenvalues, Nyquist, and Floquet theory, and can reveal important details about the transient responses and performance.Type: GrantFiled: January 10, 2018Date of Patent: October 2, 2018Assignees: National Technology & Engineering Solutions of Sandia, LLC, Michigan Technological UniversityInventors: David G. Wilson, Wayne W. Weaver, Rush D. Robinett, III, Ronald Matthews, Steven F. Glover