Conference paper Open Access

Nonlinear Power Flow Control Design Methodology for Navy Electric Ship Microgrid Energy Storage Requirements

Wilson, D G; Weaver, W W; Robinett III, R D; Young, J; Glover, S F; Cook, M A; Markle, S; McCoy, T J


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    <subfield code="x">Doerry, N., Next Generation Integrated Power System NGIPS Technology Development Roadmap, Naval Sea Systems Command, Washington, D.C., Ser. 05D/349, 30 Nov. 2007.</subfield>
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    <subfield code="x">Glover, S. and Robinett III, R.D., Enabling Secure, Scalable Microgrids with High Penetration Renewables, Grand Challenge LDRD, SAND2011-0935P, 2011.</subfield>
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    <subfield code="x">Kuseian, J., "Naval Power Systems Technology Development Roadmap PMS 320," Naval Sea Systems Command, Washington, D. C., April 2013.</subfield>
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    <subfield code="x">Matthews, R.C., Weaver, W.W., Robinett III, R.D., and Wilson, D.G., Hamiltonian Methods of Modeling and Control of AC Microgrids with Spinning Machines and Inverters, International Journal of Electrical Power and Energy Systems, 98(2018) 315-322.</subfield>
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    <subfield code="x">Neely, J., Rashkin, L., Cook, M., Wilson, D.  and Glover, S., "Evaluation of Power Flow Control for an AllElectric Warship Power System with Pulsed Load Applications," in APEC 2106, Long Beach Convention &amp; Entertainment Center, Long Beach, CA, 2016.</subfield>
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    <subfield code="x">Robinett III, R.D. and Wilson, D.G., Nonlinear Power Flow Control Design:  Utilizing Exergy, Entropy, Static and Dynamic Stability, and Lyapunov Analysis, Springer-Verlag London Ltd., August 2011, ISBN 978-0-85729822-5.</subfield>
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    <subfield code="x">Weaver, W.W., Robinett III, R.D., Wilson, D.G. and Matthews, R.C., "Meta-Stability Control of Pulse Power Loads using the Hamiltonian Surface Shaping Method," in Special Topics Journal on Electric Ship, IEEE Transactions on Energy Conversion, DOI 10.1109/TEC.2017.2652980, January 2017.</subfield>
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    <subfield code="x">Weaver, W. W., Robinett III, R.D., Parker, G. and Wilson, D.G., "Distributed Control and Energy Storage Requirements of Networked DC Microgrids," Control Engineering Practice, vol. 44, pp. 10-19, 2015.</subfield>
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    <subfield code="x">Weaver, W.W., Robinett III, R.D., Parker, G. G. and Wilson, D.G., "Energy Storage Requirements of DC Microgrids with High Penetration Renewables Under Droop Control," International Journal of Electrical Power and Energy Systems, vol. 68, pp. 203-209, 2015.</subfield>
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    <subfield code="x">Wilson, D. G., Neely, J., Cook, M. Glover, S., Young, J. and Robinett III, R. D., "Hamiltonian Control Design for DC Microgrids with Stochastic Sources and Loads with Applications," International Symposium on Power Electronics, Electrical Drives, Automation and Motion, SPEEDAM 2014, Ischia, Italy.</subfield>
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    <subfield code="x">Wilson, D., Robinett III, R. D., Weaver, W., Byrne, R. and Young, J., "Nonlinear Power Flow Control Design of High Penetration Renewable Sources for AC Inverter Based Microgrids," International Symposium on Power Electronics, Electrical Drives, Automation and Motion, SPEEDAM 2016, AnaCapri, Capri Island, Italy.</subfield>
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    <subfield code="x">Wilson, D.G., Weaver, W.W., Robinett III, R.D., Glover, S.F., "Nonlinear Power Flow Control Design for Networked AC/DC based Microgrid Systems," 2018 IEEE American Control Conference, Milwaukee, WI, June 27-29, 2018.</subfield>
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    <subfield code="x">Young, J., Optizelle: An open source software library designed to solve general purpose nonlinear optimization problems, 2014, www.optimojoe.com, Open source software.</subfield>
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    <subfield code="x">Young, J., Cook, M.A., Wilson, D.G., A Predictive Engine for On-Line Optimal Microgrid Control, 2017 IEEE Electric Ship Technologies Symposium, ESTS 2017, February 2017, Arlington, Virginia, August 15-17, 2017.</subfield>
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    <subfield code="a">Hierarchical control</subfield>
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    <subfield code="a">Nonlinear Power Flow Control Design Methodology for Navy Electric Ship Microgrid Energy Storage Requirements</subfield>
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    <subfield code="a">&lt;p&gt;As part of the U.S. Navy&amp;rsquo;s continued commitment to protecting U.S. interests at home and abroad, the Navy is investing in the development of new technologies that broaden U.S. warship capabilities and maintain U.S. naval superiority. NAVSEA is developing power systems technologies for the Navy to realize an all-electric warship. New nonlinear power system controls approaches are being developed to improve system performance in light of new electrically powered weaponry that behave as pulsed-loads. Advancements include the identification of pulsed-load profiles that identify Energy Storage System (ESS) requirements. A dynamic optimization engine has been developed and serves as the feedforward receding horizon control portion of the Hamiltonian Surface Shaping and Power Flow Control (HSSPFC) feedback controls for ESS networked microgrid system. A Coalition Warfare Program (CWP) test scenario was selected. The CWP is defined with a Reduced Order Model (ROM) that includes; generation, ESS, and mission pulsed-loads. Several numerical simulation studies were conducted. The CWP scenario is bounded by a baseline mission load local ESS contrasted with no ESS full nonlinear metastable boundaries. The main goal is to minimize ESS size and weight while maintaining power system performance. &amp;nbsp;This paper focuses on the control and optimization of ESS as an integral part of supporting critical mission loads and real-time control algorithm development to improve future energy efficiency for multi-mission activities.&amp;nbsp;&lt;/p&gt;</subfield>
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