Large-Signal Impedance-Based Modeling and Mitigation of Resonance of Converter-Grid Systems

Large-signal impedance of grid-connected converters can be used to predict resonance-generated distortions in converter-grid systems. Note that the large-signal impedance of a network represents its impedance response for different magnitudes of perturbation injected at its terminals. This paper pre...

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Veröffentlicht in:	IEEE transactions on sustainable energy 2019-07, Vol.10 (3), p.1439-1449
Hauptverfasser:	Shah, Shahil, Koralewicz, Przemyslaw, Gevorgian, Vahan, Wallen, Robb, Jha, Kapil, Mashtare, Dale, Burra, Rajni, Parsa, Leila
Format:	Artikel
Sprache:	eng
Schlagworte:	Computer simulation Converters Describing functions Distortion Doubly fed induction generators Electric potential Impedance impedance analysis Impedance measurement Induction generators Large-signal modeling Mathematical analysis Mitigation Perturbation Perturbation methods Phase locked loops Phase locked systems Phase transitions Power conversion POWER TRANSMISSION AND DISTRIBUTION Resonance Voltage voltage source converters wind power-plant stability
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container_title	IEEE transactions on sustainable energy
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creator	Shah, Shahil Koralewicz, Przemyslaw Gevorgian, Vahan Wallen, Robb Jha, Kapil Mashtare, Dale Burra, Rajni Parsa, Leila
description	Large-signal impedance of grid-connected converters can be used to predict resonance-generated distortions in converter-grid systems. Note that the large-signal impedance of a network represents its impedance response for different magnitudes of perturbation injected at its terminals. This paper presents large-signal impedance-based modeling and mitigation of resonance of grid-connected voltage source converters. Challenges of large-signal modeling because of the inapplicability of the small-signal approximation are addressed by leveraging the dominating influence of hard nonlinearities (such as pulsewidth modulation saturation and limiters) over soft nonlinearities (such as Park's transformations and phase-locked loop (PLL)) in shaping the large-signal behavior of the converter. The paper develops large-signal gains of hard nonlinearities using different types of describing functions. The paper shows that the large-signal impedance of a voltage source converter (VSC) can be shaped to reduce resonance-generated distortions by inserting limiters in the control system of the VSC. Developed large-signal impedance models are validated using numerical simulations of a VSC with dq current control and PLL. Large-signal impedance measurements of a commercial 1 MW VSC-based inverter and a medium-voltage doubly-fed induction generator with approximate 4 MW rating are presented to experimentally demonstrate the influence of the injected perturbation magnitude on the impedance response.
doi_str_mv	10.1109/TSTE.2019.2903478
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The paper shows that the large-signal impedance of a voltage source converter (VSC) can be shaped to reduce resonance-generated distortions by inserting limiters in the control system of the VSC. Developed large-signal impedance models are validated using numerical simulations of a VSC with dq current control and PLL. Large-signal impedance measurements of a commercial 1 MW VSC-based inverter and a medium-voltage doubly-fed induction generator with approximate 4 MW rating are presented to experimentally demonstrate the influence of the injected perturbation magnitude on the impedance response.</description><identifier>ISSN: 1949-3029</identifier><identifier>EISSN: 1949-3037</identifier><identifier>DOI: 10.1109/TSTE.2019.2903478</identifier><identifier>CODEN: ITSEAJ</identifier><language>eng</language><publisher>Piscataway: IEEE</publisher><subject>Computer simulation ; Converters ; Describing functions ; Distortion ; Doubly fed induction generators ; Electric potential ; Impedance ; impedance analysis ; Impedance measurement ; Induction generators ; Large-signal modeling ; Mathematical analysis ; Mitigation ; Perturbation ; Perturbation methods ; Phase locked loops ; Phase locked systems ; Phase transitions ; Power conversion ; POWER TRANSMISSION AND DISTRIBUTION ; Resonance ; Voltage ; voltage source converters ; wind power-plant stability</subject><ispartof>IEEE transactions on sustainable energy, 2019-07, Vol.10 (3), p.1439-1449</ispartof><rights>Copyright The Institute of Electrical and Electronics Engineers, Inc. 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(NREL), Golden, CO (United States)</creatorcontrib><title>Large-Signal Impedance-Based Modeling and Mitigation of Resonance of Converter-Grid Systems</title><title>IEEE transactions on sustainable energy</title><addtitle>TSTE</addtitle><description>Large-signal impedance of grid-connected converters can be used to predict resonance-generated distortions in converter-grid systems. Note that the large-signal impedance of a network represents its impedance response for different magnitudes of perturbation injected at its terminals. This paper presents large-signal impedance-based modeling and mitigation of resonance of grid-connected voltage source converters. Challenges of large-signal modeling because of the inapplicability of the small-signal approximation are addressed by leveraging the dominating influence of hard nonlinearities (such as pulsewidth modulation saturation and limiters) over soft nonlinearities (such as Park's transformations and phase-locked loop (PLL)) in shaping the large-signal behavior of the converter. The paper develops large-signal gains of hard nonlinearities using different types of describing functions. The paper shows that the large-signal impedance of a voltage source converter (VSC) can be shaped to reduce resonance-generated distortions by inserting limiters in the control system of the VSC. Developed large-signal impedance models are validated using numerical simulations of a VSC with dq current control and PLL. Large-signal impedance measurements of a commercial 1 MW VSC-based inverter and a medium-voltage doubly-fed induction generator with approximate 4 MW rating are presented to experimentally demonstrate the influence of the injected perturbation magnitude on the impedance response.</description><subject>Computer simulation</subject><subject>Converters</subject><subject>Describing functions</subject><subject>Distortion</subject><subject>Doubly fed induction generators</subject><subject>Electric potential</subject><subject>Impedance</subject><subject>impedance analysis</subject><subject>Impedance measurement</subject><subject>Induction generators</subject><subject>Large-signal modeling</subject><subject>Mathematical analysis</subject><subject>Mitigation</subject><subject>Perturbation</subject><subject>Perturbation methods</subject><subject>Phase locked loops</subject><subject>Phase locked systems</subject><subject>Phase transitions</subject><subject>Power conversion</subject><subject>POWER TRANSMISSION AND DISTRIBUTION</subject><subject>Resonance</subject><subject>Voltage</subject><subject>voltage source converters</subject><subject>wind power-plant stability</subject><issn>1949-3029</issn><issn>1949-3037</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2019</creationdate><recordtype>article</recordtype><sourceid>RIE</sourceid><recordid>eNo9kE9LAzEQxRdRsNR-APGy6Hlrktk_zVFLrYWKYOvJQ0iTSU1pk5qkQr-9u1Q6l5kHvzfwXpbdUjKklPDH5WI5GTJC-ZBxAmUzush6lJe8AALN5flm_DobxLgh7QBADaSXfc1lWGOxsGsnt_lst0ctncLiWUbU-ZvXuLVunUvXCpvsWibrXe5N_oHRuw7txNi7XwwJQzENVueLY0y4izfZlZHbiIP_3c8-XybL8Wsxf5_Oxk_zQkE9SgVK2RAOqqErKDnlo1rWjeYrhFqCNqZBkJpXpVEaWZuXEG6oJoYZqqCSJfSz-9NfH5MVUdmE6lt551AlQStC64a00MMJ2gf_c8CYxMYfQhs6CsbKEioKrGkpeqJU8DEGNGIf7E6Go6BEdF2LrmvRdS3-u249dyePRcQzP6prVnGAPzPOeas</recordid><startdate>20190701</startdate><enddate>20190701</enddate><creator>Shah, Shahil</creator><creator>Koralewicz, Przemyslaw</creator><creator>Gevorgian, Vahan</creator><creator>Wallen, Robb</creator><creator>Jha, Kapil</creator><creator>Mashtare, Dale</creator><creator>Burra, Rajni</creator><creator>Parsa, Leila</creator><general>IEEE</general><general>The Institute of Electrical and Electronics Engineers, Inc. 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Challenges of large-signal modeling because of the inapplicability of the small-signal approximation are addressed by leveraging the dominating influence of hard nonlinearities (such as pulsewidth modulation saturation and limiters) over soft nonlinearities (such as Park's transformations and phase-locked loop (PLL)) in shaping the large-signal behavior of the converter. The paper develops large-signal gains of hard nonlinearities using different types of describing functions. The paper shows that the large-signal impedance of a voltage source converter (VSC) can be shaped to reduce resonance-generated distortions by inserting limiters in the control system of the VSC. Developed large-signal impedance models are validated using numerical simulations of a VSC with dq current control and PLL. 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subjects	Computer simulation Converters Describing functions Distortion Doubly fed induction generators Electric potential Impedance impedance analysis Impedance measurement Induction generators Large-signal modeling Mathematical analysis Mitigation Perturbation Perturbation methods Phase locked loops Phase locked systems Phase transitions Power conversion POWER TRANSMISSION AND DISTRIBUTION Resonance Voltage voltage source converters wind power-plant stability
title	Large-Signal Impedance-Based Modeling and Mitigation of Resonance of Converter-Grid Systems
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