nach oben

Erschienen in:

2017 | OriginalPaper | Buchkapitel

6. Droop-Free Distributed Control of AC Microgrids

verfasst von : Ali Bidram, Vahidreza Nasirian, Ali Davoudi, Frank L. Lewis

Erschienen in: Cooperative Synchronization in Distributed Microgrid Control

Verlag: Springer International Publishing

Einloggen

Aktivieren Sie unsere intelligente Suche, um passende Fachinhalte oder Patente zu finden.

search-config

KI-gestützte Suche

Aus

Abstract

The droop mechanism, or its variations [1‐9], is a common decentralized approach to realize the primary control, although alternative methods (e.g., virtual oscillator control [10‐13]) are emerging. It emulates virtual inertia for AC systems and mimics the role of governors in traditional synchronous generators [14].

Sie haben noch keine Lizenz? Dann Informieren Sie sich jetzt über unsere Produkte:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

Jetzt informieren

Vorheriges Kapitel Multi-objective and Adaptive Distributed Control of AC Microgrids

Nächstes Kapitel Cooperative Control for DC Microgrids

Nur mit Berechtigung zugänglich

Wu D, Tang F, Guerrero JM, Vasquez JC (2014) Autonomous control of distributed generation and storage to coordinate P/Q sharing in islanded microgrids—an approach beyond droop control. In: Proceedings of IEEE international energy conference, pp 983–988

Ashabani SM, Mohamed YARI (2013) General interface for power management of micro-grids using nonlinear cooperative droop control. IEEE Trans Power Syst 28:2929–2941CrossRef

Hu J, Zhu J, Dorrell DG, Guerrero JM (2014) Virtual flux droop method—a new control strategy of inverters in microgrids. IEEE Trans Power Electron 29:4704–4711CrossRef

Mohamed YAI, El-Saadany EF (2008) Adaptive decentralized droop controller to preserve power sharing stability of paralleled inverters in distributed generation microgrids. IEEE Trans Power Electron 23:2806–2816CrossRef

He J, Li YW (2011) Analysis, design, and implementation of virtual impedance for power electronics interfaced distributed generation. IEEE Trans Ind Appl 41:2525–2538CrossRef

Simpson-Porco JW, Dorfler F, Bullo F (2013) Voltage stabilization in microgrids via quadratic droop control. In: IEEE 52nd Annual conference decision and control, pp 7582–7589

Mahmood H, Michaelson D, Jiang J (2015) Accurate reactive power sharing in an islanded microgrid using adaptive virtual impedances. IEEE Trans Power Electron 30(3):1605–1617CrossRef

Han H, Liu Y, Sun Y, Su M, Guerrero JM (2015) An improved droop control strategy for reactive power sharing in islanded microgrid. IEEE Trans Power Electron 30(6):3133–3141CrossRef

Lee CT, Chu CC, Cheng PT (2013) A new droop control method for the autonomous operation for distribute energy resource interface converters. IEEE Trans Power Electron 28:1980–1993CrossRef

10.

Dhople SV, Johnson BB, Hamadeh AO (2013) Virtual oscillator control for voltage source inverters. In: Proceedings of 51st annual Allerton conference, pp 1359–1363

11.

Johnson BB, Dhople SV, Hamadeh AO, Krein PT (2014) Synchronization of nonlinear oscillators in an LTI electrical power network. In: IEEE transaction no circuits system I: regular papers, vol 61, pp 834–844

12.

Johnson BB, Dhople SV, Hamadeh AO, Krein PT (2014) Synchronization of parallel single-phase inverters with virtual oscillator control. IEEE Trans Power Electron 29(11):6124–6138

13.

Johnson BB, Dhople SV, Cale JL, Hamadeh AO, Krein PT (2014) Oscillator-based inverter control for islanded three-phase microgrids. IEEE J Photovoltaics 4(1):387–395CrossRef

14.

Vandon TL, Meersman B, De Koonig JDM, Vandevelde L (2012) Analogy between conventional grid control and islanded microgrid control based on a global dc-link voltage droop. IEEE Trans Power Del 27:1405–1414CrossRef

15.

Etemadi AH, Davison EJ, Iravani R (2012) A decentralized robust strategy for multi-DER microgrids—part I: fundamental concepts. IEEE Trans Power Del 27:1843–1853CrossRef

16.

Shafiee Q, Nasirian V, Guerrero JM, Lewis FL, Davoudi A (2014) Team-oriented adaptive droop control for autonomous AC microgrids. In: Proceedings of 40th industrial electronics conference (IECON), pp 1861–1867

17.

Etemadi AH, Davison EJ, Iravani R (2014) A generalized decentralized robust control of islanded microgrids. IEEE Trans Power Syst 29(6):3102–3113CrossRef

18.

Hui Q, Haddad W (2008) Distributed nonlinear control algorithms for network consensus. Automatica 42:2375–2381MathSciNetCrossRefMATH

19.

Fax J, Murray R (2004) Information flow and cooperative control of vehicle formations. IEEE Trans Automat Control 49:1465–1476MathSciNetCrossRef

20.

Qu Z (2009) Cooperative control of dynamical systems: applications to autonomous vehicles. Springer, New YorkMATH

21.

Shafiee Q, Guerrero JM, Vasquez JC (2014) Distributed secondary control for islanded microgrids—a novel approach. IEEE Trans Power Electron 29:1018–1031CrossRef

22.

Shafiee Q, Stefanovic C, Dragicevic T, Popovski P, Vasquez JC, Guerrero JM (2014) Robust networked control scheme for distributed secondary control of islanded microgrids. IEEE Trans Ind Electron 61:5363–5374CrossRef

23.

Zhang Y, Ma H (2012) Theoretical and experimental investigation of networked control for parallel operation of inverters. IEEE Trans Ind Electron 59:1961–1970CrossRef

24.

Marwali MN, Keyhani A (2004) Control of distributed generation systems—part I: voltages and currents control. IEEE Trans Power Electron 19:1541–1550CrossRef

25.

Marwali MN, Jung JW, Keyhani A (2004) Stability analysis of load sharing control for distributed generation systems. IEEE Trans Energy Convers 22:737–745CrossRef

26.

McArthur SDJ, Davidson EM, Catterson VM, Dimeas AL, Hatziargyriou ND, Ponci F, Funabashi T (2007) Multi-agent systems for power engineering applications—part I: concepts, approaches, and technical challenges. IEEE Trans Power Syst 22:1743–1752CrossRef

27.

Bidram A, Davoudi A, Lewis FL, Qu Z (2013) Secondary control of microgrids based on distributed cooperative control of multi-agent systems. IET Gener Transm Dist 7:822–831CrossRef

28.

Nasirian V, Davoudi A, Lewis FL (2014) Distributed adaptive droop control for dc microgrids. In: Proceedings of 29th IEEE applied power electronics conference and exposition (APEC), pp 1147–1152

29.

Nasirian V, Moayedi S, Davoudi A, Lewis FL (2015) Distributed cooperative control of dc microgrids. IEEE Trans Power Electron 30:2288–2303CrossRef

30.

Nasirian V, Davoudi A, Lewis FL, Guerrero JM (2014) Distributed adaptive droop control for dc distribution systems. IEEE Trans Energy Convers 29:944–956CrossRef

31.

Moayedi S, Nasirian V, Lewis FL, Davoudi A (2015) Team-oriented load sharing in parallel dc-dc converters. IEEE Trans Ind Appl 51(1):479–490CrossRef

32.

Robbins BA, Hadjicostis CN, Dominguez-Garcia AD (2013) A two-stage distributed architecture for voltage control in power distribution systems. IEEE Trans Power Syst 28:1470–1482CrossRef

33.

Dominguez-Garcia AD, Hadjicostis CN, Vaidya NF (2012) Resilient networked control of distributed energy resources. IEEE J Sel Areas Commun 30:113–1148CrossRef

34.

Cady ST, Dominguez-Garcia AD (2012) Distributed generation control of small-footprint power systems. In: Proceedings of North American power symposium, pp 1–6

35.

Bidram A, Davoudi A, Lewis FL (2014) A multi-objective distributed control framework for islanded microgrids. IEEE Trans Ind Inform 10(3):1785–1798CrossRef

36.

Dorfler F, Simpson-Porco JW, Bullo F (2014) Breaking the hierarchy: distributed control and economic optimality in microgrids. Available on arXiv:1401.1767v1

37.

Bouattour H, Simpson-Porco JW, Dorfler F, Bullo F (2013) Further results on distribute secondary control in microgrids. In: IEEE conference on decision and control, pp 1514–1519

38.

Simpson-Porco JW, Dorfler F, Bullo F, Shafiee Q, Guerrero JM (2013) Stability, power sharing, and distributed secondary control in droop-controlled microgrids. In: IEEE smart grid communications symposium, pp 672–677

39.

Simpson-Porco JW, Dorfler F, Bullo F (2013) Synchronization and power sharing for droop-controlled inverters in islanded microgrids. Automatica 49:2603–2611MathSciNetCrossRef

40.

Olfati-saber R, Fax JA, Murray RM (2007) Consensus and cooperation in networked multi-agent systems. Proc IEEE 95(1):215–233CrossRef

41.

Olfati-Saber R, Murray RM (2004) Consensus problems in networks of agents with switching topology and time-delays. IEEE Trans Automat Control 49(9):1520–1533MathSciNetCrossRef

42.

Erickson RW, Maksimovic D (2001) Fundamental of power electronics, 2nd edn. Kluwer, NorwellCrossRef

43.

Spanos DP, Olfati-Saber R, Murray RM (2005) Dynamic consensus for mobile networks. In: Proceedings of 16th international federation of automatic control (IFAC), pp 1–6

44.

Chen L, Hu C, Zhang Q, Zhang K, Batarseh I (2015) Modeling and triple-loop control of ZVS grid-connected dc/ac converters for three-phase balanced micro-inverter application. IEEE Trans Power Electron 30(4):2010–2023CrossRef

45.

Sozer Y, Torrey DA (2009) Modeling and control of utility interactive inverters. IEEE Trans Power Electron 24(11):2475–2483CrossRef

46.

Pogaku N, Prodanovic M, Green TC (2007) Modeling, analysis and testing of autonomous operation of an inverter-based microgrid. IEEE Trans Power Electron 22(2):613–625CrossRef

47.

Guo X, Lu Z, Wang B, Sun X, Wang L, Guerrero JM (2014) Dynamic phasors-based modeling and stability analysis of droop-controlled inverters for microgrid applications. IEEE Trans Smart Grid 5(6):2980–2987CrossRef

48.

Zhang H, Lewis FL, Qu Z (2012) Lyapunov, adaptive, and optimal design techniques for cooperative systems on directed communication graphs. IEEE Trans Ind Electron 59(7):3026–3041CrossRef

49.

Xiao F, Wang L (2008) Asynchronous consensus in continuous-time multi-agent systems with switching topology and time-varying delays. IEEE Trans Automat Control 53(8):1804–1816MathSciNetCrossRef

50.

Kahrobaeian A, Mohamed YARI (2015) Networked-based hybrid distributed power sharing and control of islanded micro-grid systems. IEEE Trans Power Electron 30(2):603–617CrossRef

51.

Ci S, Qian J, Wu D, Keyhani A (2012) Impact of wireless communication delay on load sharing among distributed generation systems through smart microgrids. IEEE Wireless Commun 19(3):24–29CrossRef

52.

Liu S, Wang X, Liu PX, Impact of communication delays on secondary frequency control in an islanded microgrid. IEEE Trans Ind Electron (to be published). doi:10.1109/TIE.2014.2367456

53.

Behjati H, Davoudi A, Lewis FL (2014) Modular DC-DC converters on graphs: cooperative control. IEEE Trans Power Electron 29(12):6725–6741CrossRef

54.

Nasirian V, Shafiee Q, Guerrero J, Lewis F, Davoudi A, (2016) Droop-free distributed control for AC microgrids. IEEE Trans Power Electronics 31(2):1600–1617

Titel: Droop-Free Distributed Control of AC Microgrids
verfasst von: Ali Bidram
Vahidreza Nasirian
Ali Davoudi
Frank L. Lewis
Verlag: Springer International Publishing
Buch: Cooperative Synchronization in Distributed Microgrid Control
Print ISBN: 978-3-319-50807-8

Electronic ISBN: 978-3-319-50808-5

Copyright-Jahr: 2017
DOI: https://doi.org/10.1007/978-3-319-50808-5_6