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Erschienen in:
Fundamentals of More-Electronics Power Systems Kapitel lesen Erstes Kapitel lesen

2021 | OriginalPaper | Buchkapitel

3. Power Quality Conditioning

verfasst von : Jingyang Fang

Erschienen in: More-Electronics Power Systems: Power Quality and Stability

Verlag: Springer Singapore

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Abstract

This chapter presents state-of-the-art solutions to power quality problems in more-electronics power systems. It begins with passive solutions. In particular, power electronics-based power conditioning equipment, including uninterruptable power supplies (UPSs), dynamic voltage restorers (DVRs), static compensators (STATCOMs), active power filters (APFs), and unified power quality conditioners (UPQCs), forms the main part of this chapter. The fundamental principles, modeling and control, and results of such power conditioning equipment are highlighted.

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Vorheriges Kapitel Power Quality Problems and Standards
Nächstes Kapitel Stability Problems
Literatur
1.
Kundur P (1994) Power system stability and control. McGraw-Hill, New York, NY, USA
2.
Dugan RC, McGranaghan MF, Santoso S, Beaty HW (2003) Electrical power systems quality. McGraw-Hill, 2 Penn Plaza, New York, NY, USA
3.
Fang J, Lin P, Li H, Yang Y, Tang Y (2019) An improved virtual inertia control for three-phase voltage source converters connected to a weak grid. IEEE Trans Power Electron 34(9):8660–8670CrossRef
4.
Fang J, Xiao G, Yang X, Tang Y (2017) Parameter design of a novel series-parallel-resonant LCL filter for single-phase half-bridge active power filters. IEEE Trans Power Electron 32(1):200–217CrossRef
5.
Fang J, Li X, Yang X, Tang Y (2017) An integrated trap–LCL filter with reduced current harmonics for grid-connected converters under weak grid conditions. IEEE Trans Power Electron 32(11):8446–8457CrossRef
6.
Srianthumrong S, Akagi H (2003) Medium-voltage transformerless ac/dc power conversion system consisting of a diode rectifier and a shunt hybrid filter. IEEE Trans Ind Appl 39(3):874–882CrossRef
7.
Wu W, He Y, Blaabjerg F (2012) An LLCL power filter for single-phase grid-tied inverter. IEEE Trans Power Electron 27(2):782–789CrossRef
8.
Fang J, Xiao G, Zhang Y (2015) An LCCL filter and its application to a half-bridge APF. In: Presented at the Proceedings of the ICPE 2015–ECCE Asia, Seoul, Korea, pp 2566–2573
9.
Zhang X, Zhu H, Li H, Yu C (2015) An LCL-LC filter for grid-connected converter: topology, parameter, and analysis. IEEE Trans Power Electron 30(9):5067–5077CrossRef
10.
Wu W et al (2014) A modified LLCL filter with the reduced conducted EMI noise. IEEE Trans Power Electron 29(7):3393–3402CrossRef
11.
Xu J, Yang J, Ye J, Zhang Z, Shen A (2014) An LTCL filter for three-phase grid-connected converters. IEEE Trans Power Electron 29(8):4322–4338CrossRef
12.
Li X, Fang J, Lin P, Tang Y (2018) Active magnetic decoupling for improving the performance of integrated LCL-filters in grid-connected converters. IEEE Trans Ind Electron 65(2):1367–1376CrossRef
13.
Wu W, He Y, Lin Z, Blaabjerg F, Chung HS-H (2015) A simple differential mode EMI suppressor for the LLCL-filter-based single-phase grid-tied transformerless inverter. IEEE Trans Ind Electron 62(7):4141–4147CrossRef
14.
Wu W, Sun Y, Lin Z, Tang T, Blaabjerg F, Chung HS-H (2014) A new LCL-filter with in-series parallel resonant circuit for single-phase grid-tied inverter. IEEE Trans Ind Electron 61(9):4640–4644CrossRef
15.
Holmes DG, Lipo TA (2003) Pulse width modulation for power converters: principles and practice. Wiley, Hoboken, NJCrossRef
16.
Erickson RW, Maksimovic D (2001) Fundamentals of power electronics. Springer, New York, NY, USACrossRef
17.
Liserre M, Blaabjerg F, Hansen S (2005) Design and control of an LCL filter-based three-phase active rectifier. IEEE Trans Ind Appl 41(5):1281–1291CrossRef
18.
Fang J, Li H, Tang Y (2017) A magnetic integrated LLCL filter for grid-connected voltage source converters. IEEE Trans Power Electron 32(3):1725–1730CrossRef
19.
Fang J, Li X, Tang Y, Li H (2018) Design of virtual synchronous generators with enhanced frequency regulation and reduced voltage distortions. In: Presented at the Proceedings of the IEEE APEC, San Antonio, TEXAS, USA, pp 1412–1419
20.
Sype DM, Gusseme KD, Belie FM, Bossche AP, Melkebeek JA (2006) Small-signal z-domain analysis of digitally controlled converters. IEEE Trans Power Electron 21(2):470–478CrossRef
21.
Kai Z, Yong K, Jian X, Jian C (2003) Direct repetitive control of SPWM inverter for UPS purpose. IEEE Trans Power Electron 18(3):784–792CrossRef
22.
García-Cerrada A, Pinzón-Ardila O, Feliu-Batlle V, Roncero-Sánchez P, García-González P (2007) Application of a repetitive controller for a three-phase active power filter. IEEE Trans Power Electron 22(1):237–246CrossRef
23.
Li YW, Vilathgamuwa DM, Blaabjerg F, Loh PC (2007) A robust control scheme for medium-voltage-level DVR implementation. IEEE Trans Power Electron 54(4):2249–2261
24.
Fang J, Zhang R, Li H, Tang Y (2019) Frequency derivative-based inertia enhancement by grid-connected power converters with a frequency-locked-loop. IEEE Trans Smart Grid 10(5):4918–4927CrossRef
25.
Peng FZ, Lai J (1996) Dynamic performance and control of a static var generator using cascade multilevel inverters. IEEE Trans Ind Appl 32(3):509–517
26.
Wang J, Yan JD, Jiang L, Zou J (2016) Delay-dependent stability of single-loop controlled grid-connected inverters with LCL filters. IEEE Trans Power Electron 31(1):743–757CrossRef
27.
Fang J, Li X, Tang Y (2017) A novel LCL-filtered single-phase half-bridge distributed static compensator with DC-link filter capacitors and reduced passive component parameters. In: Proceedings of the IEEE APEC, Tampa, Florida, USA, pp 3279–3285
28.
Tang Y, Loh PC, Wang P, Choo FH, Gao F, Blaabjerg F (2012) Generalized design of high performance shunt active power filter with output LCL filter. IEEE Trans Ind Electron 59(3):1443–1452CrossRef
29.
Fujita H, Akagi H (1998) The unified power quality conditioner: the integration of series- and shunt-active filters. IEEE Trans Power Electron 13(2):315–322CrossRef
30.
Khadkikar V (2012) Enhancing electric power quality using UPQC: a comprehensive overview. IEEE Trans Power Electron 27(5):2284–2297CrossRef
31.
Fang J, Li Z, Goetz SM (2020) Multilevel converters with symmetrical half-bridge submodules and sensorless voltage balance. IEEE Trans Power Electron (in press)
32.
Khadkikar V, Chandra A (2008) A new control philosophy for a unified power quality conditioner (UPQC) to coordinate load-reactive power demand between shunt and series inverters. IEEE Trans Power Del 23(4):2522–2534CrossRef
33.
Khadkikar V, Chandra A (2011) UPQC-S: a novel concept of simultaneous voltage sag/swell and load reactive power compensations utilizing series inverter of UPQC. IEEE Trans Power Electron 26(9):2414–2425CrossRef
Metadaten
Titel
Power Quality Conditioning
verfasst von
Jingyang Fang
Copyright-Jahr
2021
Verlag
Springer Singapore
Buch
More-Electronics Power Systems: Power Quality and Stability

Print ISBN: 978-981-15-8589-0

Electronic ISBN: 978-981-15-8590-6

Copyright-Jahr: 2021

DOI
https://doi.org/10.1007/978-981-15-8590-6_3

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