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dc.contributor.authorJang, Gilsoo*
dc.date.accessioned2021-02-11T15:40:22Z
dc.date.available2021-02-11T15:40:22Z
dc.date.issued2019*
dc.date.submitted2019-12-09 11:49:16*
dc.identifier42646*
dc.identifier.urihttps://directory.doabooks.org/handle/20.500.12854/49696
dc.description.abstractThe modern electric power system has evolved into a huge nonlinear complex system due to the interconnection of thousands of generation and transmission systems. The unparalleled growth of renewable energy resources (RESs) has caused significant concern regarding grid stability and power quality, and it is essential to find ways to control such a massive system for effective operation. The controllability of HVDC and FACTS devices allows for improvement of the dynamic behavior of grids and their flexibility. Research is being carried out at both the system and component levels of modelling, control, and stability. This Special Issue aims to present novel HVDC topologies and operation strategies to prevent abnormal grid conditions.*
dc.languageEnglish*
dc.subjectTA1-2040*
dc.subjectT1-995*
dc.subject.otherDC distribution system*
dc.subject.otherback-to-back HVDC*
dc.subject.othervirtual impedance*
dc.subject.othern/a*
dc.subject.othersynchronous condenser (SC)*
dc.subject.otherVSC–HVDC*
dc.subject.otherembedded HVDC*
dc.subject.otherPowell’s direct set method*
dc.subject.otherspecial protection system*
dc.subject.otherloss minimization*
dc.subject.othergrid-interconnection*
dc.subject.othermulti-infeed HVDC system*
dc.subject.otherreclosing process*
dc.subject.othermodular multilevel converter (MMC)*
dc.subject.othergrid service of HVDC*
dc.subject.otherangle stability*
dc.subject.otherimpedance-based Nyquist stability criterion*
dc.subject.otherHVDC operation point*
dc.subject.othercommutation failure probability*
dc.subject.otherpower control*
dc.subject.otherAC/DC converter*
dc.subject.otherVSC HVDC*
dc.subject.otherfrequency droop control*
dc.subject.otherprotection*
dc.subject.otherhigh voltage direct current (HVDC)*
dc.subject.otherquantitative evaluation*
dc.subject.othershort-circuit current calculation*
dc.subject.otheractive power control strategies*
dc.subject.othergrounding system*
dc.subject.otherLCC HVDC*
dc.subject.otherinsulation monitoring device (IMD)*
dc.subject.other3-phase AC/DC PWM converter*
dc.subject.othertransient stability*
dc.subject.otherangle spread*
dc.subject.otherreclosing current limiting resistance (RCLR)*
dc.subject.otherBTB-HVDC*
dc.subject.otherfull bridge (FB)*
dc.subject.otherGVIF index*
dc.subject.othersystem loss minimization*
dc.subject.otherSOGI-FLL*
dc.subject.otherhalf bridge (HB)*
dc.subject.otherfault current limiter (FCL)*
dc.subject.otherVSC-HVDC*
dc.subject.otherline commutated converter*
dc.subject.otherDC distribution*
dc.subject.otherhybrid HVDC breaker (HCB)*
dc.subject.otherphase detection*
dc.subject.otherDC-side oscillation*
dc.titleHVDC for Grid Services in Electric Power Systems*
dc.typebook
oapen.identifier.doi10.3390/books978-3-03921-763-2*
oapen.relation.isPublishedBy46cabcaa-dd94-4bfe-87b4-55023c1b36d0*
oapen.relation.isbn9783039217632*
oapen.relation.isbn9783039217625*
oapen.pages176*
oapen.edition1st*


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