연구동향 분석
박사

Analysis and Design of Stabilization Techniques for Distributed Generation Systems in Microgrid = 마이크로그리드에 적용된 분산전원 시스템의 안정화 운용 기술 해석 및 설계

조종민 2020년

논문상세정보
    • 저자 조종민
    • 형태사항 26 cm: 178p.
    • 일반주기 지도교수: 차한주
    • 학위논문사항 忠南大學校 大學院, 학위논문(박사)-, 2020. 2, 전기공학과 전력 및 자동화
    • 발행지 대전
    • 언어 eng
    • 출판년 2020
    • 발행사항 忠南大學校 大學院
    • 주제어 Microgrid
    유사주제 논문( 116)
인용/피인용
' Analysis and Design of Stabilization Techniques for Distributed Generation Systems in Microgrid = 마이크로그리드에 적용된 분산전원 시스템의 안정화 운용 기술 해석 및 설계' 의 주제별 논문영향력
논문영향력 선정 방법
논문영향력 요약
주제
  • microgrid
동일주제 총논문수 논문피인용 총횟수 주제별 논문영향력의 평균
117 0

0.0%

' Analysis and Design of Stabilization Techniques for Distributed Generation Systems in Microgrid = 마이크로그리드에 적용된 분산전원 시스템의 안정화 운용 기술 해석 및 설계' 의 참고문헌

  • ¡°¡±On the Design of LCL Filter with Passive Damping in Three-Phase Shunt Active Power Filter
    pp . 825-830 . [2016]
  • ¡°Wide Damping Region for LCL-Type Grid-Connected Inverter With an ImprovedCapacitor-Current-Feedback Method
    vol . 30 , no . 9 , [2015]
  • ¡°Utilization of Proportional FilterCapacitor Voltage Feedforward to Realize Active Damping for Digitally-Controlled Grid-Tied Inverter Operation Under Wide Grid Impedance Variation ,
    pp . 4450-4457 . [2014]
  • ¡°TransitionControl Strategy Between Standalone and Grid-Connected Operations of Voltage-Source Inverters
    vol . 48 , no . 5 , pp . 1516-1525 , Sep./Oct [2012]
  • ¡°The AC LineCurrent Regulation Strategy for the Grid-Connected PV System
    vol . 25 , no . 1 , pp . 209-208 , [2010]
  • ¡°Systematic Design of the Lead-Lag Network Method for Active Damping in LCL-Filter Based Three PhaseConverters
    vol . 10 , no . 1 , pp . 43-52 , [2014]
  • ¡°Stability of Photovoltaic and Wind Turbine Grid-Connected Inverters for a Large Set of Grid Impedance Values
    vol . 21 , no . 1 , pp . 263-272 , [2006]
  • ¡°Stability and Bandwidth Implications of DigitallyControlled Grid-Connected Parallel Inverters
    vol . 57 , no . 11 , pp . 3685-3694 , [2010]
  • ¡°Stability Improvement ofCurrentControl by Voltage FeedforwardConsidering a Large Synchronous Inductance of a Diesel Generator
    vol . 54 , no . 5 , pp . 5134-5142 , Sep./Oct [2018]
  • ¡°Stability Improvement ofCurrentControl by Voltage FeedforwardConsidering a Large Synchronous Inductance of Diesel Generator
    pp . 1540-1544 [2017]
  • ¡°Stability Improvement of Battery Energy Storage SystemConsidering Synchronous Inductance Effect of Diesel Generator ,
    vol . 13 , no . 6 , pp . 2254-2261 , [2018]
  • ¡°Stability Design of Electric Springs in Power Grids
    pp . 6838-3844 . [2015]
  • ¡°Stability Analysis of HarmonicCompensation System under Weak GridConditions
    pp . 5802-5807 . [2015]
  • ¡°Single-Phase Distributed Generation Synchronization with a Distorted or Weak Grid
    pp . 1143-1148 . [2015]
  • ¡°Robust Single-Loop DirectCurrentControl of LCL-filteredConverter-based DG Units in Grid-Connected and Autonomous Microgrid Modes
    vol . 29 , no . 10 , pp . 5605 ? 5619 [2014]
  • ¡°Robust Design of LCL Filters for Single-Current-Loop-Controlled Grid-Connected PowerConverters With Unit PCC Voltage Feedforward ,
    vol . 6 , no . 1 , pp . 54-62 , [2018]
  • ¡°Resonance Interaction of Multiparallel Grid-Connected Inverters With LCL Filter
    vol . 32 , no . 2 , pp . 894-899 , [2017]
  • ¡°Research on AdaptiveControl of Grid-Connected PV Inverters in Weak Grid
    pp . 4229-4235 [2015]
  • ¡°Regions of Active DampingControl for LCL Filters
    vol . 50 , no . 1 , pp . 424-432 , Jan./Feb [2014]
  • ¡°Protection of Microgrids During Utility Voltage Sags ,
    vol . 53 , no . 5 , pp . 1427-1426 , [2006]
  • ¡°PredictiveCurrentControl of a Voltage Source Inverter
    vol . 54 , no . 1 , pp . 495-503 , [2007]
  • ¡°Positive-Feedback-Based Active Anti-Islanding Schemes for Inverter-Based Distributed Generators : Basic Principle , Design Guideline and Performance Analysis
    vol . 25 , no . 12 . [2010]
  • ¡°Passivity-Based Design of Passive Damping for LCL-Filtered Voltage SourceConverters
    pp . 3718-3725 . [2015]
  • ¡°Passive Filter Design for Three-Phase Inverter Interfacing in Distributed Generation
    [2007]
  • ¡°Optimized Design of Stationary Frame Three Phase ACCurrent Regulators ,
    vol . 24 , no . 11 , pp . 2417-2416 , [2009]
  • ¡°Optimal Operation forCommunity-Based Multi-Party Microgrid in Grid-Connected and Islanded Modes ,
    vol . 9 , no . 2 , pp . 756-765 , [2018]
  • ¡°Optimal Design of High-Order Passive-Damped Filters for Grid-Connected Applications
    vol . 31 , no . 3 , pp . 2083-2098 , [2016]
  • ¡°Observer-Based Active Damping of LCL Resonance in Grid-Connected Voltage SourceConverters
    vol . 50 , no . 6 , pp . 3977-3985 , Nov./Dec [2014]
  • ¡°Modeling andControl of N-Paralleled Grid-Connected Inverters With LCL FilterCoupled Due to Grid Impedance in PV Plants
    vol . 26 , no . 3 , pp . 770-785 , [2011]
  • ¡°Mechanism Analysis and Mitigation of Instability in Grid-Connected Voltage Source Inverter with LCL Filters Based on Terminal Impedance
    pp . 2272-2277 . [2016]
  • ¡°Mechanism Analysis and Mitigation of Instability in Grid-Connected Voltage Source Inverter with LCL Filters Based on Terminal Impedance
  • ¡°Limitations of Voltage-Oriented PICurrentControl of Grid-Connected PWM Rectifiers With LCL Filters
    vol . 56 , no . 2 , pp . 380-388 , [2009]
  • ¡°LCL-Filter Design for Robust Active Damping in Grid-ConnectedConverters
    vol . 10 , no . 4 , pp . 2192-2203 , [2014]
  • ¡°LCL-Filter Design for Robust Active Damping in Grid-ConnectedConverter
    vol . 10 , no . 4 , pp . 2192-2203 , [2014]
  • ¡°LCL Filter with Passive Damping for PV SystemConnected to the Network , ¡± in
    [2016]
  • ¡°Investigation of Active Damping Approaches for PI-BasedCurrentControl of Grid-Connected Pulse Width ModulationConverters With LCL Filters
    vol . 46 , no . 4 pp , 1509-1507 , Jul./Aug [2010]
  • ¡°Investigation and Active Damping of Multiple Resonances in a Parallel-Inverter-Based Microgrid
    vol . 28 , no . 1 , pp . 234-246 , [2013]
  • ¡°Inpednace Shpaing of the Grid-Connected Inverter with LCL Filter to Improve Its Adaptability to the Weak GridCondition ,
    vol . 29 , no . 11 , pp . 5795-5805 , [2014]
  • ¡°ImprovedControl strategy with grid-voltage feedforward for LCL-filter-based inverterConnected to weak grid
    vol . 7 , no . 10 , pp . 2660-2671 [2014]
  • ¡°ImprovedControl strategy for stand-alone distributed generation system under unbalanced and non-linear loads ,
    vol . 5 , no . 5 , pp . 323-331 [2011]
  • ¡°Impedance-Based Stability Analysis of Single-Phase InverterConnected to Weak Grid with Voltage Feed-ForwardControl
    pp . 2182-2186 [2016]
  • ¡°Impedance Shaping of the Grid-Connected Inverter with LCL Filter to Improve Its Adaptability to the Weak GridCondition ,
    vol . 29 , no . 11 , pp . 5795-5805 , [2014]
  • ¡°Impact of the Voltage Feed-Forward andCurrent Decoupling on VSCCurrentControl Stability in Weak Grid Based onComplex Variables
    pp . 6845-6852 [2015]
  • ¡°Highly Accurate Derivatives for LCL-Filtered GridConverter WithCapacitor Voltage Active Damping
    vol . 31 , no . 5 , pp . 3612-3625 [2016]
  • ¡°High-performance harmonic extraction algorithm for a 25kV traction power qualityConditioner , ¡± IEE Proc.-Electron
    vol . 151 , no . 5 , pp . 505-512 , [2004]
  • ¡°Harmonic Resonance Investigation of a Multi-Inverter Grid-Connected System Using Resonance Modal Analysis
    vol . 34 , no . 1 , pp . 63-72 , [2019]
  • ¡°GridCurrent Regulation of a Three-Phase Voltage Source Inverter With an LCL Input Filter
    vol . 18 , no . 3 , pp . 888-895
  • ¡°Grid-Voltage-Feedforward Active Damping for Grid-Connected Inverter with LCL Filter
  • ¡°Grid-Voltage Feedforward Based on Grid-Connected LCL-Filtered Inverter with High Robustness and Low GridCurrent Distortion in Weak Grid
    2016. pp . 1919-2005
  • ¡°Grid-Filter Design for a Multimegawatt Medium-Voltage Voltage ? Source Inverter
    vol . 58 , no . 4 , pp . 1205-1217 [2011]
  • ¡°Grid-Current-Feedback Active Damping for LCL Resonance in Grid-Connected Voltage-SourceConverters
    vol . 31 , no . 1 , [2016]
  • ¡°Genetic Algorithm-Based Design of the Active Damping for an LCL-Filter Three-Phase Active Rectifier
    vol . 19 , no . 1 , pp . 76-86 , [2004]
  • ¡°GeneralizedClosed-LoopControl Schemes with Embedded Virtual Impedances for Voltage SourceConverters with LC or LCL Filters
    vol . 27 , no . 4 , pp . 1850-1861 [2012]
  • ¡°Generalized Stability Regions ofCurrentControl for LCL-Filtered Grid-ConnectedConverters without Passive or Active Damping
    pp . 2040-2047 [2015]
  • ¡°Generalized Design of High Performance Shunt Active Power Filter With Output LCL Filter
    vol . 59 , no . 3 , pp . 1443-1452 , [2012]
  • ¡°Full-Feedforward Schemes of Grid Voltages for a Three-Phase LCL-type Grid-Connected Inverter
    vol . 60 , no . 6 , pp . 2237-2250 , [2013]
  • ¡°Frequency-Shift AccelerationControl for Anti-Islanding of a Distributed-Generation Inverter
    vol . 57 , no . 2 , [2010]
  • ¡°Frequency fuzzy anti-islanding for grid-connected and islanding operation in distributed generation systems
    vol . 8 , no . 7 , pp . 1255-1262 , [2015]
  • ¡°Filter-Based Active Damping of Voltage SourceConverters With LCL Filter
    vol . 58 , no . 8 , pp . 3623-2633 , [2011]
  • ¡°Exploring Inherent DampingCharacteristic of LCL-Filters for Three-Phase Grid-Conneected Voltage Source Inverters
    vol . 27 , no . 3 , pp . 1433-1443 , [2012]
  • ¡°Evaluations ofCurrentControl in weak gridCase for grid-connected LCL-filtered inverter ,
    vol . 6 , no . 2 , pp . 227-234 [2013]
  • ¡°Evaluation of Anti-Islanding Schemes based on Nondetection ZoneConcept
    vol . 19 , no . 5 , pp . 1171-1176 , [2004]
  • ¡°Evaluation of AFD Islanding Detection Methods Based on NDZs Described in Power Mismatch Space
    pp . 2733-2739
  • ¡°Energy management of microgrid in grid-connected and stand-alone modes ,
    vol . 28 , no . 3 , pp . 3380-3389 , [2013]
  • ¡°Dynamic Non-detection Zones of Positive Feedback Anti-Islanding Methods for Inverter-Based Distributed Generators
    vol . 26 , no . 2 , pp . 1145-1145 [2011]
  • ¡°DigitalCurrentControl of a Voltage SourceConverte With Active Damping of LCl Resonance
    vol . 21 , no . 5 , pp . 1364-1373 , [2006]
  • ¡°Design of LCL Filters With LCL Resonance Frequencies Beyond Nyquist Frequency for Grid-ConnectedConverters , ¡± EEE J. Emerg
    vol . 4 , no.1 , pp . 3-14 , [2016]
  • ¡°Design of High-Performance Stand-Alone and Grid-Connected Inverter for Distributed Generation Applications
    vol . 60 , no . 4 , pp . 1542-1555 [2013]
  • ¡°Design of Effective Passive Damping Resistor of Grid-Connected Inverter with LCL Filter for Industrial Applications
    vol . 14 , no . 5 , pp . 2039-2048 , [2019]
  • ¡°Design andControl of an LCL-Filter-Based Three-Phase Active Rectifier
    vol . 41 , no . 5 , pp . 1281-1291 , Sep./Oct [2005]
  • ¡°Design and Operation for a Standalone DG-SPV-BES Microgrid System
    pp . 1 ? 6 . [2014]
  • ¡°Design and Implementation of a RobustCurrentController for VSIConnected to the Grid Through an LCL Filter
    vol . 24 , no . 6 , pp . 1444-1452 , [2009]
  • ¡°Design and Analysis of Robust Active Damping for LCL Filters Using Digital Notch Filters
    vol . 32 , no . 3 , pp . 2360-2375 , [2017]
  • ¡°Derivation of a Stationary-Frame Single-LoopController for Three-Phase Standalone Inverter Supplying Nonlinear Loads ,
    vol . 29. no . 9 , [2014]
  • ¡°Delay-Dependent Stability of Single-LoopControlled Grid-Connected Inverters with LCL Filters
    vol . 31 , no . 1 , pp . 743-757 , [2016]
  • ¡°Damping Methods for ResonancesCaused by LCL-Filter-BasedCurrent-Controlled Grid-Tied Power Inverters : An Overview
    vol . 64 , no . 9 , pp . 7402-7413 , [2017]
  • ¡°DOE/EPRI Electricity Storage Handbook inCollaboration with NRECA , ¡± SANDIA Report SAND2015
    [2015]
  • ¡°Comparative Analysis of Low-pass Output Filter for Single-phase Grid-connected Photovoltaic Inverter
    pp . 1659-1665 . [2010]
  • ¡°Capacitor-Voltage Feedforward With Full DelayCompensation to Improve Weak Grids Adaptability of LCL-Filtered Grid-ConnectedConverters for Distributed Generation System
    vol . 33 , no . 1 , pp . 749-764 , [2018]
  • ¡°Capacitor-Current-Feedback Active Damping With ReducedComputation Delay for Improving Robustness of LCL-Type Grid-Connected Inverter
    vol . 29 , no . 7 , pp . 3414-2427 , [2014]
  • ¡°Analysis ofCurrentControl Stability using PIControl in Synchronous Reference Frame for Grid-Connected Inverter with LCL Filter
    vol . 21 , no . 2 , pp . 168-175 [2016]
  • ¡°Analysis of the Passive Damping Losses in LCL-Filter-Based GridConverters
    vol . 28 , no . 6 , pp . 2642-2646 , [2013]
  • ¡°Analysis and Suppression of Interaction between STATCOM and Voltage-source Inverter in Islanded Micro-grid
    pp . 6858-6863 . [2015]
  • ¡°Analysis and Mitigation of Resonance Propagation in Grid-Connected and Islanding Microgrids
    vol . 30 , no . 1 , pp . 70-81 , [2015]
  • ¡°Analysis and Mitigation of Interaction Dynamics in Active DC Distribution Systems With Positive Feedback Islanding Detection Schemes
    vol . 33 , no . 3 , pp . 2751-2773 , [2018]
  • ¡°Analysis and Impacts of Implementing DroopControl in DFIG-Based Wind Turbines on Microgrid/Weak-Grid Stability
    vol . 30 , no . 1 , pp . 385-396 , [2015]
  • ¡°Analysis and Design of LCL Filter with Passive DampingCircuits for Three-Phase Grid-Connected Inverters
    652-658 [2015]
  • ¡°An LCL-LC Filter for Grid-ConnectedConverter : Topology , Parameter , and Analysis
    vol . 30 , no . 9 , pp . 5067-5077 , [2015]
  • ¡°An Islanding Detection Method by Using Frequency Positive Feedback Based on FLL for Single-Phase Microgrid
    vol . 8 , no . 4 , pp . 1821-1830 [2017]
  • ¡°An Islanding Detection Algorithm for Inverter-Based Distribiuted Generation Based on Reactive PowerControl
    vol . 29 , no . 9 , pp . 4672-4683 , [2014]
  • ¡°An Interaction-Admittance Model for Multi-Inverter Grid-Connected Systems
    vol . 34 , no . 8 , pp . 7542-7557 , [2019]
  • ¡°An Improved Three-Phase Variable-Band HysteresisCurrent Regulator
    vol . 28 , no . 1 , pp . 441-450 , [2013]
  • ¡°An Improved Robust PredictiveCurrent Regulation Algorithm
    vol . 41 , no . 6 , pp . 1720-1733 , Nov./Dec [2005]
  • ¡°An Improved Islanding Detection Method for a Grid-Connected Inverter With Intermittent Bilateral Reactive Power Variation
    vol . 28 , no . 1 , pp . 268-278 , [2013]
  • ¡°An Anti-Islanding Protection Method Based on Reactive Power Injection and ROCOF
    vol . 32 , no . 1 , pp . 401-410 , [2017]
  • ¡°An Analysis Method for Harmonic Resonance and Stability of Multi-Paralleled LCL-Filtered Inverters ,
    [2015]
  • ¡°An Adaptive VoltageControl Strategy of Trhee-Phase Inverter for Stand-Alone Distributed Generation Systems
    vol . 60 , no . 12 , pp . 5660-5672 , [2013]
  • ¡°An Active Damper for Stabilizing Power-Electronics-Based AC Systems ,
    vol . 29 , no . 7 , pp . 3318-3329 , [2014]
  • ¡°Active Damping-BasedControl for Grid-Connected LCL-Filtered Inverter With Injected GridCurrent Feedback Only
    vol . 61 , no . 9 , pp . 4746-4758 , [2014]
  • ¡°ACompositeCompensation Method of a Grid-connected AC/DCConverter to Improve Robustness under Weak GridConditions
    pp . 6853-6857 [2015]
  • ¡°A Self-commissioning Notch Filter for Active Damping ina Three-Phase LCL-Filter=Based Grid-TieConverter
    vol . 29 , no . 12 , pp . 6754-6761 , [2014]
  • ¡°A Practical Method for Nondetection Zone Estimation of Passive Anti-Islanding Schemes Applied to Synchronous Distributed Generators
    vol . 30 , no . 5 , pp . 2006-2076 , [2015]
  • ¡°A Novel RPV ( Reactive-Power-Variation ) Antiislanding Method Based on Adapted Reactive Power Perturbation ,
    vol . 28 , no . 11 , pp . 4998-5012 , [2013]
  • ¡°A Novel Hybrid Islanding Detection Method for Inverter-Based DGs Using SFS and ROCOF ,
    vol . 32 , no . 5 , pp . 2162-2170 , [2017]
  • ¡°A Novel Design and Optimization Method of an LCL Filter for a Shunt Active Power Filter
    vol . 61 , no . 8 , pp . 4000-4010 , [2014]
  • ¡°A New Feedback Method for PRCurrentControl of LCL-Filter-Based Grid-Connected Inverte ,
    vol . 57 , no . 6 , pp . 2033-2041 , [2010]
  • ¡°A NEw Design Method for the Passive Damped LCL and LLCL Filter-Based Single-Phase Grid-tied Inverter ,
    vol . 60 , no . 10 , [2013]
  • ¡°A General Design Procedure for Multi-Parallel Modular Grid-Tied Inverters System to PreventCommon and Interactive Instability
    vol . 34 , no . 7 , pp . 6025-6030 [2019]
  • ¡°A Feedforward Scheme to Improve System Stability in Grid-connected Inverter with LCL Filter
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  • Overview of Control and Grid Synchronization for Distributed Power Generation Systems
    vol . 53 , no . 5 , pp . 1398-1399 , [2006]
  • M. Liserre and P. C. Loh , ¡°Proportional-resonant controllers and filters for grid-connected voltage-source converters
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