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      KCI등재 SCIE SCOPUS

      Active power decoupling method for single‑phase PWM converters without LC branch sensors

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      https://www.riss.kr/link?id=A108197166

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      다국어 초록 (Multilingual Abstract)

      The presence of ripple power in a converter system has a negative influence on both control performance and reliability. Active power decoupling (APD) is a practical technique to deal with such problems. However, the APD method requires extra sensors ...

      The presence of ripple power in a converter system has a negative influence on both control performance and reliability. Active power decoupling (APD) is a practical technique to deal with such problems. However, the APD method requires extra sensors on the LC branch, which increases the complexity and cost of the control system. This paper puts forward a new APD method to handle undesirable ripple power for H-bridge PWM converters. When compared with previous APD methods, the proposed APD method eliminates the current and voltage sensors on the LC branch by utilizing a ripple voltage control loop. Then, both the cost and reliability of the converter system are improved. To improve the control performance, an APD method that only has a voltage sensor in the LC branch is also discussed. Simulation results show that the DC-link voltage ripples can be decreased due to the application of the proposed APD method. Finally, the effectiveness of the proposed method is verified by the experimental results.

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      참고문헌 (Reference)

      1 Xu, S, "Single-phase voltage source inverter with voltage boosting and power decoupling capabilities" 8 (8): 2977-2988, 2020

      2 Shin, H, "Single-phase grid-connected motor drive system with dc-link shunt compensator and small dc-link capacitor" 32 (32): 1268-1278, 2017

      3 Li-Jun Diao ; Kan Dong ; Shao-Bo Yin ; Jing Tang ; Jie Chen, "Ripple Analysis and Control of Electric Multiple Unit Traction Drives under a Fluctuating DC Link Voltage" 전력전자학회 16 (16): 1851-1860, 2016

      4 Wu, M, "Optimal design of integrated magnetics for differential rectifiers and inverters" 33 (33): 4616-4626, 2018

      5 Zeng, J, "Modeling and control for a photovoltaic inverter with power decoupling on the AC side" 991-997, 2018

      6 Zhao, N, "Inverter power control based on dc-link voltage regulation for IPMSM drives without electrolytic capacitors" 33 (33): 558-571, 2018

      7 Nandi, P, "Integration of boost-type active power decoupling topology with single-phase switched boost inverter" 35 (35): 11965-11975, 2020

      8 Li, S, "Integration of an active filter and a single-phase AC/DC converter with reduced capacitance requirement and component count" 31 (31): 4121-4137, 2016

      9 Roy, J, "High step-up transformerless inverter for AC module applications with active power decoupling" 66 (66): 3891-3901, 2019

      10 Roy, J, "Half-bridge voltage swing inverter with active power decoupling for single-phase PV systems supporting wide power factor range" 34 (34): 7450-7461, 2019

      1 Xu, S, "Single-phase voltage source inverter with voltage boosting and power decoupling capabilities" 8 (8): 2977-2988, 2020

      2 Shin, H, "Single-phase grid-connected motor drive system with dc-link shunt compensator and small dc-link capacitor" 32 (32): 1268-1278, 2017

      3 Li-Jun Diao ; Kan Dong ; Shao-Bo Yin ; Jing Tang ; Jie Chen, "Ripple Analysis and Control of Electric Multiple Unit Traction Drives under a Fluctuating DC Link Voltage" 전력전자학회 16 (16): 1851-1860, 2016

      4 Wu, M, "Optimal design of integrated magnetics for differential rectifiers and inverters" 33 (33): 4616-4626, 2018

      5 Zeng, J, "Modeling and control for a photovoltaic inverter with power decoupling on the AC side" 991-997, 2018

      6 Zhao, N, "Inverter power control based on dc-link voltage regulation for IPMSM drives without electrolytic capacitors" 33 (33): 558-571, 2018

      7 Nandi, P, "Integration of boost-type active power decoupling topology with single-phase switched boost inverter" 35 (35): 11965-11975, 2020

      8 Li, S, "Integration of an active filter and a single-phase AC/DC converter with reduced capacitance requirement and component count" 31 (31): 4121-4137, 2016

      9 Roy, J, "High step-up transformerless inverter for AC module applications with active power decoupling" 66 (66): 3891-3901, 2019

      10 Roy, J, "Half-bridge voltage swing inverter with active power decoupling for single-phase PV systems supporting wide power factor range" 34 (34): 7450-7461, 2019

      11 Rezaie, H, "Enhancing reliability and power density of single-phase PHEV charger using an integrated active filter" 544-549, 2018

      12 Chen, H, "Digital current sensorless control for dual-boost half-bridge PFC converter with natural capacitor voltage balancing" 32 (32): 4074-4083, 2017

      13 Huang, K, "Design of power decoupling strategy for single-phase grid-connected inverter under nonideal power grid" 34 (34): 2938-2955, 2019

      14 Qi, W, "Design considerations for voltage sensorless control of a PFC single-phase rectifier without electrolytic capacitors" 67 (67): 1878-1889, 2020

      15 Chen, H, "Design and implementation of threephase current sensorless control for PFC bridge converter with considering voltage drops of power semiconductors" 65 (65): 9234-9242, 2018

      16 Chen, R, "DC capacitor- less inverter for single-phase power conversion with minimum voltage and current stress" 30 (30): 5499-5507, 2015

      17 Santoyo-Anaya, M.A, "Current-sensorless VSC-PFC rectifier control with enhance response to dynamic and sag conditions using a single PI loop" 33 (33): 6403-6415, 2018

      18 Wu, H, "Control and modulation of bidirectional single-phase AC–DC three-phase-leg SPWM converters with active power decoupling and minimal storage capacitance" 31 (31): 4226-4240, 2016

      19 Sun, H, "Automatic power decoupling controller of dependent power decoupling circuit for enhanced transient performance" 66 (66): 1820-1831, 2019

      20 Mohammad Sameer Irfan ; Mohamed Atef Tawfik ; Ashraf Ahmed ; Joung‑Hu Park, "Analysis and design of flux cancellation power-decoupling method for electrolytic-capacitorless three-phase cascaded multilevel inverters" 전력전자학회 21 (21): 321-341, 2021

      21 Li, H, "Active power decoupling for high-power single-phase PWM rectifiers" 28 (28): 1308-1319, 2013

      22 Zhang, J, "Active power decoupling and controlling for single-phase FACTS device" 2019 (2019): 1333-1337, 2019

      23 Yao, W, "Active damping of LCL filters with all-pass filters considering grid impedance variations and parameter drifts" 4915-4921, 2018

      24 Liang, S, "A solid state variable capacitor with minimum DC capacitance" 3496-3501, 2014

      25 Ming, W, "A single-phase four-switch rectifier with significantly reduced capacitance" 31 (31): 1618-1632, 2016

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      학술지 이력

      학술지 이력
      연월일 이력구분 이력상세 등재구분
      2023 평가예정 해외DB학술지평가 신청대상 (해외등재 학술지 평가)
      2020-01-01 평가 등재학술지 유지 (해외등재 학술지 평가) KCI등재
      2014-10-08 학술지명변경 한글명 : 전력전자학회 영문논문지 -> Journal of Power Electronics KCI등재
      2010-01-01 평가 등재학술지 유지 (등재유지) KCI등재
      2007-01-01 평가 등재학술지 선정 (등재후보2차) KCI등재
      2006-01-01 평가 등재후보 1차 PASS (등재후보1차) KCI등재후보
      2004-07-01 평가 등재후보학술지 선정 (신규평가) KCI등재후보
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      학술지 인용정보

      학술지 인용정보
      기준연도 WOS-KCI 통합IF(2년) KCIF(2년) KCIF(3년)
      2016 0.83 0.54 0.74
      KCIF(4년) KCIF(5년) 중심성지수(3년) 즉시성지수
      0.65 0.62 0.382 0.06
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