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      KCI등재 SCOPUS

      10MW급 능동 차폐형 초전도 발전기 계자 전자석의 최적 설계

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      https://www.riss.kr/link?id=A107261651

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      다국어 초록 (Multilingual Abstract)

      In this paper, an optimal design was performed to improve the power density and specific power of a superconducting generator for 10MW-class actively shielded wind turbine using the response surface method (RSM). The objective functions of optimal des...

      In this paper, an optimal design was performed to improve the power density and specific power of a superconducting generator for 10MW-class actively shielded wind turbine using the response surface method (RSM). The objective functions of optimal design for reducing the weight of the generator were selected as perpendicular magnetic flux density, output power, and terminal voltage. The design variables were selected as three variables: field coil aperture, shield coil aperture and superconducting coil pitch (between shield and field aperture), which have a great influence on the objective function. After that, optimal design points were derived within the optimal region, and verification was performed through finite element analysis(FEM).

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      목차 (Table of Contents)

      • Abstract
      • 1. 서론
      • 2. 능동 차폐형 초전도 발전기 계자 전자석 형상 설계
      • 3. 결론
      • References
      • Abstract
      • 1. 서론
      • 2. 능동 차폐형 초전도 발전기 계자 전자석 형상 설계
      • 3. 결론
      • References
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      참고문헌 (Reference)

      1 방태경, "전기추진 항공기를 위한 급 공심형 초전도 발전기의 설계 타당성 연구" 대한전기학회 69 (69): 66-75, 2020

      2 "Wind Vision Detailed Roadmap Actions"

      3 B. S. Koo, "Trend Analysis of Power Electronics System and Motor for electric propulsion aircraft" 17 (17): 45-54, 2019

      4 K. B. Kim, "Technology Trends on the Electric Propulsion System for Aircraft" 14 (14): 70-82, 2016

      5 N. Mijatovic, "Superconducting Wind Turbine Generators" Technology University of Denmark 2012

      6 P. Chi-Kwong Luk, "Superconducting Machines - The Enabling Technology for Future Electric Propulsion in Aircraft" 2017

      7 H. J. Sung, "Practical Design of a 10MW Superconducting Wind Power Generator Considering Weight Issue" 23 (23): 2013

      8 Y. Xu, "Performance Comparison of 10MW Wind Turbine Generators with HTS, Copper, and PM Excitation" 26 (26): 2015

      9 H. J. Sung, "Necessity and status of large superconducting wind power generator development" 2020

      10 S. H. Park, "Modern Design of Experiments using Minitab" Minyoungsa 2010

      1 방태경, "전기추진 항공기를 위한 급 공심형 초전도 발전기의 설계 타당성 연구" 대한전기학회 69 (69): 66-75, 2020

      2 "Wind Vision Detailed Roadmap Actions"

      3 B. S. Koo, "Trend Analysis of Power Electronics System and Motor for electric propulsion aircraft" 17 (17): 45-54, 2019

      4 K. B. Kim, "Technology Trends on the Electric Propulsion System for Aircraft" 14 (14): 70-82, 2016

      5 N. Mijatovic, "Superconducting Wind Turbine Generators" Technology University of Denmark 2012

      6 P. Chi-Kwong Luk, "Superconducting Machines - The Enabling Technology for Future Electric Propulsion in Aircraft" 2017

      7 H. J. Sung, "Practical Design of a 10MW Superconducting Wind Power Generator Considering Weight Issue" 23 (23): 2013

      8 Y. Xu, "Performance Comparison of 10MW Wind Turbine Generators with HTS, Copper, and PM Excitation" 26 (26): 2015

      9 H. J. Sung, "Necessity and status of large superconducting wind power generator development" 2020

      10 S. H. Park, "Modern Design of Experiments using Minitab" Minyoungsa 2010

      11 Y. Guan, "Influence of Pole Number and Stator Outer Diameter on Volume, Weight, and Cost of Superconducting Generators With Iron-Cored Rotor Topology for Wind Turbines" 27 (27): 2017

      12 K. S. Haran, "High power density superconducting rotating machines — development status and technology roadmap" 30 (30): 2017

      13 P. J. Masson, "High Power Density Superconducting Motor for All-Electric Aircraft Propulsion" 15 (15): 2226-2229, 2005

      14 Z. Q. Jiang, "HTS Field Coil Optimization for Large Capacity Generators" 26 (26): 2016

      15 H. W. Cho, "Force Analysis of Superconducting Coils in Actively Shielded Air-Core Superconducting Machines" 28 (28): 2018

      16 Y. Terao, "Electromagnetic Design of 10MW Class Fully Superconducting Wind Turbine Generators" 22 (22): 2012

      17 성해진, "Designs of 10 MW Air-core and Iron-core HTS Wind Power Generators" 대한전기학회 10 (10): 545-550, 2015

      18 R. Shafaie, "Design of a 10-MW-Class Wind Turbine HTS Synchronous Generator With Optimized Field Winding" 23 (23): 2013

      19 S. B. Lee, "Design of Experiments Based on Minitab Examples"

      20 A. Patel, "Design considerations for fully superconducting synchronous motors aimed at future electric aircraft" 1-5, 2018

      21 J. Park, "Design and comparative analysis of a 2 ㎿ class HTS wind power generator with and without gear box" 1435-1436, 2020

      22 B. S. Go, "Design and Comparative Analysis of Performance Evaluation Systems for a Larga-Scale HTS Generator" 29 (29): 2019

      23 D. Loder, "Demonstration of a Practical Nb3Sn Coil for an Actively Shielded Generator" 27 (27): 2017

      24 "Deliverable D5.13, Technology Roadmap"

      25 Y. Terao, "Comparison of conventional and superconducting generator concepts for offshore wind turbines" 23 (23): 2013

      26 N. W. Kim, "Comparative Analysis of 10MW Class Geared and Gearless Type Superconducting Synchoronous Generators for a Wind Power Generation System" 22 (22): 2012

      27 C. Wen, "Coil Shape Optimization for Superconducting Wind Turbine Generator Using Response Surface Methodology and Particle Swarm Optimization" 24 (24): 2014

      28 D. Loder, "Actively shielded air-core superconducting machines: optimization and design considerations" University of Illinois at Urbana-Champaign 2016

      29 K. S. Haran, "Actively Shielded High- Field Air-Core Superconducting Machines" 26 (26): 2016

      30 Ruben Del Rosario, "A Future with Hybrid Electric Propulsion Systems: A NASA Perspective" 2014

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      공동연구자 (7)

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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
      2010-01-01 평가 등재학술지 유지 (등재유지) KCI등재
      2007-01-01 평가 학술지 통합 (기타) KCI등재
      2001-01-01 평가 등재학술지 유지 (등재유지) KCI등재
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      학술지 인용정보

      학술지 인용정보
      기준연도 WOS-KCI 통합IF(2년) KCIF(2년) KCIF(3년)
      2016 0.27 0.27 0.24
      KCIF(4년) KCIF(5년) 중심성지수(3년) 즉시성지수
      0.21 0.19 0.366 0.08
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