• 대한전기학회
Mobile QR Code QR CODE : The Transactions of the Korean Institute of Electrical Engineers
  • COPE
  • kcse
  • 한국과학기술단체총연합회
  • 한국학술지인용색인
  • Scopus
  • crossref
  • orcid
The Transactions of the Korean Institute of Electrical Engineers

The Transactions of the Korean Institute of Electrical Engineers

ISO Journal TitleTrans. Korean. Inst. Elect. Eng.
SCImago Journal & Country Rank

Journal Search

  1. Home
  2. Archive
  3. 2021-07 (Vol.70 No.7)
  4. 10.5370/KIEE.2021.70.7.953
XML PDF INFO REF

References

1 
Yang-Hyun Nam, Sung-Sik Choi, Min-Kwan Kang, Hu-Dong Lee, Ji-Hyun Park, Dae-Seok Rho, 2018, A Study on the Large-scale Adoption Method of Distribution System Interconnected with PV System by Energy Storage System, The Transactions of the Korean Institute of Electrical Engineers, Vol. 67, No. 8, pp. 1031-1039DOI
2 
Global Wind Energy Council, 2020, GWEC Global Wind ReportGoogle Search
3 
Korea Wind Energy Industry Association, 2018, 2018 Annual Report on Wind Energy Industry in KoreaGoogle Search
4 
E.P.P. Soares-Ramos, L. de Oliveira-Assis, R. Sarrias-Mena,, L.M. Fernández-Ramírez, 2020, Current status and future trends of offshore wind power in Europe Energy, Vol. 202, pp. 117787Google Search
5 
Beom-Keun Seo, Yeon-Hee Kim, Ji-Hee Kim, Baek-Jo Kim, 2017, Comparison of Wind Resource Characteristics in Korea According to Different Mapping Method, New & Renewable Energy, Vol. 13, No. 4, pp. 23-38Google Search
6 
Z. R. Shu, Q. S. Li, P. W. Chan, 2015, Investigation of offshore wind energy potential in Hong Kong based on Weibull distribution function, Applied Energy 156 (2015), pp. 362-373DOI
7 
C. L. Archer, M. Z. Jacobson, 2005, Evaluation of global wind power, J. Geophys. Res., Vol. 110, No. D12110Google Search
8 
Desmond Cian, Murphy Jimmy, Blond Lindert, Haans Wouter, 2016, Description of an 8MW Reference Wind Turbine, J. Phys. Conf. Ser., Vol. 753, No. 092013Google Search
9 
Feng Ju, Zhong Shen Wen, 2017, Design optimization of offshore wind farms with multiple types of wind turbines, Applied Energy 205, pp. 1283-1297DOI
10 
T. Ashuri, M. B. Zaaijer, J. R. R. A. Martins, G. J. W. van Bussel, G. A. M. van Kuik, 2014, Multidisciplinary design optimization of offshore wind turbines for minimum levelized cost of energy, Renewable Energy 68, pp. 893-905DOI
11 
Chaouachi Aymen, Felix Covriga Catalin, Ardelean Mircea, 2017, Multi-criteria selection of offshore wind farms: Case study for the Baltic States, Energy Policy 103, pp. 179-192DOI
12 
Dahmani Ouahid, Bourguet Salvy, Machmoum Mohamed, Guerin Patrick, Rhein Pauline, Lionel Josse and, 2017, Optimi- zation and Reliability Evaluation of an Offshore Wind Farm ArchitectureDesign optimization of offshore wind farms with multiple types of wind turbines, IEEE Trans. Sustain. Energy, Vol. 8, No. 2DOI
13 
Je-Seok Shin, Jin-O Kim, 2017, Optimal Design for Offshore Wind Farm considering Inner Grid Layoutand Offshore Substation Location. IEEE Trans. Power Syst., vol.32, no.3, pp.2041-2048, 2017., IEEE Trans. Power Syst, Vol. 32, No. 3, pp. 2041-2048DOI
14 
H. Ergun, D. Van Hertem, R. Belmans, 2012, Transmission system topology optimization for large-scale offshore wind integration, IEEE Trans. Sustain. Energy, Vol. 3, No. 4, pp. 908-917DOI
15 
D. Elliott, Jul 2016, A comparison of AC and HVDC options for the connection of offshore wind generation in great britain, IEEE Trans. Power Del., Vol. 31, No. 2, pp. 798-809DOI
16 
P. Bresesti, W. Kling, R. Hendriks, R. Vailati, Mar 2007, HVDC connection of offshore wind farms to the transmission system, IEEE Trans. Energy Convers., Vol. 22, No. 1, pp. 37-43DOI
17 
B. Van Eeckhout, D. Van Hertem, M. Reza, K. Srivastava, R. Belmans, Jul 2010, Economic comparison of VSC HVDC and HVAC as transmission system for a 300 MW offshore wind farm, Eur. Trans. Elect. Power, Vol. 20, No. 5, pp. 661-671DOI
18 
A. Ioannou, A. Angus, F. Brennan, May 2018, Parametric CAPEX, OPEX, and LCOE expressions for offshore wind farms based on global deployment parameters, Energy Sources, Part B Econ Planning, Vol. 13, No. 5, pp. 281-290DOI
19 
J. Chen, F. Wang, S. Kim, 2018, A mathematical approach to minimizing the cost of energy for large utility wind turbines, Appl. Energy 228, pp. 1413-1422DOI
20 
Won-Sik Moon, Jong-Nam Won, Jae-Sun Huh, Ara Jo, Jae-Chul Kim, 2015, Optimal Design of Power Grid and Location of Offshore Substation for Offshore Wind Power Plant, The Transactions of the Korean Institute of Elec- trical Engineers, Vol. 64, No. 7, pp. 984-991DOI
21 
Won-Sik Moon, Ara Jo, Jae-Chul Kim, 2015, Economic Eva- luation of Power Grid Interconnection between Offshore Wind Power Plants, The Transactions of the Korean Institute of Electrical Engineers P, Vol. 64, No. 7, pp. 984-991DOI
22 
Angel G. Gonzalez-Rodriguez, 2017, Review of offshore wind farm cost components, Energy for Sustainable Development, Vol. 37, pp. 10-19DOI
23 
M.Dicorato, G. Forte, M. Pisani, M. Trovato, 2011, Guidelines for assessment of investment cost for offshore wind generation, Renew. Energy, Vol. 36, pp. 2043-2051DOI
24 
S. Cavazzi, A.G. Dutton, 2016, An Offshore Wind Energy Geographic Information System (OWE-GIS) for assessment of the UK's offshore wind energy potential, Renewable Energy, Vol. 87, pp. 212-228DOI
25 
J. Warnock, D. McMillan, J. Pilgrim, and S. Shenton, 2019, Failure rates of offshore wind transmission systems, Energies, Vol. 12, No. 14, pp. 1-12DOI