Acknowledgement
본 연구는 2022년도 산업통상자원부의 재원으로 한국에너지기술평가원의 신재생에너지 핵심기술 개발사업(과제번호 : 20203040020130) 및 한국전력공사의 재원으로 수행된 "해상풍력 지지구조 최적화 설계기술 개발(R22EA12)" 연구 결과의 일부입니다.
References
- Berkenhagen, J., Doring, R., Fock, H.O., Kloppmann, M.H., Pedersen, S.A. and Schulze, T., 2010, Decision bias in marine spatial planning of offshore wind farms: problems of singular versus cumulative assessments of economic impacts on fisheries, Marine policy, 34(3), pp.733-736.
- Ashley, M.C., Mangi, S.C., and Rodwell, L.D., 2014, The potential of offshore windfarms to act as marine protected areas - A systematic review of current evidence, Marine Policy, 45, pp.301-309.
- Hooper, T. and Austen, M., 2014, The co-location of offshore windfarms and decapod fisheries in the UK: Constraints and opportunities, Marine Policy, 43, pp.295-300.
- Griffin, R., Buck, B. and Krause, G., 2015, Private incentives for the emergence of co-production of offshore wind energy and mussel aquaculture. Aquaculture, 436, pp.80-89.
- Kang, KS., Jeon, I.S., Kwak, J.Y., 2016, Possibilities and Orientation toward Co-existaence of Offshore Wind Farms, J. of Wind Energy, KWEA, pp.5-13
- Hooper, T., Ashley, M. and Austen, M., 2018, Capturing benefits: opportunities for the co-location of offshore energy and fisheries. In Offshore Energy and Marine Spatial Planning, pp. 189-213.
- Schupp, M.F., Kafas, A., Buck, B.H., Krause, G., Onyango, V., Stelzenmiiller, V., Davies, I. and Scott, B.E., 2021, Fishing within offshore wind farms in the North Sea: Stakeholder perspectives for multi-use from Scotland and Germany. Journal of Environmental Management, 279, p.111762.
- Stenberg, C., Christoffersen, M.O., Krog, C., Patrizio, M. and Dolmer, P., 2010, Offshore wind farms and their potential for shellfish aquaculture and restocking. ICES CM.
- Stelzenmiiller, V., Diekmann, R., Bastardie, F., Schulze, T., Berkenhagen, J., Kloppmann, M., Krause, G., Pogoda, B., Buck, B.H. and Kraus, G., 2016, Co-location of passive gear fisheries in offshore wind farms in the German EEZ of the North Sea- A first socio-economic scoping. Journal of Environmental Management, 183, pp.794-805.
- Lengkeek, W., Didderen, K, Teunis, M., Driessen, F., Coolen, J.W.P., Bos, O.G., Vergouwen, S.A., Raaijmakers, T., De Vries, M.B. and Van Koningsveld, M., 2017, Eco-friendly design of scour protection: potential enhancement of ecological functioning in offshore wind farms: Towards an implementation guide and experimental set-up (No. 17-001). Bureau Waardenburg.
- Xu, Z. and Qin, H, 2020, Fluid-structure interactions of cage based aquaculture- From structures to organisms. Ocean Engineering, 217, p.107961.
- Guo, Y.C., Mohapatra, S.C. and Soares, C.G., 2020, Review of developments in porous membranes and net-type structures for breakwaters and fish cages. Ocean Engineering, 200, p.107027.
- Cardia, F., Ciattaglia, A. and Comer, R.A., 2017, Guidelines and Criteria on Technical and Environmental Aspects of Cage Aquaculture Site Selection in the Kingdom of Saudi Arabia.
- Shuchuang Dong, Xingxing You and Fuxiang Hu., 2020, Effects of design factors on drag forces and deformations on marine aquaculture cages: A parametric study based on numerical Simulations, Journal of Marine Science and Engineering., 8(2), 125
- Hao Chen and Erik Damgaard Christensen., 2017, Development of a numerical model for fluid-structure interaction analysis of flow through and around an aquaculture net cage, Ocean Engineering, pp.597-615.
- Francois, M., Davies, P., 2000. Fiber rope deep water mooring: a practical model for the analysis of polyester mooring system. Rio Oil and Gas Conference, IBP24700, Rio de Janeiro, Brazil, 16-19 October 2000, pp.1-10
- The application of fiber rope for offshore mooring, ABS Guidance notes, 2021
- Ministry of Oceans and Fisheries, 2019, National Deep water design wave report (in Korean)
- Huang, C.C., Tang, H.J. and Liu, J.Y., 2008, Effects of waves and currents on gravity-type cages in the open sea. Aquacultural Engineering, 38(2), pp. 105-116.