Ringsberg J.W.Jansson H.?rg?rd M.Yang S.-H.Johnson E.SHUN-HAN YANG2022-05-242022-05-242020https://www.scopus.com/inward/record.uri?eid=2-s2.0-85083916302&doi=10.1115%2f1.4045370&partnerID=40&md5=90ec128bb268bda6143c7adec50a806chttps://scholars.lib.ntu.edu.tw/handle/123456789/611680Most of the ocean energy technologies are considered to be in a pre-commercial phase and need technical development. This study focuses on the design of mooring solutions and compares array systems of a specific floating point-absorbing wave energy converter (WEC) developed by the company Waves4Power. A full-scale prototype of the WEC is installed in Runde (Norway) where it is moored with three polyester mooring lines, each having one floater and one gravity anchor. Based on this reference installation, the method of systems engineering was used to propose 22 conceptual mooring solutions for different array systems. They were compared and reduced to four top concepts in a systematic elimination procedure using Pugh and Kesselring matrices. The top concepts were assessed in detail by means of levelized cost of energy (LCOE), life cycle analysis (LCA), and risk analyses. The fatigue life of the mooring lines and the energy capture were calculated using results obtained from coupled hydrodynamic and structure response analyses in the dnv-gl deepc software. Two final concepts were proposed for the water depths 75 and 200 m. ? 2020 Royal Society of Chemistry. All rights reserved.Digital arithmeticLife cycleMooringMooring cablesRisk analysisRisk assessmentElimination procedureFloating pointsGravity anchorsLevelized costsLife cycle analysisPolyester mooring linesStructure responseTechnical developmentWave energy conversionanchorarraydesignfloating bodyhydrodynamicsinstallationlife cycle analysispolymertechnological developmentwave energyMore og RomsdalNorwayRunde[SDGs]SDG12journal article10.1115/1.40453702-s2.0-85083916302