Verfügbarkeit: Ocean energy conversion systems

Ocean energy conversion systems: an innovative concept approach

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Bibliographische Detailangaben
1. Verfasser:	Scharmann, Nik (VerfasserIn)
Format:	Abschlussarbeit Buch
Sprache:	English
Veröffentlicht:	Hamburg 2018
Schlagworte:	Offshore-Technik Hochschulschrift
Online-Zugang:	Inhaltsverzeichnis Inhaltsverzeichnis
Beschreibung:	Literaturverzeichnis: Seite [130]-136
Beschreibung:	viii, 148 Seiten Illustrationen, Diagramme, Karten 30 cm

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Datensatz im Suchindex

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adam_text	C ON TEN TS NOMENCLATURE...................................................................................................... VII 1. SCOPE OF WORK 1 2. OCEAN WAVE ENERGY AS A GLOBAL ENERGY RESOURCE 3 2.1. LOCATION AND MAGNITUDE OF THE WAVE RE SO U RC E ....................................... 3 2.2. INTEGRATION WITH OTHER RENEWABLE ENERGY SOURCES .................................... 5 3. PERFORMANCE INDICATORS AND REQUIREMENT ANALYSIS FOR WAVE ENERGY CONVERT ERS 7 3.1. LEVELIZED COST OF ENERGY AS KEY PERFORMANCE INDICATOR ........................... 7 3.2. WEC REQUIREMENTS DERIVED FROM LCOE-NETWORK A N A LY S IS .................. 8 3.3. THE WAVE RESOURCE AT A SPECIFIC SITE AND ITS TECHNICAL ATTRIBUTES .... 11 4. THE INNOVATION HYPOTHESIS AND GENERAL APPROACH 15 4.1. THE CONTEXT OF OCEAN WAVE ENERGY CO N V ERSIO N ....................................... 15 4.2. THE WH-WEC INNOVATION HYPOTHESIS ...................................................... 17 5. CONCEPTUAL DESIGN SPACE 21 5.1. SITE DISCOVERY AND RANKING ..................................................................... 21 5.2. FUNCTIONAL ANALYSIS AND TECHNICAL BREAKDOWN-STRUCTURE ........................ 31 5.3. CONCEPT DISCOVERY AND R A N K IN G ............................................................... 31 5.3.1. ROTOR C ONCEPTS.............................................................................. 31 5.3.1.1. MAPPING OF SYSTEM REQUIREMENTS TO TECHNICAL ROTOR AT TRIBUTES ........................................................................... 34 5.3.1.2. CONVERTING ENERGY WITH THE DYNAMIC LIFTING HYDROFOIL C O N CE P T........................................................................... 35 5.3.1.3. CONVERTING ENERGY WITH THE FLETTNER C O N C E P T ............ 40 5.3.1.4. CONVERTING ENERGY WITH THE SAVONIUS CONCEPT .... 40 5.3.1.5. RANKING OF ROTOR CONCEPTS ............................................. 42 5.3.1.6. ORDER OF MAGNITUDE FORCES AND TORQUES ..................... 42 5.3.2. POWER-TAKE-OFF C O N C E P TS ............................................................ 45 5.3.2.1. MAPPING OF SYSTEM REQUIREMENTS TO TECHNICAL PTO AT TRIBUTES ........................................................................... 46 5.3.2.2. MECHANICAL GEARBOX WITH A D G A S G ........................... 48 5.3.2.3. HYDROSTATIC GEAR WITH A PM SG /FESG .......................... 49 5.3.2.4. DIRECTLY DRIVEN PMSG WITH F C .................................... 50 5.3.2.5. RANKING OF PTO CONCEPTS ............................................. 51 5.3.3. S U B S TRU C TU RE .................................................................................. 51 5.3.3.1. MAPPING OF SYSTEM REQUIREMENTS TO TECHNICAL SUBSTRUC TURE A TTRIB U TE S ............................................................... 53 5.3.3.2. UNDER-CRITICAL SUBSTRUCTURES .......................................... 57 5.3.3.3. OVER-CRITICAL S U B STRU C TU RE S .......................................... 64 5.3.3.4. RANKING OF SUBSTRUCTURE CONCEPTS .............................. 68 5.3.3.5. ORDER OF MAGNITUDE WEIGHTS AND DIM ENSION ............... 68 5.3.4. INSTALLATION CO N CEP TS...................................................................... 68 5.3.4.1. MAPPING OF SYSTEM REQUIREMENTS ON INSTALLATION AT TRIBUTES ............................................................................ 72 5.3.42. D P H L V ........................................................................ 72 5.3.4.3. CRANE B A R G E .................................................................. 73 5.3.4.4. SHEERLEG C RA N E ............................................................... 74 5.3.4.5. RANKING OF INSTALLATION C O N C E P TS ................................. 74 5.3.5. MAINTENANCE CONCEPT ..................................................................... 76 5.3.5.1. WEC MAINTENANCE ......................................................... 77 5.3.5.2. PTO M AINTENANCE ......................................................... 78 5.4. CONCEPT INTEGRATION ON W E C -LEV EL......................................................... 78 6. IMPLEMENTATION OF PRIORISED CONCEPTS 81 6.1. HYDRODYNAMICAL MODELS FOR WAVE-HYDROFOIL IN TE RA C TIO N ........................ 81 6.1.1. VIRTUAL MODELS AND MODELING R E S U LTS .......................................... 82 6.1.1.1. NUMERIC M O D E LS ............................................................ 85 6.1.1.2. OPTIMIZATION OF ROTOR D E S IG N ....................................... 87 6.1.2. V ERIFICATION..................................................................................... 94 6.1.3. 3D-DOMINATED SCALED MODELS ...................................................... 94 6.1.4. 2D-PERFORMANCE PREDICTION IN REALISTIC SEA S T A T E S ..................... 96 6.1.5. 3D BEHAVIOR OF THE R O TO R ............................................................... 97 6.2. MECHANICAL MODELS FOR DESIGNING THE W H -W E C .................................... 98 6.2.1. ULTIMATE LIMIT STATE FORCES ON THE W E C .................................... 99 6.2.2. WEC-MODULE ..................................................................................100 6.2.3. JACKET S U B S TRU C TU RE .........................................................................103 6.2.4. LAUNCH AND RECOVERY SYSTEM .............................................................104 6.3. ELECTRICAL AND HYDROSTATIC MODELS FOR THE POWER-TAKE-OFF AND GRID CON NECTION ............................................................................................................. 106 6.4. INSTALLATION AND MAINTENANCE M O D E LS ......................................................... 108 6.4.1. P RE-P ILING...........................................................................................109 6.4.2. INSTALLATION OF WH-WEC ................................................................112 6.4.3. MAINTENANCE M ODEL............................................................................113 6.4.3.1. WEC M AINTENANCE.............................................................114 6.4.3.2. PTO M AINTENANCE.............................................................116 6.4.4. DISCUSSION OF MAINTENANCE INTERVENTIONS ....................................... 117 6.5. INTEGRATION OF MODELING RESULTS ..................................................................118 6.5.1. ENERGY YIELD ESTIMATIONS FOR EMEC .......................................... 118 6.5.1.1. MECHANICAL ENERGY YIELD ESTIMATION .............................. 118 6.5.1.2. CONDITIONED ELECTRICAL ENERGY SELLABLE TO CUSTOMERS . . 119 6.5.2. LCOE 20AK AT E M E C .................................................................. 121 7. DISCUSSION 123 7.1. OUTLOOK ON LEARNING EFFECTS ........................................................................ 123 7.2. OUTLOOK ON ALTERNATIVE S I T E S ........................................................................ 124 7.3. OUTLOOK ON ALTERNATIVE INTEGRATIONS ............................................................ 125 7.4. DISCUSSION ....................................................................................................126 BIBLIOGRAPHY 129 A. APPENDIX 137 A.L. NUMERIC VALUES OF THE PREFERRED WH-WEC ROTOR CONFIGURATION.................139 A.2. TASK LISTINGS OF MARINE OPERATIONS ............................................................... 140
adam_txt	C ON TEN TS NOMENCLATURE. VII 1. SCOPE OF WORK 1 2. OCEAN WAVE ENERGY AS A GLOBAL ENERGY RESOURCE 3 2.1. LOCATION AND MAGNITUDE OF THE WAVE RE SO U RC E . 3 2.2. INTEGRATION WITH OTHER RENEWABLE ENERGY SOURCES . 5 3. PERFORMANCE INDICATORS AND REQUIREMENT ANALYSIS FOR WAVE ENERGY CONVERT ERS 7 3.1. LEVELIZED COST OF ENERGY AS KEY PERFORMANCE INDICATOR . 7 3.2. WEC REQUIREMENTS DERIVED FROM LCOE-NETWORK A N A LY S IS . 8 3.3. THE WAVE RESOURCE AT A SPECIFIC SITE AND ITS TECHNICAL ATTRIBUTES . 11 4. THE INNOVATION HYPOTHESIS AND GENERAL APPROACH 15 4.1. THE CONTEXT OF OCEAN WAVE ENERGY CO N V ERSIO N . 15 4.2. THE WH-WEC INNOVATION HYPOTHESIS . 17 5. CONCEPTUAL DESIGN SPACE 21 5.1. SITE DISCOVERY AND RANKING . 21 5.2. FUNCTIONAL ANALYSIS AND TECHNICAL BREAKDOWN-STRUCTURE . 31 5.3. CONCEPT DISCOVERY AND R A N K IN G . 31 5.3.1. ROTOR C ONCEPTS. 31 5.3.1.1. MAPPING OF SYSTEM REQUIREMENTS TO TECHNICAL ROTOR AT TRIBUTES . 34 5.3.1.2. CONVERTING ENERGY WITH THE DYNAMIC LIFTING HYDROFOIL C O N CE P T. 35 5.3.1.3. CONVERTING ENERGY WITH THE FLETTNER C O N C E P T . 40 5.3.1.4. CONVERTING ENERGY WITH THE SAVONIUS CONCEPT . 40 5.3.1.5. RANKING OF ROTOR CONCEPTS . 42 5.3.1.6. ORDER OF MAGNITUDE FORCES AND TORQUES . 42 5.3.2. POWER-TAKE-OFF C O N C E P TS . 45 5.3.2.1. MAPPING OF SYSTEM REQUIREMENTS TO TECHNICAL PTO AT TRIBUTES . 46 5.3.2.2. MECHANICAL GEARBOX WITH A D G A S G . 48 5.3.2.3. HYDROSTATIC GEAR WITH A PM SG /FESG . 49 5.3.2.4. DIRECTLY DRIVEN PMSG WITH F C . 50 5.3.2.5. RANKING OF PTO CONCEPTS . 51 5.3.3. S U B S TRU C TU RE . 51 5.3.3.1. MAPPING OF SYSTEM REQUIREMENTS TO TECHNICAL SUBSTRUC TURE A TTRIB U TE S . 53 5.3.3.2. UNDER-CRITICAL SUBSTRUCTURES . 57 5.3.3.3. OVER-CRITICAL S U B STRU C TU RE S . 64 5.3.3.4. RANKING OF SUBSTRUCTURE CONCEPTS . 68 5.3.3.5. ORDER OF MAGNITUDE WEIGHTS AND DIM ENSION . 68 5.3.4. INSTALLATION CO N CEP TS. 68 5.3.4.1. MAPPING OF SYSTEM REQUIREMENTS ON INSTALLATION AT TRIBUTES . 72 5.3.42. D P H L V . 72 5.3.4.3. CRANE B A R G E . 73 5.3.4.4. SHEERLEG C RA N E . 74 5.3.4.5. RANKING OF INSTALLATION C O N C E P TS . 74 5.3.5. MAINTENANCE CONCEPT . 76 5.3.5.1. WEC MAINTENANCE . 77 5.3.5.2. PTO M AINTENANCE . 78 5.4. CONCEPT INTEGRATION ON W E C -LEV EL. 78 6. IMPLEMENTATION OF PRIORISED CONCEPTS 81 6.1. HYDRODYNAMICAL MODELS FOR WAVE-HYDROFOIL IN TE RA C TIO N . 81 6.1.1. VIRTUAL MODELS AND MODELING R E S U LTS . 82 6.1.1.1. NUMERIC M O D E LS . 85 6.1.1.2. OPTIMIZATION OF ROTOR D E S IG N . 87 6.1.2. V ERIFICATION. 94 6.1.3. 3D-DOMINATED SCALED MODELS . 94 6.1.4. 2D-PERFORMANCE PREDICTION IN REALISTIC SEA S T A T E S . 96 6.1.5. 3D BEHAVIOR OF THE R O TO R . 97 6.2. MECHANICAL MODELS FOR DESIGNING THE W H -W E C . 98 6.2.1. ULTIMATE LIMIT STATE FORCES ON THE W E C . 99 6.2.2. WEC-MODULE .100 6.2.3. JACKET S U B S TRU C TU RE .103 6.2.4. LAUNCH AND RECOVERY SYSTEM .104 6.3. ELECTRICAL AND HYDROSTATIC MODELS FOR THE POWER-TAKE-OFF AND GRID CON NECTION . 106 6.4. INSTALLATION AND MAINTENANCE M O D E LS . 108 6.4.1. P RE-P ILING.109 6.4.2. INSTALLATION OF WH-WEC .112 6.4.3. MAINTENANCE M ODEL.113 6.4.3.1. WEC M AINTENANCE.114 6.4.3.2. PTO M AINTENANCE.116 6.4.4. DISCUSSION OF MAINTENANCE INTERVENTIONS . 117 6.5. INTEGRATION OF MODELING RESULTS .118 6.5.1. ENERGY YIELD ESTIMATIONS FOR EMEC . 118 6.5.1.1. MECHANICAL ENERGY YIELD ESTIMATION . 118 6.5.1.2. CONDITIONED ELECTRICAL ENERGY SELLABLE TO CUSTOMERS . . 119 6.5.2. LCOE 20AK AT E M E C . 121 7. DISCUSSION 123 7.1. OUTLOOK ON LEARNING EFFECTS . 123 7.2. OUTLOOK ON ALTERNATIVE S I T E S . 124 7.3. OUTLOOK ON ALTERNATIVE INTEGRATIONS . 125 7.4. DISCUSSION .126 BIBLIOGRAPHY 129 A. APPENDIX 137 A.L. NUMERIC VALUES OF THE PREFERRED WH-WEC ROTOR CONFIGURATION.139 A.2. TASK LISTINGS OF MARINE OPERATIONS . 140
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spelling	Scharmann, Nik Verfasser (DE-588)1156756235 aut Ocean energy conversion systems an innovative concept approach von Nik Scharmann Hamburg 2018 viii, 148 Seiten Illustrationen, Diagramme, Karten 30 cm txt rdacontent n rdamedia nc rdacarrier Literaturverzeichnis: Seite [130]-136 Dissertation Technische Universität Hamburg-Harburg 2017 Offshore-Technik (DE-588)4125537-9 gnd rswk-swf (DE-588)4113937-9 Hochschulschrift gnd-content Offshore-Technik (DE-588)4125537-9 s DE-604 Kaltschmitt, Martin 1961- (DE-588)115399704 oth Hoffmann, Norbert 1969- (DE-588)113319978X oth B:DE-101 application/pdf http://d-nb.info/1159983615/04 Inhaltsverzeichnis DNB Datenaustausch application/pdf http://bvbr.bib-bvb.de:8991/F?func=service&doc_library=BVB01&local_base=BVB01&doc_number=032663971&sequence=000001&line_number=0001&func_code=DB_RECORDS&service_type=MEDIA Inhaltsverzeichnis
spellingShingle	Scharmann, Nik Ocean energy conversion systems an innovative concept approach Offshore-Technik (DE-588)4125537-9 gnd
subject_GND	(DE-588)4125537-9 (DE-588)4113937-9
title	Ocean energy conversion systems an innovative concept approach
title_auth	Ocean energy conversion systems an innovative concept approach
title_exact_search	Ocean energy conversion systems an innovative concept approach
title_exact_search_txtP	Ocean energy conversion systems an innovative concept approach
title_full	Ocean energy conversion systems an innovative concept approach von Nik Scharmann
title_fullStr	Ocean energy conversion systems an innovative concept approach von Nik Scharmann
title_full_unstemmed	Ocean energy conversion systems an innovative concept approach von Nik Scharmann
title_short	Ocean energy conversion systems
title_sort	ocean energy conversion systems an innovative concept approach
title_sub	an innovative concept approach
topic	Offshore-Technik (DE-588)4125537-9 gnd
topic_facet	Offshore-Technik Hochschulschrift
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