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1 - Introduction to Ship-Shaped Offshore Installations

Published online by Cambridge University Press:  27 January 2022

Jeom Kee Paik
Jeom Kee Paik
Affiliation:
University College London
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Summary

Various types of engineering structures have been developed over the course of human civilisation. One type is the ship-shaped offshore installation, which is a floating structural system located at sea. As a result of their multiple functionalities, these installations are widely used in the production, processing and storage of energy derived from marine sources and electrical power generation in a marine environment.

Type
Chapter
Information
Ship-Shaped Offshore Installations
Design, Construction, Operation, Healthcare and Decommissioning
 , pp. 1 - 48
Publisher: Cambridge University Press
Print publication year: 2022

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References

Assayag, S., Prallon, E. and Sartori, F. (1997). ‘Improvements in design of converted FPSOs regarding 20 years operation without docking’. Offshore Technology Conference, OTC 8389, Houston, TX, 5–8 May.CrossRefGoogle Scholar
Biasotto, P., Bonniol, V. and Cambos, P. (2005). ‘Selection of trading tankers for FPSO conversion projects’. Offshore Technology Conference, OTC 17506, Houston, TX, 2–5 May.Google Scholar
Boggs, D., Barton, C., Albaugh, E. K. and Davis, D. (2021). ‘2021 worldwide survey of floating production, storage and offloading (FPSO) units’. Offshore Magazine / Endeavor Business Media, Houston, TX, July/August.Google Scholar
Cabrera-Miranda, J. M., Sakugawa, P. M., Corona-Tapia, R. and Paik, J. K. (2018). ‘On design criteria for a disconnectable FPSO mooring system associated with expected life-cycle cost’. Ships and Offshore Structures, 13(4): 432442.Google Scholar
Cong, H., Haiying, M. and Zaijin, Y. (2018). ‘Study on the distribution of wave energy resources in China and the applicability of wave energy generation device’. Ocean Science, 42(3): 142148.Google Scholar
da Costa Filho, F. H. (1997). ‘The world’s biggest conversion’. Offshore Technology Conference, OTC 8407, Houston, TX, 5–8 May.Google Scholar
Devanney, J. (2020). Why Nuclear Power Has Been a Flop at Solving the Gordian Knot of Electricity Poverty and Global Warming. The CTX Press, Stevenson, WA.Google Scholar
Dicson, T., Farr, H., Sear, D. and Blake, J. I. R. (2019). ‘Uncertainty in marine weather routing’. Applied Ocean Research, 88, doi: 10.1016/j.apor.2019.04.008.Google Scholar
Gkerekos, C. and Lazakis, I. (2020). ‘A novel, data-driven heuristic framework for vessel weather routing’. Ocean Engineering, 197, doi: 10.1016/j.oceaneng.2019.106887.Google Scholar
HSE (2003). Margins of Safety in FPSO Hull Strength. Research Report 083, Health and Safety Executive, London.Google Scholar
IACS (2020). Common Structural Rules for Bulk Carriers and Oil Tankers. International Association of Classification Societies, London.Google Scholar
IMO (2003). Guidelines for Application of MARPOL Annex I Requirements to FPSOs and FSUs. MEPC/Circ. 406, International Maritime Organization, London.Google Scholar
Johnson, M. (1996). ‘Application of the ABS/SafeHull technology to FPSO conversions’. Presented at the Annual Meeting of the Texas Section, The Society of Naval Architects and Marine Engineers, Alexandria, VA, 23 February.Google Scholar
Kristensen, H. O. (2012). Determination of regression formulas for main dimensions of tankers and bulk carriers based on IHS Fairplay data. Project no. 2010-56, Emissionsbeslutningsstøttesystem Work Package 2, Report no. 02, Technical University of Denmark, Lyngby.Google Scholar
Kurosawa, K., Uchiyama, Y. and Kosako, T. (2020). ‘Development of a numerical marine weather routing system for coastal and marginal seas using regional oceanic and atmospheric simulations’. Ocean Engineering, 195, doi: 10.1016/j.oceaneng.2019.106706.CrossRefGoogle Scholar
Lane, J. A., Bryans, R. and Preston, R. (2004). ‘Conversion of the TT Sahara to FPSO Fluminense, a low cost solution for the Bijupira and Salema field development, offshore Brazil’. Offshore Technology Conference, OTC 16707, Houston, TX, 3–6 May.Google Scholar
Ma, K., Luo, Y., Kwan, T. and Wu, Y. (2019). Mooring System Engineering for Offshore Structures, Gulf Professional Publishing, Cambridge, MA.Google Scholar
McCormick, M. E. (2013). Ocean Wave Energy Conversion, Dover Publications, New York.Google Scholar
Mansour, A. E., Pedersen, P. T. and Paik, J. K. (2013). ‘Wave energy extraction using decommissioned ships’. Ships and Offshore Structures, 8(5): 504516.CrossRefGoogle Scholar
Mones, M. (2004). ‘Hull structural assessment and refurbishment for conversion FPSOs’. Proceedings of ASMR-PTI FPSO Integrity Workshop, American Society Mechanical Engineers/Petroleum Technology Institute, Houston, TX, 30 August–2 September.Google Scholar
Neto, T. G. and de Souza Lima, H. A. (2001). ‘Conversion of tankers into FPSOs: practical design experiences’. Offshore Technology Conference, OTC 13209, Houston, TX, 30 April–3 May.Google Scholar
Olsen, A. S., Schroter, C. and Jensen, J. J. (2006). ‘Wave height distribution observed by ships in the North Atlantic’. Ships and Offshore Structures, 1(1): 112.CrossRefGoogle Scholar
Paik, J. K. (2018). Ultimate Limit State Analysis and Design of Plated Structures. 2nd Edition, John Wiley & Sons, Chichester.Google Scholar
Paik, J. K. (2019). Structural Designs of a Hypothetical Ship-Shaped Nuclear Power-Plant Hull. Technical Report to ThorCon Power, Department of Mechanical Engineering, University College London, London.Google Scholar
Paik, J. K. (2020). Advanced Structural Safety Studies with Extreme Conditions and Accidents. Springer, Singapore.Google Scholar
Park, I. K., Jang, Y. S., Shin, H. S. and Yang, Y. T. (1998). ‘Conceptual design and analyses of deep-sea FPSO converted from VLCC’. Offshore Technology Conference, OTC 8809, Houston, TX, 4–7 May.Google Scholar
Parker, G. (1999a). The FPSO Design and Construction Guidance Manual. Reserve Technology Institute, Houston, TX.Google Scholar
Parker, G. (1999b). The FPSO Design and Construction Guidance Manual: A Reference Guide to Successful Projects Designing and Constructing FPSOs in all Water Depths. Reserve Technology Institute, Houston, TX.Google Scholar
Sparenberg, O. (2019). ‘A historical perspective on deep-sea mining for manganese nodules, 1965–2019’. The Extractive Industries and Society, 6(3): 842854.Google Scholar
Szlapczynska, J. and Szlapczynski, R. (2019). ‘Preference-based evolutionary multi-objective optimization in ship weather routing’. Applied Soft Computing Journal, 84, doi: 10.1016/j.asoc.2019.105742.Google Scholar
Terpstra, T., d’Hautefeuille, B. B. and MacMillan, A. A. (2001). ‘FPSO design and conversion: A designer’s approach’. Offshore Technology Conference, OTC 13210, Houston, TX, 30 April–3 May.Google Scholar
Terpstra, T., Schouten, G. and Ursini, L. (2004). ‘Design and conversion of FPSO Mystras’. Offshore Technology Conference, OTC 16198, Houston, TX, 3–6 May.Google Scholar
ThorCon (2019). Design of ThorConIsle (www.thorconpower.com). Stevenson, WA.Google Scholar
Voogt, A. and Buchner, B. (2004). ‘Wave impacts excitation on ship-type offshore structures in steep fronted waves’. Proceedings of OMAE Specialty Symposium on Integrity of Floating Production, Storage & Offloading (FPSO) Systems, OMAE-FPSO’04-0062, Houston, TX, 30 August–2 September.Google Scholar
Wang, G. (2003). ‘Experience based data for FPSO’s structural design’. Offshore Technology Conference, OTC 15068, Houston, TX, 5–8 May.CrossRefGoogle Scholar

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