Stability of Offshore Systems

Aubault, Alexia; Ertekin, R. Cengiz

doi:10.1007/978-3-319-16649-0_34

Alexia Aubault³ &
R. Cengiz Ertekin⁴

Part of the book series: Springer Handbooks ((SHB))

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Abstract

Stability analysis is a major aspect of the design of offshore platforms. It focuses on averting any failures associated with excessive heel or trim, capsizing, catastrophic loss of buoyancy, or even sinking. In this chapter, we cover the buoyancy and stability of offshore platforms from both viewpoints of theoretical and regulatory issues. Intact and damaged stability of floating structures are discussed and essential formulations of the associated problems are introduced. In doing so, the stability of a platform (its ability to be at or to recover equilibrium at acceptable heel and/or trim angles) is assessed by comparison of the righting moment to overturning moments from external loads. Methods of calculating the righting moment that varies with the heel angle are discussed. At small heel and trim angles, the metacentric height and displacement may be used directly to calculate the righting arm. Overturning moments that account for all static loads, including environmental, operational, and live loads are listed as well. Assumptions are needed to calculate the applied loads, and stability analysis does not usually include the upsetting dynamic forces. To address these issues, regulators set criteria, with embedded safety factors, and they require sufficient reserve stability beyond the equilibrium of the platform. These and the risks associated with flooding are addressed through hull subdivision and damaged analysis in this chapter.

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Abbreviations

2-D:: two-dimensional
3-D:: three-dimensional
AWM:: added-weight method
CBM:: constant-buoyancy method
FPSO:: floating production, storage and offloading
LBM:: lost-buoyancy method
LCB:: longitudinal center of buoyancy
LCF:: longitudinal center of flotation
LCG:: longitudinal center of gravity
MCTC:: moment to change trim by one centimeter
MODU:: mobile offshore drilling unit
MWL:: mean-water level
TCB:: transverse center of buoyancy
TCG:: transverse center of gravity
TLP:: tension leg platform
VCB:: vertical center of buoyancy
VCG:: vertical center of gravity

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Authors and Affiliations

Principle Power Inc., 2321 4th Street, CA 94710, Berkeley, California, USA
Alexia Aubault
Dep. Ocean & Resources Engineering, University of Hawaii at Manoa, 2540 Dole Street, Holmes Hall 402, HI 96822, Honolulu, Hawaii, USA
R. Cengiz Ertekin

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Alexia Aubault
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R. Cengiz Ertekin
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Correspondence to Alexia Aubault .

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Editors and Affiliations

The Inst. for Ocean and Systems Engineering – SeaTech, Florida Atlantic University, 101 North Beach Road, FL 33004, Dania Beach, Florida, USA
Manhar R. Dhanak
School of Naval Architecture & Marine Engineering, University of New Orleans, 2000 Lakeshore Drive, LA 70148, New Orleans, Louisiana, USA
Nikolaos I. Xiros

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Aubault, A., Ertekin, R.C. (2016). Stability of Offshore Systems. In: Dhanak, M.R., Xiros, N.I. (eds) Springer Handbook of Ocean Engineering. Springer Handbooks. Springer, Cham. https://doi.org/10.1007/978-3-319-16649-0_34

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DOI: https://doi.org/10.1007/978-3-319-16649-0_34
Publisher Name: Springer, Cham
Print ISBN: 978-3-319-16648-3
Online ISBN: 978-3-319-16649-0
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