SemOpenAlex |

SemOpenAlex

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2003926952> ?p ?o ?g. }

Showing items 1 to 54 of 54 with 100 items per page.

W2003926952 abstract "ABSTRACT Motion analysis of platforms operating in deep waters is quite a challenge. In order to obtain a realistic motion, the analysis must be performed as an integrated system of risers, mooring lines, and the platform. A fully coupled analysis of such a system is very time consuming and modeling simplifications, both structural and hydrodynamic, are often applied thereby introducing uncertainty in the accuracy of the results. For accurate vessel motions such fully coupled analysis may not really be warranted. It is rather beneficial to use a simplified procedure to include the effects of the risers and mooring lines and, if possible, be more accurate in the hydrodynamic modeling. A simple procedure has been developed in the form of a computer program, NICDAF, (Non-linear Integrated Coupled Dynamic Analysis of Floaters). The coupling effects of the risers and mooring lines are included based on their quasistatic configurations at each time step instead of their actual dynamic equilibrium configurations. The case study results show that full coupling of dynamic equilibrium is not important for accurate platform motion, but it is important for the riser or mooring line motions. Details of the development of the procedure and the case study analysis results from ABAQUS and NICDAF are presented. INTRODUCTION Recovery and production of oil from fields in deep and ultradeep waters require the services of compliant floating platforms. Design of the mooring system and risers, connected to floating platforms, are dominated by the motions of the platforms. An over prediction of motion would require costly risers and moorings, whilst an under prediction can lead to inadequate designs of possible catastrophic consequence. Accurate prediction of motions of a floater is very important for the integrity and associated costs of the risers, and moorings. For platforms in deeper waters, risers and mooring lines generally contribute significant inertia and damping due to their longer lengths, larger sizes, and heavier weights. Accurate motion analysis of platforms in deep waters requires that a fully integrated risers, moorings, and platform dynamic model be used. It is believed that a fully coupled analysis must be performed. This has resulted in recent efforts of the industry focused on the fully coupled dynamic motion analysis of floating platforms (1–4) to be used in deep waters. The accuracy of predicted motions also depends on accurate computation of wave forces (both wave frequency and low frequency), other hydrodynamic loads, and how the frequency dependent parameters are incorporated in the analysis. For example, wave forces on a large floating body are computed up to the mean water level and at a constant draft. Actual water surface elevation and the instantaneous position of the floater cannot be included in the present wave force calculation. Computation of hydrodynamic loads in a situation where natural periods of the system are changing all the time is complex. Change in natural periods occurs due to changes in mooring line tensions, which generate the system stiffness." @default.
W2003926952 created "2016-06-24" @default.
W2003926952 creator A5006427037 @default.
W2003926952 creator A5039297896 @default.
W2003926952 date "2000-05-01" @default.
W2003926952 modified "2023-09-24" @default.
W2003926952 title "Coupled Dynamic Analysis of Platforms, Risers, and Moorings" @default.
W2003926952 doi "https://doi.org/10.4043/12084-ms" @default.
W2003926952 hasPublicationYear "2000" @default.
W2003926952 type Work @default.
W2003926952 sameAs 2003926952 @default.
W2003926952 citedByCount "10" @default.
W2003926952 countsByYear W20039269522012 @default.
W2003926952 countsByYear W20039269522013 @default.
W2003926952 countsByYear W20039269522017 @default.
W2003926952 countsByYear W20039269522019 @default.
W2003926952 crossrefType "proceedings-article" @default.
W2003926952 hasAuthorship W2003926952A5006427037 @default.
W2003926952 hasAuthorship W2003926952A5039297896 @default.
W2003926952 hasConcept C127313418 @default.
W2003926952 hasConcept C127413603 @default.
W2003926952 hasConcept C199104240 @default.
W2003926952 hasConcept C41008148 @default.
W2003926952 hasConceptScore W2003926952C127313418 @default.
W2003926952 hasConceptScore W2003926952C127413603 @default.
W2003926952 hasConceptScore W2003926952C199104240 @default.
W2003926952 hasConceptScore W2003926952C41008148 @default.
W2003926952 hasLocation W20039269521 @default.
W2003926952 hasOpenAccess W2003926952 @default.
W2003926952 hasPrimaryLocation W20039269521 @default.
W2003926952 hasRelatedWork W1972919518 @default.
W2003926952 hasRelatedWork W1975106129 @default.
W2003926952 hasRelatedWork W1995832732 @default.
W2003926952 hasRelatedWork W1998990591 @default.
W2003926952 hasRelatedWork W2001145413 @default.
W2003926952 hasRelatedWork W2039343990 @default.
W2003926952 hasRelatedWork W2092312784 @default.
W2003926952 hasRelatedWork W2328515203 @default.
W2003926952 hasRelatedWork W2464121300 @default.
W2003926952 hasRelatedWork W2535570546 @default.
W2003926952 hasRelatedWork W2571558060 @default.
W2003926952 hasRelatedWork W2572285088 @default.
W2003926952 hasRelatedWork W2576506144 @default.
W2003926952 hasRelatedWork W2581216351 @default.
W2003926952 hasRelatedWork W2583984617 @default.
W2003926952 hasRelatedWork W2619778382 @default.
W2003926952 hasRelatedWork W2633338061 @default.
W2003926952 hasRelatedWork W2946262230 @default.
W2003926952 hasRelatedWork W2989624108 @default.
W2003926952 hasRelatedWork W606793085 @default.
W2003926952 isParatext "false" @default.
W2003926952 isRetracted "false" @default.
W2003926952 magId "2003926952" @default.
W2003926952 workType "article" @default.