FRINK Linked Data Fragments server

Matches in SemOpenAlex for { <https://semopenalex.org/work/W2043966923> ?p ?o ?g. }

• W2043966923 abstract "Four methods for calculating wave forces acting on tubular members affixed offshore platforms are presented and compared under identical design conditions to demonstrate their significant differences. Many wave-crest locations and wave-approach directions are considered. Variation of base shears and overturning moments among these methods is found to exceed 21 percent. percent. Introduction Numerous technical papers, texts, and offshore design codes have used Morison's equation to determine hydrodynamic forces on small, tubular, structural elements. The Morison equation includes terms for both drag and inertial forces. The drag term includes a drag coefficient, CD, and water-particle velocity, while the inertia term includes an inertial coefficient, C1, and water-particle acceleration. This equation applies to small objects (compared with wave length) where wave kinematics do not change appreciably over a distance equal to the width of the structural element. Morison's equation was developed to determine the hydrodynamic force on a small cylindrical body that is at right angles to the water-particle velocity and acceleration vectors. However, when a cylinder is oriented randomly with respect to the mud line, there is considerable question about the application of Morison's equation. Borgman, Ippen, Bursnall et al., Chakrabarti et al., and Morgan et al. have shown how for a vertical cylinder Morison's equation may be applied to a cylindrical member oriented randomly with respect to the mud line. A review of the references reveals that there are many methods for calculating wave forces acting on tubular members of fixed offshore platforms. Four different methods are presented in this study, each within procedures generally used by the industry for computing procedures generally used by the industry for computing wave forces on a randomly oriented cylindrical member. Formulation of the methods considered is based on various interpretations of the application of Morison's equation. The wave-force calculation methods presented here are in the literature. This study compares these various methods with identical design conditions and demonstrates significant differences among the methods. The wave-force equation introduced by Morison et al. is -&gt; -&gt; -&gt; -&gt; F = 1/2 CDpdv x v x + 1/4 Clp d2 a x -&gt; -&gt; F p = ----,...................................(1) d -&gt; -&gt; where vx and ax are the horizontal water-particle velocity and acceleration vectors, respectively, acting on a vertical cylinder of a diameter, d, in water of mass density, p. Both water-particle kinematic vectors are normal to the cylinder and, consequently, the force vector, will be acting in a direction parallel to the mud line. Wave-induced motion, however, includes both horizontal and vertical kinematic components. Furthermore, except for conductors, offshore platforms rarely have cylindrical members that are perfectly vertical. In each wave-force calculation method presented, the total water-particle velocity vector is assumed to be -&gt; -&gt; -&gt; v = v x + v y,...........................(2) and the total acceleration vector is -&gt; -&gt; -&gt; a = a x + a y,...........................(3) P. 447" @default.
• W2043966923 created "2016-06-24" @default.
• W2043966923 creator A5024812814 @default.
• W2043966923 creator A5086563139 @default.
• W2043966923 date "1978-03-01" @default.
• W2043966923 modified "2023-09-27" @default.
• W2043966923 title "Application of Morison's Equation to Fixed Offshore Platforms" @default.
• W2043966923 doi "https://doi.org/10.2118/6324-pa" @default.
• W2043966923 hasPublicationYear "1978" @default.
• W2043966923 type Work @default.
• W2043966923 sameAs 2043966923 @default.
• W2043966923 citedByCount "6" @default.
• W2043966923 countsByYear W20439669232013 @default.
• W2043966923 countsByYear W20439669232020 @default.
• W2043966923 crossrefType "journal-article" @default.
• W2043966923 hasAuthorship W2043966923A5024812814 @default.
• W2043966923 hasAuthorship W2043966923A5086563139 @default.
• W2043966923 hasConcept C111368507 @default.
• W2043966923 hasConcept C121332964 @default.
• W2043966923 hasConcept C127313418 @default.
• W2043966923 hasConcept C127413603 @default.
• W2043966923 hasConcept C134306372 @default.
• W2043966923 hasConcept C162284963 @default.
• W2043966923 hasConcept C187320778 @default.
• W2043966923 hasConcept C199104240 @default.
• W2043966923 hasConcept C2778449969 @default.
• W2043966923 hasConcept C33923547 @default.
• W2043966923 hasConcept C42058472 @default.
• W2043966923 hasConcept C48880136 @default.
• W2043966923 hasConcept C51709192 @default.
• W2043966923 hasConcept C62520636 @default.
• W2043966923 hasConcept C70620910 @default.
• W2043966923 hasConcept C78519656 @default.
• W2043966923 hasConcept C8735168 @default.
• W2043966923 hasConceptScore W2043966923C111368507 @default.
• W2043966923 hasConceptScore W2043966923C121332964 @default.
• W2043966923 hasConceptScore W2043966923C127313418 @default.
• W2043966923 hasConceptScore W2043966923C127413603 @default.
• W2043966923 hasConceptScore W2043966923C134306372 @default.
• W2043966923 hasConceptScore W2043966923C162284963 @default.
• W2043966923 hasConceptScore W2043966923C187320778 @default.
• W2043966923 hasConceptScore W2043966923C199104240 @default.
• W2043966923 hasConceptScore W2043966923C2778449969 @default.
• W2043966923 hasConceptScore W2043966923C33923547 @default.
• W2043966923 hasConceptScore W2043966923C42058472 @default.
• W2043966923 hasConceptScore W2043966923C48880136 @default.
• W2043966923 hasConceptScore W2043966923C51709192 @default.
• W2043966923 hasConceptScore W2043966923C62520636 @default.
• W2043966923 hasConceptScore W2043966923C70620910 @default.
• W2043966923 hasConceptScore W2043966923C78519656 @default.
• W2043966923 hasConceptScore W2043966923C8735168 @default.
• W2043966923 hasLocation W20439669231 @default.
• W2043966923 hasOpenAccess W2043966923 @default.
• W2043966923 hasPrimaryLocation W20439669231 @default.
• W2043966923 hasRelatedWork W1964109961 @default.
• W2043966923 hasRelatedWork W2002251715 @default.
• W2043966923 hasRelatedWork W2026390475 @default.
• W2043966923 hasRelatedWork W2044096250 @default.
• W2043966923 hasRelatedWork W2052731229 @default.
• W2043966923 hasRelatedWork W2057434973 @default.
• W2043966923 hasRelatedWork W2058117559 @default.
• W2043966923 hasRelatedWork W2172839701 @default.
• W2043966923 hasRelatedWork W2198945852 @default.
• W2043966923 hasRelatedWork W2293770556 @default.
• W2043966923 hasRelatedWork W2528629969 @default.
• W2043966923 hasRelatedWork W2572467331 @default.
• W2043966923 hasRelatedWork W2576300931 @default.
• W2043966923 hasRelatedWork W2576799470 @default.
• W2043966923 hasRelatedWork W2762642450 @default.
• W2043966923 hasRelatedWork W592993355 @default.
• W2043966923 hasRelatedWork W627243078 @default.
• W2043966923 hasRelatedWork W628069836 @default.
• W2043966923 hasRelatedWork W636556321 @default.
• W2043966923 hasRelatedWork W93728368 @default.
• W2043966923 isParatext "false" @default.
• W2043966923 isRetracted "false" @default.
• W2043966923 magId "2043966923" @default.
• W2043966923 workType "article" @default.