%P 299-303
%C Rio de Janeiro
%T On the specifications of flexible composite ball socket joint pipe characterized by barrel shell model
%I Offshore Technology Conference
%A T.M. Badri Albarody
%A Z. Mustaffa
%A M.B. Taufiq
%V 1
%D 2013
%O cited By 0; Conference of OTC Brasil 2013 - From North to South: A Wealth of Opportunities ; Conference Date: 29 October 2013 Through 31 October 2013; Conference Code:103421
%L scholars3861
%J Proceedings of the Annual Offshore Technology Conference
%X Pipelines for deep-water application should be designed to be extremely flexible to ease the installation procedures. Such flexibility will improve the bending instabilities of reeled pipelines during spooling of initially straight or laying of initially bent pipe. Also during construction, pipeline flexibility could be exploited to connect pipelines and risers to floaters, manifolds, wellheads, buoys, and platforms. Therefore, the proposed flexible pipe is designed to be positionable and bendable enough to fit the above requirements. The pipe is comprises a series of interconnected ball-and-socket sections forming a liner and a fluid-tight cover, one or more helical wounding layers applied to the internal liner for absorbing tension loads, and one or more additional helical wounding layers applied for absorbing bending loads. In order to form a liner, the ball-and-socket segment will passes through a die, while a thread guide applies a plurality of reinforcing threads in a particular pattern to the exterior surface thereof to keep the segments to be snappingly engageable and maintain the pipe flexibility without significantly increasing in the thickness of the pipe wall or weight. The ball and socket segments are assumed manufactured from a lightweight composite material consisting of epoxied matrix reinforced by long continuous fibers. The socket segment was assumed a stiffer ring. Therefore, this paper will emphases on the design parameters of the ball joint that form the pipe by modeling it as laminated composite barrel shell and examining its elastic deformations capacity under pure bending conditions (e.g., typical reeling installation condition). To this aim, a straightforward treatment of the problem is presented via using Hamilton's principle and based on the first order shear deformation theories. The solution of the laminated composite barrel shell was formulated to follow exactly a simply supported boundary condition. Finally, the in-plane stresses and inter-laminar stresses were evaluated for wide range of loading conditions. Copyright 2013, Offshore Technology Conference.
%K Bending (forming); Laminating; Pipelines; Plates (structural components); Reinforced plastics; Reinforcement; Shear deformation, Bending instability; Exterior surfaces; First-order shear deformation theory; Flexible composites; Hamilton's principle; Installation procedures; Lightweight composite materials; Loading condition, Laminated composites