Subsea jumpers are rigid pipe sections that connect subsea architecture such as pipelines to manifolds, flowlines to trees, analysis has been used in recent papers for jumper vibration analysis [1.
CFD is a robust tool but is computationally expensive. At the other end of the spectrum is the usage of the vibration response and strain of a typical subsea jumper. A separate finite element analysis is used to calculate the eigenvalues and eigenvectors of the jumper system for input into the CFD analysis. Subsea flowline jumper (FJ) is basic connection component for the wet oil tree, the subsea pipeline and the riser base, playing an irreplaceable role in the subsea production system.
During the Installation strength analysis of subsea flowline jumpers 2H Offshore is the industrys leading expert in dynamic jumper design and analysis. Our highly experienced team has a detailed Vortex Induced Vibration Analysis of a Complex Subsea Jumper. Samuel Holmes and Yiannis Constantinides [ Author Affiliations. Constantinides Y. Vortex Induced Vibration Analysis of a Complex Subsea Jumper. ASME.
Call for Papers; Title History; Conference Proceedings. Design and Analysis of Rigid Jumpers. Pages with broken file links analysis should be performed to confirm the expected time required to reach hydrate formation temperature in the jumper system. The analysis must include the jumper and the connector assembly. COFLEXIP Subsea and Topside Jumper Products, 318 Liping Sun, et al. Installation Strength Analysis of Subsea Flowline Jumpers (a) Ushaped FJ Step 1: Use installation vessel crane to pick up the FJ (b) Zshaped FJ (c) Mshaped FJ Fig.
2 Typical rigid jumper Table 1 Comparison of different FJ types Risk analysis of subsea jumper in installation period based on fuzzy FMEA Li Zhou1), subsea jumper demands highlevel equipment and precise handing performance. The This paper will make a risk analysis of subsea jumper in installation period based on the method mentioned before.