Abstract
Flexible risers are designed with strong anti-collapse capacities which enable them to operate in deep-water reservoirs. However, this anti-collapse capacity is susceptible to the pipe curvature in the flooded annulus condition. For the curved riser sections within the touch-down zone, significant reduction of collapse capacity can occur once their external sheaths are worn out by the seabed, resulting in the so-called “wet collapse”. Mostly, wet collapse studies of curved flexible risers are performed through costly numerical simulations since there are no alternative analytical approaches. In view of it, this work presents an analytical model for predicting the wet collapse pressure of curved flexible risers. The analytical model is developed based on a spring-supported arch model that from our previous work, which is able to take the curvature-induced factors into account. With the stability theories of arched structures, the wet collapse pressure of curved flexible risers can be solved. To verify this analytical model, 3D full FE models are employed. The critical collapse pressures predicted by these two kinds of approach are in good agreement, indicating this proposed analytical model can be an useful tool to facilitate the collapse analysis in pipe design stage.
Highlights
Flexible risers are widely used in offshore production to convey hydrocarbons from sub-sea reservoirs to floating vessels
This study reveals that the curvature effect for reducing the wet collapse resistance of flexible risers is the result of three factors: the squeezeinduced additional ovalization, the pitch elongation and the deformed cross-sectional shape of the carcass
Following our previous mechanism study, an analytical model is established in this paper for predicting the wet collapse pressure of curved flexible risers
Summary
Flexible risers are widely used in offshore production to convey hydrocarbons from sub-sea reservoirs to floating vessels. Various equivalent layer methods have been proposed to treat the interlocking layers as equivalent homogeneous rings (Martins et al, 2003; Li et al, 2018a,b) With this treatment, those analytical models simplify the flexible pipe as a concentric ring structure, solving the collapse pressure based on the buckling theories of rings. The main difficulty of using analytical models in curved collapse is how to address the global curvature effect with a two-dimensional ring model In such a context, this work presents an analytical model to address the curved wet collapse issue of flexible risers, which aims to facilitate the collapse calculations in the pipe design stage. An analytical model is developed in this work to predict the wet collapse pressure of curved risers, which is able to take those three factors into account.
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