Prediction of flexible pipe annulus composition by numerical modeling: identification of key parameters

Lefebvre, Xavier; Khvoenkova, Nina; Hemptinne, Jean-Charles de; Lefrançois, Léa; Radenac, Béatrice; Pignoc-Chicheportiche, Stéphanie; Plennevaux, C.

doi:10.2516/stet/2022008

Cited by 4 publications

(1 citation statement)

References 22 publications

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“…Therefore, the heat distribution directly affects the gas permeation. Numerous scholars have developed predictive models of heat and mass transfer for flexible riser, [13][14][15] but the predictive models make a series of simplifications to the actual models. Also, the thermal conductivity of materials is derived from the literature and differs from the actual predicted model.…”

mentioning

confidence: 99%

A method to improve the barrier performance of flexible riser internal pressure sheath—Heat transfer experiment and simulation

Meng,

Wen,

Liu

et al. 2023

J of Applied Polymer Sci

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A considerable amount of acidic gas penetrates into the annulus between the internal pressure sheath and the outer protective sheath during the service of flexible risers, which will inevitably lead to corrosion of the metal functional layer. Many researchers have modified nanocomposites from the mass transfer perspective to reduce the materials' permeability coefficient. While permeation is an integrated process of heat and mass transfer process, heat distribution directly impacts gas permeation. Herein, the thermal conductivity of flexible riser liner materials is predicted for the first time by a combination of molecular dynamics and experiments, and then the radial temperature distribution under different seawater temperatures and internal fluid temperatures is investigated by finite element analysis. Finally, the effect of temperature distribution on the permeation coefficient was analyzed. The results demonstrate that the thermal conductivity can be predicted by molecular dynamics simulation, and the thermal conductivity of (polyvinylidene difluoride) PVDF/TiO2 decreases, while the thermal conductivity of PVDF/carbon nanotube (CNT) increases compared with pure PVDF. The temperature distribution of the internal pressure sheath material decreases when condensate water is present. As the fluid temperature rises from 30 to 110°C, the maximum increase ratio in the permeability of PVDF/CNT over PVDF increased from 3.6% to 14.8%, and the maximum decrease ratio of PVDF/TiO2 permeability coefficient compared with PVDF is from 1.2% to 4.6%. The results present a new idea to improve the barrier properties of materials by decreasing thermal conductivity.

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mentioning

confidence: 99%

A method to improve the barrier performance of flexible riser internal pressure sheath—Heat transfer experiment and simulation

Meng,

Wen,

Liu

et al. 2023

J of Applied Polymer Sci

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Numerical and semi-empirical models for the stress analysis of flexible pipes tensile armors terminations within end-fittings

Miyazaki,

de Sousa,

Ellwanger

2024

Applied Ocean Research

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Carnot: a thermodynamic library for energy industries

de Hemptinne,

Ferrando,

Hajiw-Riberaud

et al. 2023

Sci. Tech. Energ. Transition

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For more than twenty years, IFP Energies Nouvelles has been developing the thermodynamic library Carnot. While devoted to the origin of the oil and gas industry, Carnot is now focused on applications related to the new technologies of energy for an industry emphasizing decarbonization and sustainability, such as CCUS, biomass, geothermal, hydrogen, or plastic and metal recycling. Carnot contains several dozens of predictive and correlative thermodynamic models, including well-established and more recent equations of state and activity coefficient models, as well as many specific models to calculate phase properties. Carnot also contains a dozen flash algorithms making possible the computation of various types of phase equilibrium, including not only two-phase and three-phase fluid equilibria but also configurations with reactive systems and with solid phases such as hydrates, wax, asphaltene, or salts. The library Carnot has a double role: first, it is a standalone toolbox for thermodynamic research and development studies. Coupled with an optimization tool, it allows to develop new thermodynamic models and to propose specific parameterizations adapted to any context. Secondly, Carnot is used as the thermodynamic engine of commercial software, such as Carbone™, Converge™, TemisFlow™, CooresFlow™ or Moldi™. Through this software, several hundreds of end-users are nowadays performing their thermodynamic calculations with Carnot. It has also been directly applied to design industrial processes such as the DMX™ process for CO2 capture, the ATOL® and BioButterFly™ solutions for bio-olefins production, and Futurol™ and BioTFuel™ for biofuels production. In this context, this article presents some significant realizations made with Carnot for both R&D and industrial applications, more specifically in the fields of CO2 capture and storage, flow assurance, chemistry, and geoscience.

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Prediction of flexible pipe annulus composition by numerical modeling: identification of key parameters

Cited by 4 publications

References 22 publications

A method to improve the barrier performance of flexible riser internal pressure sheath—Heat transfer experiment and simulation

A method to improve the barrier performance of flexible riser internal pressure sheath—Heat transfer experiment and simulation

Numerical and semi-empirical models for the stress analysis of flexible pipes tensile armors terminations within end-fittings

Carnot: a thermodynamic library for energy industries

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