Martin Gainville scite author profile

Unbonded flexible pipelines used for offshore fields developments usually rely upon a stainless steel carcass as innermost layer for collapse resistance and a polymeric pressure sheath for internal leakproofness. For some dynamic flexible risers, this pressure sheath is a multi-layer construction made of 2 or 3 layers. In this multi-layer configuration, during operation, the fluid transported in the bore of the pipe can penetrate the annular space between the pressure sheath layers by means of flow paths through the end-fitting. Then, when the pipe bore is depressurized, the pressure of the fluid trapped between the sacrificial sheath and the pressure sheath does not decrease as fast as in the bore. This is due to the small annular flow path between the sheaths. Depressurization of the pipe bore should thus be performed at a limited and controlled rate to avoid an excessive differential pressure between the pipe bore and the annulus that could potentially cause the collapse of the carcass. The allowable depressurization rate is a key parameter the field operators need to know to avoid such an issue. A model was developed and implemented in a numerical software to calculate the evolution of the differential pressure during the depressurization. It is based on a one dimension gas/liquid transient transport model. More specifically, it is composed of the mass and momentum conservation laws. The thermodynamics properties of the fluid are computed with a simple model. In addition, the dynamic behavior of the annulus is coupled with the conservation equations and the pressure of both the bore and the external environment. A Finite Volume Method is chosen to both discretize and keep the conservative properties of the model on a discrete level. In addition, a large test campaign was carried out on a full scale pipe to validate the model. A test consists in a pressure increase followed by a depressurization. The pressures in the bore and in the annulus were permanently recorded using a specific device which enables to know in real time the differential pressure between the pipe bore and the annulus. Various conditions were tested by varying the fluid viscosity, the initial bore pressure and the depressurization rate. After explaining the physics of the depressurization for this specific flexible pipe construction, this paper will present the numerical model developed to calculate the maximum differential pressure and the test campaign performed to validate this model.

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Integrated Flow Modeling Platform Using CAPE-OPEN Standard

Gainville

Roux

Pons³

et al. 2007

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fax 01-972-952-9435. AbstractThe design and the operation of petroleum field facilities are facing technical challenges that require numerous and detailed simulations to optimize investments and maximize production. Such calculations rely on a global understanding of production processes that an integrated model from wellbore to topside facilities can supply. To develop such a model, seamless integration of third-party modeling and simulation technologies in a unique software platform is useful and even necessary in many cases.First, this paper presents the R&D Transient Integrated Networks Analysis (TINA) project that was set up by TOTAL and IFP to address user requirements in term of model coupling, problem solving and data consistency. The TINA's domain of application is design and verification of flowlines from well-bore to topside facilities with a compositional approach. To achieve this objective, the CAPE-OPEN industry standard defined for Computer Aided Process Engineering (CAPE) applications has been used within the INDISS TM platform. The project relies on this platform for integrating modules, on IFP's research knowledge for pipe flow calculations and on third-party software components. TOTAL has brought to the project their knowledge of network design end operational characteristics, as well as the definition of functional requirements of TINA. Validation against field data has also been a profitable input to the project.Then, this approach is illustrated through several examples integrating three-phase pipe models, valves and surface equipments and also third-party physical and thermodynamic property servers to simulate a deep-water production network.At last, the paper expresses that the integration of a physical properties calculation server together with advanced pipe models in a software platform dedicated to steady-state and transient simulation enables to simulate deep-water production networks without having to rely on one single simulation solution provider. The interchangeability allows the end-user to choose the most convenient software components for the purpose of a study, and the interoperability allows integrating the latest research improvements together with third-party software components into a global model.

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Martin Gainville

Modelling reinjection of two-phase non-condensable gases and water in geothermal wells

Numerical and computational strategy for pressure-driven steady-state simulation of oilfield production

Experimental and Numerical Study of a Multi-Layer Flexible Pipe Depressurization

Integrated Flow Modeling Platform Using CAPE-OPEN Standard

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