https://hal-ifp.archives-ouvertes.fr/hal-02075776Masmoudi, M.M.MasmoudiCERFACS - Centre Européen de Recherche et de Formation Avancée en Calcul Scientifique - CERFACSEdoa, P. F.P. F.EdoaIFPEN - IFP Energies nouvelles - IFPEN - IFP Energies nouvellesRahon, D.D.RahonIFPEN - IFP Energies nouvelles - IFPEN - IFP Energies nouvellesIdentification of Geological Forms Using Production DataHAL CCSD1999[SPI] Engineering Sciences [physics]Sciences, EDP2019-03-21 16:05:352022-03-28 11:26:042019-03-22 10:35:42enJournal articleshttps://hal-ifp.archives-ouvertes.fr/hal-02075776/document10.2516/ogst:1999001application/pdf1Identifying the geological forms of channels, faults and boundaries of reservoirs on the basis of well-tests or production history is a tricky problem for oil reservoir engineering. Analytical interpretation models of well-tests are used in simple cases. In multiphase cases or those which present a certain degree of geometrical complexity, it becomes necessary to use fluid flow simulation models. In this article, we intend to solve a problem of form inversion associated with a two-phase oil-water flow model in which the aim is to identify the form and the position of geological bodies in a hydrocarbon reservoir with production data match. In identifying the form, two problems generally occur: the choice of representation of geometrical forms and the calculation of sensitivities. To calculate the gradients, mesh perturbation techniques exist in fields where finite elements are commonly used. In the context of structured meshes often used in reservoir simulation, the application of such mesh perturbation techniques is difficult. The method suggested is based on the calculation of sensitivities on the continuous problem in relation to the geometry of the various geological bodies. Such a geometry is defined through triangulation. The adjustment parameters are the triangulation nodes and the gradients of tthe objective function are calculated in relation to the displacement of such nodes. An optimization algorithm coupled with a polyphase flow simulator has been developed. It takes into account the geometrical constraints of the adjustment parameters and guarantees the regularity of the forms obtained. Several laboratory applications have been carried out. With the help of calibrated production data this leads to a better characterization of the form, the size and the position of the sedimentary bodies in particular: reservoir boundaries, position and size of the faults and thickness and width of the channels.