Abstract
Rock typing is an important tool in evaluation and performance prediction of reservoirs. Different techniques such as flow zone indicator (FZI), FZI* and Winland methods are used to categorize reservoir rocks into distinct rock types. Generally, these methods are applied to petrophysical data that are measured at a pressure other than reservoir pressure. Since the pressure changes the pore structure of rock, the effect of overburden pressure on rock typing should be considered. In this study, porosity and permeability of 113 core samples were measured at five different pressures. To investigate the effect of pressure on determination of rock types, FZI, FZI* and Winland methods were applied. Results indicated that although most of the samples remain in the same rock type when pressure changes, some of them show different trends. These are related to the mineralogy and changes in pore system of the samples due to pressure change. Additionally, the number of rock types increases with increasing pressure. Furthermore, the effect of overburden pressure on determination of rock types is more clearly observed in the Winland and FZI* methods. Also, results revealed that a more precise reservoir dynamic simulation can be obtained by considering the reservoir rock typing process at reservoir conditions.
Highlights
Classification of reservoir rocks into different rock types, called reservoir rock typing, is an essential tool in drilling, production and especially reservoir studies
Petrophysical rock typing is categorized into two separate classes which are petrophysical static rock typing (PSRT) and petrophysical dynamic rock typing (PDRT)
Ahwaz Faculty of Petroleum, Petroleum University of Technology (PUT), Ahwaz, Iran defined as a group of rocks with a similar capillary pressure curve in the drainage process, whereas PDRT is described as a set of rocks that shows similar fluid flow behavior (Mirzaei-Paiaman et al 2018)
Summary
Classification of reservoir rocks into different rock types, called reservoir rock typing, is an essential tool in drilling, production and especially reservoir studies. The theoretical methods (such as rock quality index (RQI)/flow zone indicator (FZI) (Amaefule and Altunbay 1993), shale zone indicator (SZI) (Jongkittinarukorn and Tiab 1997; Nooruddin and Hossain 2011), modified FZI (Nooruddin and Hossain 2011), FZI* (FZIstar) (Mirzaei-Paiaman et al 2015) and FZI** (FZI-double star) (Mirzaei-Paiaman and Saboorian-Jooybari 2016) and PSRTI (Mirzaei-Paiaman et al 2018)) are basically derived from the well-known Kozeny–Carman equation Empirical methods, such as Winland (Kolodzie Jr 1980; Pittman 1992; Aguilera 2002), generate relationships between porosity, permeability and a specific size of pore throat which is taken from mercury injection capillary pressure tests. A proper solution for considering pressure effect on rock type is to perform the RQI/FZI method at reservoir pressure
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