Pore size determination using normalized J-function for different hydraulic flow units

Ali Abedini , Farshid Torabi

Petroleum ›› 2015, Vol. 1 ›› Issue (2) : 106 -111.

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Petroleum ›› 2015, Vol. 1 ›› Issue (2) :106 -111. DOI: 10.1016/j.petlm.2015.07.004
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Pore size determination using normalized J-function for different hydraulic flow units
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Abstract

Pore size determination of hydrocarbon reservoirs is one of the main challenging areas in reservoir studies. Precise estimation of this parameter leads to enhance the reservoir simulation, process evaluation, and further forecasting of reservoir behavior. Hence, it is of great importance to estimate the pore size of reservoir rocks with an appropriate accuracy. In the present study, a modified J-function was developed and applied to determine the pore radius in one of the hydrocarbon reservoir rocks located in the Middle East. The capillary pressure data vs. water saturation (Pc-Sw) as well as routine reservoir core analysis include porosity (φ) and permeability (k) were used to develop the J-function. First, the normalized porosity (φz), the rock quality index (RQI), and the flow zone indicator (FZI) concepts were used to categorize all data into discrete hydraulic flow units (HFU) containing unique pore geometry and bedding characteristics. Thereafter, the modified J-function was used to normalize all capillary pressure curves corresponding to each of predetermined HFU. The results showed that the reservoir rock was classified into five separate rock types with the definite HFU and reservoir pore geometry. Eventually, the pore radius for each of these HFUs was determined using a developed equation obtained by normalized J-function corresponding to each HFU. The proposed equation is a function of reservoir rock characteristics including φz, FZI, lithology index (J*), and pore size distribution index (ɛ). This methodology used, the reservoir under study was classified into five discrete HFU with unique equations for permeability, normalized J-function and pore size. The proposed technique is able to apply on any reservoir to determine the pore size of the reservoir rock, specially the one with high range of heterogeneity in the reservoir rock properties.

Keywords

Pore size / Pore geometry / Hydraulic flow unit / Capillary pressure / J-function

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Ali Abedini, Farshid Torabi. Pore size determination using normalized J-function for different hydraulic flow units. Petroleum, 2015, 1(2): 106-111 DOI:10.1016/j.petlm.2015.07.004

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