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Microscopic Production Characteristics of Huff-n-Puff after CO<sub>2</sub> Flooding in Tight Oil Sandstone Reservoirs

Junjie Xue, Hui Gao, Xiaoyong Wen, Meiqiang Wang, Zhilin Cheng, Chen Wang, Teng Li, Bo Han, Kaiqing Luo, Nan Zhang

2023Energy & Fuels14 citationsDOI

Abstract

This study aims to investigate the impact of CO 2 huff-n-puff after CO 2 flooding on recovery efficiency in tight sandstone reservoirs. The experimental methodology involved the selection of three representative cores with different permeability levels to emulate class I, II, and III reservoirs. To examine immiscible, nearly miscible, and miscible conditions for different reservoir samples, a physical simulation flow system integrated with nuclear magnetic resonance technology was employed. CO 2 flooding was performed followed by CO 2 huff-n-puff experiments at five pressures, enabling a quantitative analysis of oil production characteristics in various pores during the flooding and huff-n-puff processes. This study provides insights into the microscopic production characteristics and oil recovery influenced by huff-n-puff in tight sandstone reservoirs subsequent to CO 2 flooding. The experimental results highlight that recovery efficiency increases with higher permeability, with class I reservoir samples exhibiting the highest recovery rate at 76.47%, followed by class II reservoirs at 69.33%, and class III reservoirs at 44.43%. Huff-n-puff recovery for class I and class II reservoirs gradually declines with increasing pressure after flooding, whereas class III reservoirs display an opposite trend, with recovery gradually increasing. In addition, the microscopic oil distribution characteristics change after flooding. During the near-miscible phase, class I and class III reservoirs predominantly yield oil from medium and small pores, while class II reservoirs primarily produce oil from medium pores. Upon reaching miscibility, oil production in class I, II, and III reservoirs primarily occurs in small pores, with some contribution from medium pores. The research findings presented in this paper provide valuable theoretical support for future CO 2 flooding operations in tight sandstone reservoirs and the optimization of huff-n-puff experiments subsequent to flooding.

Topics & Concepts

Petroleum engineeringTight oilPermeability (electromagnetism)Enhanced oil recoveryFlooding (psychology)Oil productionMiscibilityGeologyEnvironmental scienceMaterials scienceChemistryComposite materialOil shalePolymerBiochemistryMembranePsychotherapistPsychologyPaleontologyEnhanced Oil Recovery TechniquesHydrocarbon exploration and reservoir analysisCO2 Sequestration and Geologic Interactions