Two-phase and three-phase equilibrium K-values for modelling of non-condensable gas Co-Injection processes

To improve the efficiency of Steam Assisted Gravity Drainage process (SAGD), a small amount of non-condensable gases can be added to steam. The non-condensable gas creates an insulation film at the top of the steam chamber as a result of gas accumulation. This could prevent heat loss to the overburd...

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Bibliographic Details
Published in:Journal of petroleum science & engineering 2019-02, Vol.173, p.525-535
Main Authors: Ranjbar, Ehsan, Ghaderi, Seyyed M., Nourozieh, Hossein, Kumar, Anjani, Takbiri-Borujeni, Ali
Format: Article
Language:English
Subjects:
Gas
Heavy oil
K-value
Modelling
Thermal recovery
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Summary:To improve the efficiency of Steam Assisted Gravity Drainage process (SAGD), a small amount of non-condensable gases can be added to steam. The non-condensable gas creates an insulation film at the top of the steam chamber as a result of gas accumulation. This could prevent heat loss to the overburden, increase steam chamber propagation in the lateral direction, and consequently improve the SAGD performance. Field-scale modelling and simulation of non-condensable gas injection in a hybrid SAGD process requires a comprehensive numerical model that includes variety of mechanisms involved in the processes. During the steam/non-condensable gas co-injection, the non-condensable gas may partially be dissolved in bitumen and water, accounting for a portion of gas production from the chamber. Therefore, in order to accurately model the non-condensable gas injection process, the partitioning of the gas among the phases (oleic and aqueous) must be well understood. The most significant challenge of modelling multi-phase equilibrium in gas/bitumen/water systems is the lack of three-phase equilibrium data. This study presents a methodology to generate two-phase and three-phase K-values from the experimental solubility data. The data for binary systems at certain temperatures and pressures is translated into equilibrium K-values. The K-values were calculated either from a correlation representing the phase behavior data or from an equation of state coupled with Henry's law. Then, the generated two-phase and three-phase K-values were directly implemented in reservoir simulators to account for component partitioning in different phases. The results indicate that the generated K-values would be applicable for different types of bitumen. •A methodology to generate two-phase and three-phase k-values was proposed.•Equilibrium condition of ternary mixture can be obtained using the binary k-values.•Generated k-values were directly implemented in reservoir simulators.
ISSN:0920-4105
1873-4715
DOI:10.1016/j.petrol.2018.09.091