Semi-analytical model to predict the performance of cyclic steam stimulation oil wells

The inflection point temperature of rheology (IPTR) of heavy oil transforming from a non-Newtonian fluid into a Newtonian fluid is a key parameter in the steam huff- and-puff process. It is particularly relevant in terms of optimizing injection parameters, calculating the heating radius, and determining well spaces. However, the current approach exhibits obvious shortcomings, such as the randomness of the selected tangent line and inadaptability for extra-heavy oil with high viscosity. Therefore, this paper presents a novel method for calculating IPTR using viscosity–temperature data. The approach is based on the Arrhenius equation and quantitatively evaluates the IPTR according to the inflection point of the apparent activation energy. The IPTR values of four heavy-oil samples obtained from the Bohai Oilfield in China were quantitatively predicted according to viscosity–temperature data using the proposed method. The method's accuracy was verified by a series of rheological investigations on samples obtained from two heavy-oil wells. Additionally, the new method was used to predict IPTR according to the published viscosity–temperature data of 10 heavy-oil samples from the Shengli Oilfield. Again, a good correspondence was found, and mean absolute and relative errors of 3°C and 4.6%, respectively, were reported. Therefore, the proposed model was confirmed to improve the prediction accuracy of the existing method, and provided a new method for calculating the IPTR of heavy-oil.

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Integrating Physical and Numerical Simulation of Horizontal Well Steam Flooding in a Heavy Oil Reservoir

Liu

Lai

et al. 2023

Journal of Energy Resources Technology

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LD-N extra heavy oil reservoir in Bohai Sea is characterized with deep burial and large bottom water. Horizontal-well steam huff ‘n’ puff has been applied, yet due to water coning and serious heat losses, the oil recovery after three cycles turned out to be rather low (1.58%). To find an appropriate follow-up process, this study proposed and analyzed three different flooding schemes: steam flooding, multiple-thermal-fluid flooding, and foam flooding. Scaled 3D physical experiments and corresponding numerical simulation have been conducted to investigate the heating chamber development and fluid production. History match and parametric analyses have been carried out to optimize the well performance and operating conditions. The optimized results include 360 m3/d instantaneous steam injection rate, 1.3–1.4 production-injection ratio, and 13–16 m water avoidance height. In addition, the production well is recommended to be placed above the injection well. These findings provide a useful guidance for the design of thermal recovery schemes and the optimization of production processes for heavy oil reservoirs with bottom water.

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Semi-analytical model to predict the performance of cyclic steam stimulation oil wells

Cited by 5 publications

References 23 publications

High-efficiency emulsification anionic surfactant for enhancing heavy oil recovery

High-efficiency emulsification anionic surfactant for enhancing heavy oil recovery

A New Method for Calculating the Inflection Point Temperature of Heavy-Oil Rheology Transforming From Non-Newton Fluid into the Newton Fluid

Integrating Physical and Numerical Simulation of Horizontal Well Steam Flooding in a Heavy Oil Reservoir

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