Abstract
CO2 flooding recovery strongly depends on the minimum miscibility pressure (MMP). Conventional tests to determine gas–oil MMP such as rising bubble apparatus and slim tube displacement are either costly or time consuming. In order to propose a quick and accurate model to determine MMP, a back-propagation neural network is presented for MMP prediction during pure and impure CO2 injections. Five new variables were screened as input parameters to the network. Next, the network was optimized using five evolutionary algorithms, and this work highlights that three of these evolutionary algorithms (e.g. Mind Evolutionary, Artificial Bee Colony, and Dragonfly) are firstly used to predict MMP. Then, data from the literature were input to the optimized network to train it. Statistical evaluation and graphical analyses were used to evaluate the performance of the proposed models and for comparison with published MMP correlates to obtain the optimal model for predicting MMP. The back-propagation model optimized using the dragonfly algorithm exhibited the highest accuracy among all those considered and MMP correlates; its coefficient of determination, average absolute percent relative error, root mean square error, and standard deviation were 0.965, 5.79%, 206.1, and 0.08, respectively. In addition, reservoir temperature was determined as the strongest MMP predictor (Pearson correlation = 0.63) based on sensitivity analysis.
Highlights
The research of enhanced oil recovery (EOR) is one of the most important themes of development of reservoirs
back propagation neural network (BP-NN) is employed to build a model for predicting the minimum miscible pressure (MMP) of CO2–crude oil system, and the model is optimized by five evolutionary algorithms (EAs): genetic algorithm (GA), mind evolutionary algorithm (MEA), particle swarm optimization (PSO), ABC, and dragonfly algorithm (DA)
A BP neural network model is presented for MMP prediction during pure and impure CO2 flooding
Summary
The research of enhanced oil recovery (EOR) is one of the most important themes of development of reservoirs. CO2 flooding is widely applied in the tight reservoirs as an efficient method to improve oil recovery. Compared with conventional EOR technology, this technology can greatly improve oil recovery, and store a large amount of CO2 in the reservoir to reduce greenhouse effect, which is a win–win project (Ampomah et al, 2016). The major difference between miscible and immiscible flooding is whether the formation pressure reaches the minimum miscible pressure (MMP). When the injection pressure reaches the MMP, the interface between crude oil and CO2 disappears and a miscible zone is formed, which greatly reduces the capillary force and increases the recovery efficiency (Yuan and Johns, 2002)
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