Data Driven Prediction of the Minimum Miscibility Pressure (MMP) Between Mixtures of Oil and Gas Using Deep Learning

Q. Phạm, Trung Trinh, L. James
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Abstract

Knowing the minimum miscibility pressure (MMP) between different oil and gas compositions is important to predict reservoir performance for gas-based injection as a secondary gas flood or tertiary technique such as water alternating gas (WAG). Machine Learning (ML) has been used widely and has been proven efficient in estimating these properties. In this work, the development of ML as well as commonly used algorithms in predicting bubble point pressure and oil formation volume factor is reviewed. Just a few studies are found before 2000. From 2001 to 2010, the use of ML increased steadily. However, a sharp augmentation in number of articles is observed from 2011 up to now. More than that, Artificial Neural Networks (ANN) is the most employed algorithm with 23 applications out of 38 studied papers. In addition, for the first time, deep learning- multiple fully connected networks algorithm is implemented to predict the MMP for oil and gas through 250 datasets covering a wide range of CO2 concentration from 0 to 100% in the injected gas. The wide range of CO2 concentrations is to cover all modes of gas injection from a pure CO2 flood to CO2 being negligibly present when injecting a sweet gas. The model is then optimized using Early Stopping and K-Fold Cross Validation techniques, showing the average result of k splitting data sets. The eight input parameters are as follows: reservoir temperature, oil characteristics (molecular weight, ratio of volatile components, and intermediate components), and gas characteristics (mole percentage of CO2, Cl, N2, H2S, C2+). The proposed model is compared with other Machine Learning Techniques such as Decision Tree and Random Forest Regression. The results show that reservoir temperature, the amount of CO2 and Cl in the gas source were the parameters to affect MMP the most significantly. The presence of CO2 in the gas stream will lower the MMP significantly. The Deep Learning model obtained an R2 = 0.96 and a Root Mean Square Error (RMSE) of 5.4%. Through Early Stopping technique, the proposed model reach the R2 result of 0.97 in 7 epochs. An R2 value of 0.954 was found using K-Fold Cross Validation technique, resulting in a good model generated by five folds data set. The model built by Deep Learning algorithm was more accurate than these ones built by Decision Tree and Random Forest Regression, which had an R2 value below 0.9 and RMSE larger than 10%. This work goes beyond other prior research by adding a ‘stopping point’ concept, increasing the overall performance of the methods for general applications, and considering the full range of CO2 in the gas stream.
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基于深度学习的油气混合物最小混相压力数据驱动预测
了解不同油气成分之间的最小混相压力(MMP)对于预测二次气驱或水气交替(WAG)等三次注气技术的储层性能非常重要。机器学习(ML)已被广泛使用,并已被证明在估计这些属性方面是有效的。本文综述了机器学习的发展以及预测气泡点压力和地层体积因子的常用算法。2000年之前的研究寥寥无几。从2001年到2010年,机器学习的使用稳步增长。然而,从2011年到现在,文章的数量急剧增加。更重要的是,人工神经网络(ANN)是使用最多的算法,在38篇研究论文中有23篇应用。此外,该系统还首次实现了深度学习-多个全连接网络算法,通过250个数据集预测油气的MMP,这些数据集涵盖了注入气体中从0到100%的二氧化碳浓度范围。广泛的二氧化碳浓度范围涵盖了从纯二氧化碳注入到注入含硫气体时可忽略不计的二氧化碳的所有注气模式。然后使用早期停止和k - fold交叉验证技术对模型进行优化,显示k个分裂数据集的平均结果。8个输入参数包括:储层温度、油的特征(分子量、挥发性组分和中间组分的比值)和气的特征(CO2、Cl、N2、H2S、C2+的摩尔百分比)。该模型与其他机器学习技术如决策树和随机森林回归进行了比较。结果表明,储层温度、气源中CO2和Cl的含量是影响MMP最显著的参数。气流中CO2的存在将显著降低MMP。深度学习模型的R2 = 0.96,均方根误差(RMSE)为5.4%。通过早期停止技术,所提出的模型在7个epoch的R2值达到0.97。使用K-Fold交叉验证技术发现R2值为0.954,表明5倍数据集生成的模型效果良好。深度学习算法建立的模型比决策树和随机森林回归建立的模型更准确,R2值小于0.9,RMSE大于10%。这项工作超越了其他先前的研究,增加了“停止点”的概念,提高了一般应用方法的整体性能,并考虑了气流中二氧化碳的全部范围。
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