TY - GEN
T1 - Predictive Model for Relative Permeability Using Physics-Based Artificial Neural Networks
AU - Yoga, Hanif Farrastama
AU - Purswani, Prakash
AU - Johns, Russell Taylor
N1 - Funding Information:
The authors thank the financial support of the National Energy Technology Laboratory's ongoing research under the RSS contract number 89243318CFE000003. This study is also supported by the Indonesian Endowment Fund for Education (LPDP) of the Republic of Indonesia. Dr. Russell T. Johns holds the George E. Trimble Chair in Earth and Mineral Sciences at Penn State University.
Publisher Copyright:
Copyright 2022, Society of Petroleum Engineers.
PY - 2022
Y1 - 2022
N2 - Hysteresis of transport properties like relative permeability (Kr) can lead to computational problems and inaccuracies for various applications including CO2 sequestration and chemical enhanced oil recovery(EOR). Computational problems in multiphase numerical simulation include phase labeling issues and path dependencies that can create discontinuities. To mitigate hysteresis, modeling Kr as a state function that honors changes in physical parameters like wettability is a promising solution. In this research, we applythe state function concept to develop a physics-informed data-driven approach for predicting Kr in the spaceof its state parameters. We extend the development of the relative permeability equation-of-state (kr-EoS) to create a predictivephysics-based model using Artificial Neural Networks (ANN). We predict kr as a function of phasesaturation (S) and phase connectivity , as well as the specific path taken during the displacement, while maintaining other state parameters constant such as wet tability, pore structure, and capillary number. We use numerical data generated from pore-network simulations (PNM) to test the predictive capability of the EoS. Physical limits within space are used to constrain the model and improve its predictability you tside of the region of measured data. We find that the predicted relative permeabilities result in a smooth and physically consistent estimate. Our results show that ANN can more accurately estimate kr surface compared to using a high-order polynomial response surface. With only a limited amount of drainage and imbibition data with an initial phase saturation greater than 0.7, we provide a good prediction of kr from ANN for all other initial conditions, over the entire space. Finally, we show that we can predict the specific path taken in the space along with the corresponding kr for any initial condition and flow direction, which makes the approach practical when phase connectivity information is not available. This research demonstrates the first application of a physics-informed data-driven approach for prediction of relative permeability using ANN.
AB - Hysteresis of transport properties like relative permeability (Kr) can lead to computational problems and inaccuracies for various applications including CO2 sequestration and chemical enhanced oil recovery(EOR). Computational problems in multiphase numerical simulation include phase labeling issues and path dependencies that can create discontinuities. To mitigate hysteresis, modeling Kr as a state function that honors changes in physical parameters like wettability is a promising solution. In this research, we applythe state function concept to develop a physics-informed data-driven approach for predicting Kr in the spaceof its state parameters. We extend the development of the relative permeability equation-of-state (kr-EoS) to create a predictivephysics-based model using Artificial Neural Networks (ANN). We predict kr as a function of phasesaturation (S) and phase connectivity , as well as the specific path taken during the displacement, while maintaining other state parameters constant such as wet tability, pore structure, and capillary number. We use numerical data generated from pore-network simulations (PNM) to test the predictive capability of the EoS. Physical limits within space are used to constrain the model and improve its predictability you tside of the region of measured data. We find that the predicted relative permeabilities result in a smooth and physically consistent estimate. Our results show that ANN can more accurately estimate kr surface compared to using a high-order polynomial response surface. With only a limited amount of drainage and imbibition data with an initial phase saturation greater than 0.7, we provide a good prediction of kr from ANN for all other initial conditions, over the entire space. Finally, we show that we can predict the specific path taken in the space along with the corresponding kr for any initial condition and flow direction, which makes the approach practical when phase connectivity information is not available. This research demonstrates the first application of a physics-informed data-driven approach for prediction of relative permeability using ANN.
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U2 - 10.2118/209420-MS
DO - 10.2118/209420-MS
M3 - Conference contribution
AN - SCOPUS:85128979692
T3 - Proceedings - SPE Symposium on Improved Oil Recovery
BT - Society of Petroleum Engineers - SPE Improved Oil Recovery Conference, IOR 2022
PB - Society of Petroleum Engineers (SPE)
T2 - 2022 SPE Improved Oil Recovery Conference, IOR 2022
Y2 - 25 April 2022 through 29 April 2022
ER -