Physics-informed neural network for modelling force and torque fluctuations in a random array of bidisperse spheres

Abstract

We present a physics-informed neural network (PINN) model to predict the hydrodynamic force and torque fluctuations in a random array of stationary bidisperse spheres. The PINN model is formulated based on two hypotheses: (i) pairwise interaction assumption that approximates the total force/torque exerted on a target sphere by linear superposition of individual contributions from a finite number of influential neighbors; (i) unified function representation that suggests a single functional form to describe the contribution from different neighbors based on the observation of probability distribution maps obtained with various binary interaction modes in bidisperse particle-laden flows. We accordingly establish a compact PINN architecture to evaluate individual force/torque contribution of influential neighbors through the same neural network block which tremendously reduces the number of unknown parameters, and ultimately compute the total force/torque exerted on target sphere by their weighted sum. We compare the model predictions to PR-DNS data of eight different cases in a range of Reynolds number 1≤ Re≤100, solid volume fraction 10\%≤φ≤40\%, sphere diameter ratio 1.5≤ dl*/ds*≤2.5 and volume ratio 1≤ Vl*/Vs*≤ 4, which demonstrates excellent performance with an optimal R2≈0.9 for both force and torque predictions. We establish a universal model that is applicable within the aforementioned input space, and examine its interpolation capability to the unseen data with multiple additional datasets. Finally, we extract the interpretable information of our PINN model in binary and trinary interactions, and discuss its potential extensions to other particle-laden flow problems with more complicated scenarios and Eulerian-Lagrangian simulations as a superior alternative to the classic average drag laws.