Deep-learning accelerated calculation of real-fluid properties in numerical simulation of complex flowfields

•A deep learning methodology is proposed for fast calculation of real-fluid properties.•The method features a neural network with appropriate boundary information.•The method can be coupled to a flow solver in a robust manner.•The approach is demonstrated in primitive- and conservative-variable base...

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Bibliographic Details
Published in:Journal of computational physics 2021-11, Vol.444, p.110567, Article 110567
Main Authors: Milan, Petro Junior, Hickey, Jean-Pierre, Wang, Xingjian, Yang, Vigor
Format: Article
Language:English
Subjects:
Artificial neural networks
Chemical composition
Computational efficiency
Computational physics
Computer simulation
Computing time
Counterflow
Counterflow diffusion flames
Cryoforming
Cryogenic combustion
Deep learning
Diffusion flames
Equations of state
Evaluation
Fluid dynamics
Fluid flow
Mathematical models
Neural networks
Numerical simulations
Parametric analysis
Preconditioning
Real-fluid properties
Robustness (mathematics)
Simulation
Solvers
Supercritical flows
Swirl injector flows
Thermophysical models
Thermophysical properties
Time integration
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Summary:•A deep learning methodology is proposed for fast calculation of real-fluid properties.•The method features a neural network with appropriate boundary information.•The method can be coupled to a flow solver in a robust manner.•The approach is demonstrated in primitive- and conservative-variable based solvers.•The approach significantly reduces the simulation time and memory usage. A deep-learning based approach is developed for efficient evaluation of thermophysical properties in numerical simulation of complex real-fluid flows. The work enables a significant improvement of computational efficiency by replacing direct calculation of the equation of state with a deep feedforward neural network with appropriate boundary information (DFNN-BC). The proposed method can be coupled to a flow solver in a robust manner. Depending on the numerical formulation of the flow solver, the neural network takes in either the primitive or conservative variables, including the chemical composition of the system, and calculates all relevant fluid properties for the subsequent routines in the solver. Two test problems are employed to validate the proposed methodology. The first uses a preconditioning scheme with dual-time integration for the simulation of swirl rocket injector flow dynamics under supercritical conditions. The second uses a conservative-variable based formulation for the simulation of laminar counterflow diffusion flames for cryogenic combustion. A parametric analysis is performed to optimize the numbers of hidden layers and neurons per hidden layer. The computational accuracy, efficiency, and memory requirements of the neural network are examined. The DFNN-BC model accelerates the evaluation of real-fluid properties by a factor of 2.43 and 3.7 for the two test problems, respectively, and the overall flowfield simulation by 1.5 and 2.3, respectively. In addition, the memory usage is reduced by up to five orders of magnitude in comparison with the table look-up method.
ISSN:0021-9991
1090-2716
DOI:10.1016/j.jcp.2021.110567