Machine learning for rapid discovery of laminar flow channel wall
modifications that enhance heat transfer
- URL: http://arxiv.org/abs/2101.08130v2
- Date: Tue, 8 Aug 2023 14:11:40 GMT
- Title: Machine learning for rapid discovery of laminar flow channel wall
modifications that enhance heat transfer
- Authors: Yuri Koide, Arjun J. Kaithakkal, Matthias Schniewind, Bradley P.
Ladewig, Alexander Stroh and Pascal Friederich
- Abstract summary: We present a combination of accurate numerical simulations of arbitrary, flat, and non-flat channels and machine learning models predicting drag coefficient and Stanton number.
We show that convolutional neural networks (CNN) can accurately predict the target properties at a fraction of the time of numerical simulations.
- Score: 56.34005280792013
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: Numerical simulation of fluids plays an essential role in modeling many
physical phenomena, which enables technological advancements, contributes to
sustainable practices, and expands our understanding of various natural and
engineered systems. The calculation of heat transfer in fluid flow in simple
flat channels is a relatively easy task for various simulation methods.
However, once the channel geometry becomes more complex, numerical simulations
become a bottleneck in optimizing wall geometries. We present a combination of
accurate numerical simulations of arbitrary, flat, and non-flat channels and
machine learning models predicting drag coefficient and Stanton number. We show
that convolutional neural networks (CNN) can accurately predict the target
properties at a fraction of the time of numerical simulations. We use the CNN
models in a virtual high-throughput screening approach to explore a large
number of possible, randomly generated wall architectures. Data Augmentation
was applied to existing geometries data to add generated new training data
which have the same number of parameters of heat transfer to improve the
model's generalization. The general approach is not only applicable to simple
flow setups as presented here but can be extended to more complex tasks, such
as multiphase or even reactive unit operations in chemical engineering.
Related papers
- Physics-enhanced Neural Operator for Simulating Turbulent Transport [9.923888452768919]
This paper presents a physics-enhanced neural operator (PENO) that incorporates physical knowledge of partial differential equations (PDEs) to accurately model flow dynamics.
The proposed method is evaluated through its performance on two distinct sets of 3D turbulent flow data.
arXiv Detail & Related papers (2024-05-31T20:05:17Z) - Simulation-Based Parallel Training [55.41644538483948]
We present our ongoing work to design a training framework that alleviates those bottlenecks.
It generates data in parallel with the training process.
We present a strategy to mitigate this bias with a memory buffer.
arXiv Detail & Related papers (2022-11-08T09:31:25Z) - On Fast Simulation of Dynamical System with Neural Vector Enhanced
Numerical Solver [59.13397937903832]
We introduce a deep learning-based corrector called Neural Vector (NeurVec)
NeurVec can compensate for integration errors and enable larger time step sizes in simulations.
Our experiments on a variety of complex dynamical system benchmarks demonstrate that NeurVec exhibits remarkable generalization capability.
arXiv Detail & Related papers (2022-08-07T09:02:18Z) - Machine Learning model for gas-liquid interface reconstruction in CFD
numerical simulations [59.84561168501493]
The volume of fluid (VoF) method is widely used in multi-phase flow simulations to track and locate the interface between two immiscible fluids.
A major bottleneck of the VoF method is the interface reconstruction step due to its high computational cost and low accuracy on unstructured grids.
We propose a machine learning enhanced VoF method based on Graph Neural Networks (GNN) to accelerate the interface reconstruction on general unstructured meshes.
arXiv Detail & Related papers (2022-07-12T17:07:46Z) - Learning Large-scale Subsurface Simulations with a Hybrid Graph Network
Simulator [57.57321628587564]
We introduce Hybrid Graph Network Simulator (HGNS) for learning reservoir simulations of 3D subsurface fluid flows.
HGNS consists of a subsurface graph neural network (SGNN) to model the evolution of fluid flows, and a 3D-U-Net to model the evolution of pressure.
Using an industry-standard subsurface flow dataset (SPE-10) with 1.1 million cells, we demonstrate that HGNS is able to reduce the inference time up to 18 times compared to standard subsurface simulators.
arXiv Detail & Related papers (2022-06-15T17:29:57Z) - Towards Fast Simulation of Environmental Fluid Mechanics with
Multi-Scale Graph Neural Networks [0.0]
We introduce MultiScaleGNN, a novel multi-scale graph neural network model for learning to infer unsteady continuum mechanics.
We demonstrate this method on advection problems and incompressible fluid dynamics, both fundamental phenomena in oceanic and atmospheric processes.
Simulations obtained with MultiScaleGNN are between two and four orders of magnitude faster than those on which it was trained.
arXiv Detail & Related papers (2022-05-05T13:33:03Z) - Accelerating Part-Scale Simulation in Liquid Metal Jet Additive
Manufacturing via Operator Learning [0.0]
Part-scale predictions require many small-scale simulations.
A model describing droplet coalescence for LMJ may include coupled incompressible fluid flow, heat transfer, and phase change equations.
We apply an operator learning approach to learn a mapping between initial and final states of the droplet coalescence process.
arXiv Detail & Related papers (2022-02-02T17:24:16Z) - Learning Mesh-Based Simulation with Graph Networks [20.29893312074383]
We introduce MeshGraphNets, a framework for learning mesh-based simulations using graph neural networks.
Our results show it can accurately predict the dynamics of a wide range of physical systems, including aerodynamics, structural mechanics, and cloth.
arXiv Detail & Related papers (2020-10-07T13:34:49Z) - Combining Differentiable PDE Solvers and Graph Neural Networks for Fluid
Flow Prediction [79.81193813215872]
We develop a hybrid (graph) neural network that combines a traditional graph convolutional network with an embedded differentiable fluid dynamics simulator inside the network itself.
We show that we can both generalize well to new situations and benefit from the substantial speedup of neural network CFD predictions.
arXiv Detail & Related papers (2020-07-08T21:23:19Z) - Learning Incompressible Fluid Dynamics from Scratch -- Towards Fast,
Differentiable Fluid Models that Generalize [7.707887663337803]
Recent deep learning based approaches promise vast speed-ups but do not generalize to new fluid domains.
We propose a novel physics-constrained training approach that generalizes to new fluid domains.
We present an interactive real-time demo to show the speed and generalization capabilities of our trained models.
arXiv Detail & Related papers (2020-06-15T20:59:28Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.