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Abstract
In this paper, a physics-informed neural network (PINN) technique is developed to study the heat and mass transfer for the process of vapour bubble growth in a superheated liquid domain and tested using three working fluids including water, R-134a and FC-72. The work represents a novel step in the development of PINNs for phase change scenarios where surface tension effects dominate, and acts as a necessary validation stage before PINN techniques can be applied to complex boiling analysis. Initially, a forward analysis was performed using water and R-134a as working fluids. For each of these investigations, the PINN algorithm was trained on 50% of the available CFD data. The proposed algorithm was able to accurately infer velocity fields, particularly in the near-interfacial region. The resultant circulatory flow was found to maintain the desired round shape of the growing bubbles. As a result, when predicting the evolution of a water vapour bubble, the developed PINN algorithm produced a reduction in peak error by 0.87% compared to CFD reference data, and 3.42% reduction in peak error for prediction of the evolution of the R-134a vapour bubble. To test and optimise the transfer learning capabilities of the developed methodology, the evolution of an FC-72 vapour bubble in superheated FC-72 was predicted without supplying supporting observational data. For this scenario, the PINN algorithm produced a peak error within 1.3% of the unobserved CFD reference data. The proposed approach confirms the robustness of PINN methodologies as a method of solving phase-change problems where surface tension plays a pivotal, promising to expedite parametric studies in practice. This study represents a pioneering effort in the development of PINNs for phase change by applying the current algorithm to investigate bubble growth within superheated liquid domains, serving as a basis for the application of PINNs for boiling problems and as a benchmark for inverse training strategy.
Original language | English |
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Article number | 125940 |
Journal | International Journal of Heat and Mass Transfer |
Volume | 323 |
Early online date | 27 Jul 2024 |
DOIs | |
Publication status | E-pub ahead of print - 27 Jul 2024 |
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Dive into the research topics of 'Transfer Learning through Physics-Informed Neural Networks for Bubble Growth in Superheated Liquid Domains'. Together they form a unique fingerprint.Projects
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Fundamental Understanding of Turbulent Flow over Fluid-Saturated Complex Porous Media
Mahmoudi Larimi, Y. (PI) & Revell, A. (CoI)
1/07/23 → 31/12/26
Project: Research