A machine learning study to predict wind-driven water runback characteristics

Wang, Jincheng; Hu, Haiyang; He, Ping; Hu, Hui

doi:10.1063/5.0167545

Physics of Fluids

2023

DOI: 10.1063/5.0167545

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A machine learning study to predict wind-driven water runback characteristics

Jincheng Wang,

Haiyang Hu,

Ping He

et al.

Abstract: The unsteady runback behavior of wind-driven runback water film (WDRWF) flows over aircraft surfaces has a significant impact on the aircraft icing process, one of the most significant aviation hazards in cold weather. The limited understanding of the complex multiphase interactions between freestream airflow, water film motion, and solid airframe surface makes conventional theoretical/numerical methods unable to precisely simulate WDRWF flow. Machine learning-based techniques can accurately capture complex ph… Show more

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2024

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Cited by 2 publications

References 36 publications

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Gradient Nonwettability Controls Water-Film Flowing Features

Zhu,

Shen,

Jia

et al. 2024

Langmuir

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The flow of the water film on solid surface depended on the film Reynolds number and wind speed. Moreover, environmental factors had an impact on the flow process. This study explored how surface wettability impacts the stability and detachment of water film under varying conditions. Superhydrophobic surface played a critical role in speeding up the detachment of water film, especially under conditions of strong wind and specific flow dynamics, such as a wind speed of 19 m/s and a Reynolds number of 83. The efficiency in water removal was due to a combination of forces: capillary action, which pulls the water into smaller areas, reduced surface tension, and decreased adhesion between the liquid and surface. These factors worked together to shrink the area of contact, allowing the film to break and detach more easily. The findings suggested that enhancing nonwettability can improve water removal efficiency, with potential applications in fields like aerospace. Furthermore, additional trials across varying wind speeds and Reynolds numbers consistently supported the superior performance of superhydrophobic surface in driving rapid water-film detachment. To advance this effect, a gradient nonwetting surface was introduced, specifically engineered within the superhydrophobic regime, to amplify the velocity of film separation. This design innovation leveraged variations in surface energy across the gradient, which fostered directional waterfilm movement and accelerated detachment. A comprehensive analysis of the underlying physical mechanisms further elucidated its potential in enhancing water-shedding applications across a range of environmental conditions.

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Gradient Nonwettability Controls Water-Film Flowing Features

Zhu,

Shen,

Jia

et al. 2024

Langmuir

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An accuracy-enhanced transonic flow prediction method fusing deep learning and a reduced-order model

Jia,

Gong,

et al. 2024

Physics of Fluids

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It is difficult to accurately predict the flow field over an aircraft in the presence of shock waves due to its strong nonlinear characteristics. In this study, we developed an accuracy-enhanced flow prediction method that fuses deep learning and a reduced-order model to achieve accurate flow field prediction for various aerodynamic shapes. Herein, we establish a convolutional neural network/proper orthogonal decomposition (CNN-POD) model for mapping geometries to the overall flow field. Then, local flow regions containing nonlinear flow structures can be identified by the POD reconstruction to build the enhanced model. A CNN model is established to map geometries to the local flow field. The proposed method was applied to two cases involving the prediction of transonic flow over airfoils. The results indicate that the proposed accuracy-enhanced flow prediction method can reduce the prediction error for flow properties in regions with nonlinear flow structures by values ranging from 13% to 66.27%. Additionally, the proposed method demonstrates better efficiency and robustness in comparison to existing methods, and it can also address the prediction problem of complex transonic flow with multiple strong nonlinear structures.

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A machine learning study to predict wind-driven water runback characteristics

Cited by 2 publications

References 36 publications

Gradient Nonwettability Controls Water-Film Flowing Features

Gradient Nonwettability Controls Water-Film Flowing Features

An accuracy-enhanced transonic flow prediction method fusing deep learning and a reduced-order model

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