Thermal patterns from an evaporating flat surface under nonuniform heating
Previous research on thermocapillary flows during evaporation has often neglected key factors, including evaporation’s role in surface instability, precise heat source positioning at the liquid- vapor interface, and the influence of low-pressure environments on thermocapillary instabilities....
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2025
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sg-ntu-dr.10356-1819202025-01-04T16:54:58Z Thermal patterns from an evaporating flat surface under nonuniform heating Ho, Augus Kian Li Fei Duan School of Mechanical and Aerospace Engineering feiduan@ntu.edu.sg Engineering Physics Other Thermal patterns Nonuniform heating Infrared Previous research on thermocapillary flows during evaporation has often neglected key factors, including evaporation’s role in surface instability, precise heat source positioning at the liquid- vapor interface, and the influence of low-pressure environments on thermocapillary instabilities. Experiments with droplets have also struggled with nonuniform surfaces, complicating control over surface tension variations. This study addresses these gaps by examining controlled temperature gradients on thermal pattern formation during ethanol evaporation. Nonuniform heating using resistive wires at 35°C, 45°C, and 55°C was applied under open (atmospheric) and closed (reduced pressure) conditions to observe thermal pattern evolution under single heating wire and dual heating wire configurations. Temperature measurements were taken at four points—Wire Top, Wire Edge, Mid Field, and Far Field— along the tank centerline, and thermal patterns were captured at 1 ms intervals. Results show that reduced pressure stabilized and enhanced thermal patterns, with minimal flow under low heating and increased instability and turbulence under higher heating conditions. Dual heating setups demonstrated stable thermal boundaries and minimized movement under reduced pressure. These findings highlight the critical role of temperature gradients and environmental control in pattern formation for applications in microelectronics cooling and aerospace. Future work should explore broader pressure ranges, diverse liquids, and surface properties to deepen understanding of thermocapillary dynamics and integrate numerical simulations for enhanced insights. Bachelor's degree 2025-01-02T23:59:00Z 2025-01-02T23:59:00Z 2024 Final Year Project (FYP) Ho, A. K. L. (2024). Thermal patterns from an evaporating flat surface under nonuniform heating. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/181920 https://hdl.handle.net/10356/181920 en application/pdf Nanyang Technological University |
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Engineering Physics Other Thermal patterns Nonuniform heating Infrared |
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Engineering Physics Other Thermal patterns Nonuniform heating Infrared Ho, Augus Kian Li Thermal patterns from an evaporating flat surface under nonuniform heating |
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Previous research on thermocapillary flows during evaporation has often neglected key factors,
including evaporation’s role in surface instability, precise heat source positioning at the liquid-
vapor interface, and the influence of low-pressure environments on thermocapillary
instabilities. Experiments with droplets have also struggled with nonuniform surfaces,
complicating control over surface tension variations. This study addresses these gaps by
examining controlled temperature gradients on thermal pattern formation during ethanol
evaporation. Nonuniform heating using resistive wires at 35°C, 45°C, and 55°C was applied
under open (atmospheric) and closed (reduced pressure) conditions to observe thermal pattern
evolution under single heating wire and dual heating wire configurations. Temperature
measurements were taken at four points—Wire Top, Wire Edge, Mid Field, and Far Field—
along the tank centerline, and thermal patterns were captured at 1 ms intervals. Results show
that reduced pressure stabilized and enhanced thermal patterns, with minimal flow under low
heating and increased instability and turbulence under higher heating conditions. Dual heating
setups demonstrated stable thermal boundaries and minimized movement under reduced
pressure. These findings highlight the critical role of temperature gradients and environmental
control in pattern formation for applications in microelectronics cooling and aerospace. Future
work should explore broader pressure ranges, diverse liquids, and surface properties to deepen
understanding of thermocapillary dynamics and integrate numerical simulations for enhanced
insights. |
| author2 |
Fei Duan |
| author_facet |
Fei Duan Ho, Augus Kian Li |
| format |
Final Year Project |
| author |
Ho, Augus Kian Li |
| author_sort |
Ho, Augus Kian Li |
| title |
Thermal patterns from an evaporating flat surface under nonuniform heating |
| title_short |
Thermal patterns from an evaporating flat surface under nonuniform heating |
| title_full |
Thermal patterns from an evaporating flat surface under nonuniform heating |
| title_fullStr |
Thermal patterns from an evaporating flat surface under nonuniform heating |
| title_full_unstemmed |
Thermal patterns from an evaporating flat surface under nonuniform heating |
| title_sort |
thermal patterns from an evaporating flat surface under nonuniform heating |
| publisher |
Nanyang Technological University |
| publishDate |
2025 |
| url |
https://hdl.handle.net/10356/181920 |
| _version_ |
1821237105635885056 |