Micro/nanostructured additively manufactured surfaces for enhanced flow boiling of refrigerants
Many studies on two-phase flow boiling in microchannels involving factors that affect bubble nucleation to effectively dissipate heat from surfaces have been reported. These studies mainly involved the use of additive manufacturing fabrication orsurface modification to enhance flow boiling heat...
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| Format: | Final Year Project |
| Language: | English |
| Published: |
Nanyang Technological University
2024
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| Online Access: | https://hdl.handle.net/10356/176808 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Many studies on two-phase flow boiling in microchannels involving factors that affect bubble
nucleation to effectively dissipate heat from surfaces have been reported. These studies mainly
involved the use of additive manufacturing fabrication orsurface modification to enhance flow boiling
heat transfer performance. However, these approaches usually come with a significant amount of
pressure drops, which can result in higher energy demand.
In this project, a combination of additively manufactured aluminum alloys (AM AlSi10Mg) and
surface modification was implemented to study the influence of microstructure on flow boiling
performance and pressure drops. The experiment was conducted with R134a as the working fluid
flowing through 16 parallel rectangular channels. The flow boiling performance of various samples
was tested using heat flux ranging from 1.5 to 142 kW/m2
, mass flux of 73 and 146 kg/m2
·s, and a
controlled inlet subcooling temperature of 2°C. Throughout the experiment, parameters such as the
average temperature of the wall, heat transfer coefficient, and pressure drop were recorded. A high speed camera was also deployed to observe the flow pattern within the cold plates. A plain
conventionally manufactured aluminum (Al6061) was also fabricated and tested, and its thermal
performance was compared against the AM samples.
It was concluded from this experiment that the chemically etched AM surface with the refrigerant mass
flux of 73 kg/m2
·s demonstrated a significant improvement in the heat transfer coefficient by 87% at
low heat flux from 1.9 to 15 kW/m2
, 70% at medium heat flux from 15 and 93 kW/m2
, and 98% at
high heat flux from 93 to 140 kW/m2
as compared to plain Al6061 surface. In addition, the
microstructured AM sample also exhibited at least a 33% reduction in pressure drop as compared to
the plain AM surface. The etching process was able to reduce the surface roughness by removing
III
surface irregularities that arose during the AM fabrication process, and generated microstructures on
the aluminum alloy surface. This, in turn, resulted in a significant increase in active nucleation sites to
create bubbles to promote heat removal and minimize the energy required to overcome friction across
the channel surfaces. |
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