Thermal performance of cold plates with novel pin-fins designed using Bézier curves
This report explores the use of Bézier curves to form novel pin-fin shapes. Bézier curves are promising in their use for shape optimization since they are flexible enough to take all possible shapes in the design space. The pin-fin geometry is altered by adjusting the location of the control points....
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sg-ntu-dr.10356-1711882023-10-17T02:09:59Z Thermal performance of cold plates with novel pin-fins designed using Bézier curves Fok, Priscilla Jia Yuan Liu, Pengfei Kandasamy, Ranjith Wong, Teck Neng School of Mechanical and Aerospace Engineering Temasek Laboratories @ NTU Engineering::Mechanical engineering Thermal Performance Index Bézier Curve This report explores the use of Bézier curves to form novel pin-fin shapes. Bézier curves are promising in their use for shape optimization since they are flexible enough to take all possible shapes in the design space. The pin-fin geometry is altered by adjusting the location of the control points. For this study, the Bézier curves used each had 5 control points. The study was conducted for single-phase liquid cooling in the laminar regime (200≤ Re≤1000). Numerical investigations were carried out using aluminium alloy material (AlSi10Mg) as the cold plate material with deionized water as the coolant. In total, 7 different pin-fin geometries were explored. Overall, the novel wing-shaped pin-fins had the best thermal performance at Reynolds number (Re) of 1000. The velocity contours of the various pin-fin geometries confirmed that the pin-fins disrupt steady flow and accelerate the flow due to the decrease in cross-sectional area. For the pin-fin configurations simulated, the Nusselt number (Nu) increases while the friction factor generally decreases with higher Re. It is also observed that at lower Re, a higher Nu plays a significant role in achieving better thermal performance while at higher Re, a lower friction factor is more crucial. To validate the numerical results and further demonstrate the potential applications of such pin-fin shapes, experimental investigations were also conducted for circle and ellipse shaped pin-fins, which were designed using Bézier curves and subsequently printed through additive manufacturing. This study highlights the flexibility of Bézier curves in producing different pin-fin geometries. The writers would like to acknowledge DSO National Laboratories, Singapore for their support on this study. 2023-10-17T02:09:59Z 2023-10-17T02:09:59Z 2024 Journal Article Fok, P. J. Y., Liu, P., Kandasamy, R. & Wong, T. N. (2024). Thermal performance of cold plates with novel pin-fins designed using Bézier curves. International Journal of Thermal Sciences, 195, 108611-. https://dx.doi.org/10.1016/j.ijthermalsci.2023.108611 1290-0729 https://hdl.handle.net/10356/171188 10.1016/j.ijthermalsci.2023.108611 2-s2.0-85168999424 195 108611 en International Journal of Thermal Sciences © 2023 Published by Elsevier Masson SAS. All rights reserved. |
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Engineering::Mechanical engineering Thermal Performance Index Bézier Curve Fok, Priscilla Jia Yuan Liu, Pengfei Kandasamy, Ranjith Wong, Teck Neng Thermal performance of cold plates with novel pin-fins designed using Bézier curves |
| description |
This report explores the use of Bézier curves to form novel pin-fin shapes. Bézier curves are promising in their use for shape optimization since they are flexible enough to take all possible shapes in the design space. The pin-fin geometry is altered by adjusting the location of the control points. For this study, the Bézier curves used each had 5 control points. The study was conducted for single-phase liquid cooling in the laminar regime (200≤ Re≤1000). Numerical investigations were carried out using aluminium alloy material (AlSi10Mg) as the cold plate material with deionized water as the coolant. In total, 7 different pin-fin geometries were explored. Overall, the novel wing-shaped pin-fins had the best thermal performance at Reynolds number (Re) of 1000. The velocity contours of the various pin-fin geometries confirmed that the pin-fins disrupt steady flow and accelerate the flow due to the decrease in cross-sectional area. For the pin-fin configurations simulated, the Nusselt number (Nu) increases while the friction factor generally decreases with higher Re. It is also observed that at lower Re, a higher Nu plays a significant role in achieving better thermal performance while at higher Re, a lower friction factor is more crucial. To validate the numerical results and further demonstrate the potential applications of such pin-fin shapes, experimental investigations were also conducted for circle and ellipse shaped pin-fins, which were designed using Bézier curves and subsequently printed through additive manufacturing. This study highlights the flexibility of Bézier curves in producing different pin-fin geometries. |
| author2 |
School of Mechanical and Aerospace Engineering |
| author_facet |
School of Mechanical and Aerospace Engineering Fok, Priscilla Jia Yuan Liu, Pengfei Kandasamy, Ranjith Wong, Teck Neng |
| format |
Article |
| author |
Fok, Priscilla Jia Yuan Liu, Pengfei Kandasamy, Ranjith Wong, Teck Neng |
| author_sort |
Fok, Priscilla Jia Yuan |
| title |
Thermal performance of cold plates with novel pin-fins designed using Bézier curves |
| title_short |
Thermal performance of cold plates with novel pin-fins designed using Bézier curves |
| title_full |
Thermal performance of cold plates with novel pin-fins designed using Bézier curves |
| title_fullStr |
Thermal performance of cold plates with novel pin-fins designed using Bézier curves |
| title_full_unstemmed |
Thermal performance of cold plates with novel pin-fins designed using Bézier curves |
| title_sort |
thermal performance of cold plates with novel pin-fins designed using bézier curves |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/171188 |
| _version_ |
1781793786440974336 |