Investigation of Bio-Inspired Cylinders for Enhanced Heat Transfer
This project investigates a novel cylinder design inspired from the Harbor Seal whisker, with the goal of reducing coolant pumping power requirements while maintaining heat transfer rates in pin-fin arrays. Arrays of constant cross-section cylinders have been employed in many heat exchange applicati...
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Scholarly Commons
2023
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| Online Access: | https://commons.erau.edu/faculty-research-projects/62 |
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ftembryriddleaun:oai:commons.erau.edu:faculty-research-projects-1055 |
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ftembryriddleaun:oai:commons.erau.edu:faculty-research-projects-1055 2023-10-01T03:56:28+02:00 Investigation of Bio-Inspired Cylinders for Enhanced Heat Transfer Ricklick, Mark Prasad, Anish 2368747, 2393240 2023-08-29T19:56:02Z https://commons.erau.edu/faculty-research-projects/62 unknown Scholarly Commons https://commons.erau.edu/faculty-research-projects/62 Faculty Research Projects text 2023 ftembryriddleaun 2023-09-02T19:06:20Z This project investigates a novel cylinder design inspired from the Harbor Seal whisker, with the goal of reducing coolant pumping power requirements while maintaining heat transfer rates in pin-fin arrays. Arrays of constant cross-section cylinders have been employed in many heat exchange applications. Increases in heat transfer rates characteristically result in an increase in the coolant pumping power requirements, which can be quite high for a circular cylinder array. Pin fin channels are often used at the trailing edge of the blades where they also serve an additional purpose of providing structural support. It has been found that the behavior of the flow around a wall-mounted cylinder significantly impacts the heat transfer. The boundary layer becomes broken up by the presence of the pin, creating a horseshoe vortex. This horseshoe vortex produces high wall shear stress beneath it, resulting in high heat transfer from the wall in this region. The resulting flow separation around the pin, however, results in large pressure losses. The pin fin channel has been heavily studied in the literature, in an effort to describe the heat transfer and flow behavior and improve prediction abilities. The circular cylindrical pins are relatively easy to manufacture and hence, this configuration is often found in commercial applications. However, the need to reduce pressure drop and maintain the heat transfer rates are a much needed requirement for a variety of industries to improve the cooling efficiency. One such prominent line of research is conducted on optimizing the design of the circular cylindrical pins to increase their cooling performance. In this line of research, it was found that bio-mimicked harbor seal whisker geometry leads to the reduction in the cooling system pumping power requirements, while maintaining or improving heat transfer rates. The seal whisker geometry consists of stream-wise and span-wise undulations which reduce the size of the wake and coherent structures shed from the body as a result of ... Text harbor seal Embry-Riddle Aeronautical University: ERAU Scholarly Commons |
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Embry-Riddle Aeronautical University: ERAU Scholarly Commons |
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ftembryriddleaun |
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unknown |
| description |
This project investigates a novel cylinder design inspired from the Harbor Seal whisker, with the goal of reducing coolant pumping power requirements while maintaining heat transfer rates in pin-fin arrays. Arrays of constant cross-section cylinders have been employed in many heat exchange applications. Increases in heat transfer rates characteristically result in an increase in the coolant pumping power requirements, which can be quite high for a circular cylinder array. Pin fin channels are often used at the trailing edge of the blades where they also serve an additional purpose of providing structural support. It has been found that the behavior of the flow around a wall-mounted cylinder significantly impacts the heat transfer. The boundary layer becomes broken up by the presence of the pin, creating a horseshoe vortex. This horseshoe vortex produces high wall shear stress beneath it, resulting in high heat transfer from the wall in this region. The resulting flow separation around the pin, however, results in large pressure losses. The pin fin channel has been heavily studied in the literature, in an effort to describe the heat transfer and flow behavior and improve prediction abilities. The circular cylindrical pins are relatively easy to manufacture and hence, this configuration is often found in commercial applications. However, the need to reduce pressure drop and maintain the heat transfer rates are a much needed requirement for a variety of industries to improve the cooling efficiency. One such prominent line of research is conducted on optimizing the design of the circular cylindrical pins to increase their cooling performance. In this line of research, it was found that bio-mimicked harbor seal whisker geometry leads to the reduction in the cooling system pumping power requirements, while maintaining or improving heat transfer rates. The seal whisker geometry consists of stream-wise and span-wise undulations which reduce the size of the wake and coherent structures shed from the body as a result of ... |
| author2 |
2368747, 2393240 |
| format |
Text |
| author |
Ricklick, Mark Prasad, Anish |
| spellingShingle |
Ricklick, Mark Prasad, Anish Investigation of Bio-Inspired Cylinders for Enhanced Heat Transfer |
| author_facet |
Ricklick, Mark Prasad, Anish |
| author_sort |
Ricklick, Mark |
| title |
Investigation of Bio-Inspired Cylinders for Enhanced Heat Transfer |
| title_short |
Investigation of Bio-Inspired Cylinders for Enhanced Heat Transfer |
| title_full |
Investigation of Bio-Inspired Cylinders for Enhanced Heat Transfer |
| title_fullStr |
Investigation of Bio-Inspired Cylinders for Enhanced Heat Transfer |
| title_full_unstemmed |
Investigation of Bio-Inspired Cylinders for Enhanced Heat Transfer |
| title_sort |
investigation of bio-inspired cylinders for enhanced heat transfer |
| publisher |
Scholarly Commons |
| publishDate |
2023 |
| url |
https://commons.erau.edu/faculty-research-projects/62 |
| genre |
harbor seal |
| genre_facet |
harbor seal |
| op_source |
Faculty Research Projects |
| op_relation |
https://commons.erau.edu/faculty-research-projects/62 |
| _version_ |
1778526333322657792 |