dc.contributor.author |
Mutangara, Ngonidzashe E.
|
|
dc.contributor.author |
Smith, Lelanie
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|
dc.contributor.author |
Craig, K.J. (Kenneth)
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|
dc.contributor.author |
Sanders, Drewan S.
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|
dc.date.accessioned |
2022-10-21T05:54:07Z |
|
dc.date.available |
2022-10-21T05:54:07Z |
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dc.date.issued |
2021-11 |
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dc.description.abstract |
New aircraft developments are made to improve aircraft performance and efficiency. One such method is integrating propulsion into the airframe. This allows for boundary-layer ingestion, which shows promise of significant power benefits. However, these benefits are difficult to quantify as the propulsion system and aircraft body become meticulously integrated. The thrust and drag are coupled and cannot be defined separately, making conventional performance analysis methods inapplicable. The power balance method (PBM) addresses this by quantifying aircraft performance in terms of mechanical flow power and change in kinetic-energy rate. The primary focus of this work was to perform computational studies implementing the PBM on unpowered aerodynamic bodies to evaluate their respective drag contributions. A secondary study was also conducted to quantify the energy recovery potential of various bodies using a potential for energy recovery factor. The computational fluid dynamics case studies showed that drag obtained using the PBM agreed to within 2% of conventional momentum-based approaches. Maximal energy recovery potential was consistently observed at the trailing ends of the geometries, with values ranging between 9 and 12%. |
en_US |
dc.description.department |
Mechanical and Aeronautical Engineering |
en_US |
dc.description.librarian |
hj2022 |
en_US |
dc.description.sponsorship |
The University of Pretoria Department of Research and Innovation as well as Cranfield School of Aerospace, Transport and Manufacturing. |
en_US |
dc.description.uri |
https://arc.aiaa.org/toc/ja/58/6 |
en_US |
dc.identifier.citation |
Mutangara, N.E., Smith, L., Craig, K.J. et al. 2021, 'Potential for energy recovery of unpowered configurations using power balance method computations', Journal of Aircraft, vol. 58, no. 6, pp. 1364-1374, doi : 10.2514/1.C036172. |
en_US |
dc.identifier.issn |
0021-8669 (print) |
|
dc.identifier.issn |
1533-3868 (online) |
|
dc.identifier.other |
10.2514/1.C036172 |
|
dc.identifier.uri |
https://repository.up.ac.za/handle/2263/87855 |
|
dc.language.iso |
en |
en_US |
dc.publisher |
American Institute of Aeronautics and Astronautics |
en_US |
dc.rights |
© 2021 by the American Institute of Aeronautics and Astronautics, Inc. All rights reserved. |
en_US |
dc.subject |
Energy recovery |
en_US |
dc.subject |
Laminar separation bubble |
en_US |
dc.subject |
Spalart-Allmaras turbulence model |
en_US |
dc.subject |
Natural laminar flow |
en_US |
dc.subject |
Aerodynamic characteristics |
en_US |
dc.subject |
Aircraft performance |
en_US |
dc.subject |
Computational fluid dynamics (CFD) |
en_US |
dc.subject |
Propulsion system |
en_US |
dc.subject |
Aircraft configurations |
en_US |
dc.subject |
Kinetic energy |
en_US |
dc.title |
Potential for energy recovery of unpowered configurations using power balance method computations |
en_US |
dc.type |
Postprint Article |
en_US |