Aerodynamic shape optimization of fan blades
The purpose of this work is to develop and evaluate an inverse optimization algorithm which designs two-dimensional fan blade shapes. Given a prescribed pressure distribution and inlet and outlet flow angles, this design optimization technique finds the optimal fan blade shape, stagger angle, and p...
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2007
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| Online Access: | http://hdl.handle.net/1993/1676 |
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ndltd-MANITOBA-oai-mspace.lib.umanitoba.ca-1993-16762014-01-31T03:30:50Z Aerodynamic shape optimization of fan blades Rogalsky, Timothy P. The purpose of this work is to develop and evaluate an inverse optimization algorithm which designs two-dimensional fan blade shapes. Given a prescribed pressure distribution and inlet and outlet flow angles, this design optimization technique finds the optimal fan blade shape, stagger angle, and pitch/chord ratio. The algorithm is coded into a completely self-contained C++ program. Its three main components are: a surface vorticity panel method flow solver, a Bezier curve surface definition routine, and an optimization method. Three different optimizers are tested and compared. A relatively new genetic algorithm, Differential Evolution, is determined to be the most effective. To demonstrate the abilities of the aerodynamic shape optimization algorithm, several fan blades are designed to exhibit a Liebeck pressure distribution. For each design, the optimal fan blade spacing is also found, verifying theoretically a claim that until now has been supported experimentally and with simple modelling. 2007-05-18T12:16:41Z 2007-05-18T12:16:41Z 1998-10-01T00:00:00Z http://hdl.handle.net/1993/1676 en_US |
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NDLTD |
| language |
en_US |
| sources |
NDLTD |
| description |
The purpose of this work is to develop and evaluate an inverse optimization algorithm which designs two-dimensional fan blade shapes. Given a prescribed pressure distribution and inlet and outlet flow angles, this design optimization technique finds the optimal fan blade shape, stagger angle, and pitch/chord ratio. The algorithm is coded into a completely self-contained C++ program. Its three main components are: a surface vorticity panel method flow solver, a Bezier curve surface definition routine, and an optimization method. Three different optimizers are tested and compared. A relatively new genetic algorithm, Differential Evolution, is determined to be the most effective. To demonstrate the abilities of the aerodynamic shape optimization algorithm, several fan blades are designed to exhibit a Liebeck pressure distribution. For each design, the optimal fan blade spacing is also found, verifying theoretically a claim that until now has been supported experimentally and with simple modelling. |
| author |
Rogalsky, Timothy P. |
| spellingShingle |
Rogalsky, Timothy P. Aerodynamic shape optimization of fan blades |
| author_facet |
Rogalsky, Timothy P. |
| author_sort |
Rogalsky, Timothy P. |
| title |
Aerodynamic shape optimization of fan blades |
| title_short |
Aerodynamic shape optimization of fan blades |
| title_full |
Aerodynamic shape optimization of fan blades |
| title_fullStr |
Aerodynamic shape optimization of fan blades |
| title_full_unstemmed |
Aerodynamic shape optimization of fan blades |
| title_sort |
aerodynamic shape optimization of fan blades |
| publishDate |
2007 |
| url |
http://hdl.handle.net/1993/1676 |
| work_keys_str_mv |
AT rogalskytimothyp aerodynamicshapeoptimizationoffanblades |
| _version_ |
1716628046753038336 |