Numerical investigation of propulsive characteristics of podded propeller

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TypeArticle
Conference1st International Conference on Technological Advances in Podded Propulsion, 14th-16th April 2004, University of Newcastle, UK
Subjectpod-strut; gap pressure; podded propeller
AbstractNumerical investigations were performed to predict effects of propeller hub taper angle and pod geometry configurations on propulsive performance. An existing time domain panel method code was extended to handle the simulation tasks. The effect of taper angle was examined in terms of shaft thrust coefficient, KT, and torque coefficient, KQ, for different taper angles of -15° (pull/tractor configuration) and +15° (push configuration). The predicted pressure distribution was also analyzed to investigate the effect of taper ratio on pressure coefficient, Cp, at the blade root section. The effects of pod-strut geometry on KT and KQ of a propeller with taper angles of 15° and 20° with two pods both in push configuration were examined. A complementary experimental study of the effects of taper angle on propulsive performance was also conducted for 15° and 20° taper angles in push configuration. Numerical predictions and experimental measurement showed a good agreement over a wide range of advance coefficients from the bollard pull condition to the design advance coefficient of about 1.0.
Publication date
AffiliationNRC Institute for Ocean Technology; National Research Council Canada
Peer reviewedNo
IdentifierIR-2004-16
NRC number6052
NPARC number8895056
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Record identifier2309fa42-6248-4cb2-8e05-a6d3458cac3f
Record created2009-04-22
Record modified2016-05-09
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