RANS Simulation of Podded Propulsor Performances in Straight Forward Motion 被引量：7

RANS Simulation of Podded Propulsor Performances in Straight Forward Motion

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摘要 The Computational Fluid Dynamics （CFD） approach is adopted to study the steady and unsteady performances of the podded propulsor by the Fluent software package. While the interactions of the propeller blades with the pod and strut are time-dependent by nature, the mixing plane model is employed firstly to predict the steady performance, where the interactions are time-averaged. Numerical experiments are carried out with systematically varied mesh sizes to investigate the dependence of the predicted force values on the mesh sizes. Furthermore, the sliding mesh model is employed to simulate the unsteady interactions between the blades, pod and strut. Based on the numerical results, the characteristics of unsteady hydrodynamic forces are discussed, and the applicability of the mixing plane model is investigated for puller-type podded propulsor. The Computational Fluid Dynamics （CFD） approach is adopted to study the steady and unsteady performances of the podded propulsor by the Fluent software package. While the interactions of the propeller blades with the pod and strut are time-dependent by nature, the mixing plane model is employed firstly to predict the steady performance, where the interactions are time-averaged. Numerical experiments are carried out with systematically varied mesh sizes to investigate the dependence of the predicted force values on the mesh sizes. Furthermore, the sliding mesh model is employed to simulate the unsteady interactions between the blades, pod and strut. Based on the numerical results, the characteristics of unsteady hydrodynamic forces are discussed, and the applicability of the mixing plane model is investigated for puller-type podded propulsor.

作者郭春雨杨晨俊马宁

机构地区 State Key Laboratory of Ocean Engineering School of Shipbuilding Engineering

出处《China Ocean Engineering》 SCIE EI 2008年第4期663-674,共12页 中国海洋工程（英文版）

基金 supported by the"Knowledge-based Ship Design Hyper-Integrated Platform(KSHIP)" a key project of the Ministry of Education and the Ministry of Finance of China

关键词 podded propulsor PROPELLER STEADY UNSTEADY podded propulsor propeller steady unsteady

分类号 U664.3 [交通运输工程—船舶及航道工程]

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