|Table of Contents|

Citation:
 Mohammed Adnan Rizk,Samir E. Belhenniche,Omar Imine,et al.Cavitation Predictions of E779A Propeller by a RANSE-based CFD and Its Performance Behind a Generic Hull[J].Journal of Marine Science and Application,2023,(2):273-283.[doi:10.1007/s11804-023-00342-w]
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Cavitation Predictions of E779A Propeller by a RANSE-based CFD and Its Performance Behind a Generic Hull

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Title:
Cavitation Predictions of E779A Propeller by a RANSE-based CFD and Its Performance Behind a Generic Hull
Author(s):
Mohammed Adnan Rizk1 Samir E. Belhenniche2 Omar Imine3 Omer Kemal Kinaci456
Affilations:
Author(s):
Mohammed Adnan Rizk1 Samir E. Belhenniche2 Omar Imine3 Omer Kemal Kinaci456
1 Faculty of Mechanical and Electrical Engineering, Maritime Engineering Department, Tishreen University, Lattakia, Syria;
2 Naval Aero-Hydrodynamic Laboratory, Marine Engineering Department, USTO MB, Oran 31000, Algeria;
3 Aeronautics and Propulsion Systems Laboratory, Mechanical Engineering Department, USTO MB, Oran 31000, Algeria
Keywords:
CavitationMarine propellerPropulsion efficiencyPropeller-hull interactionINSEAN E779A
分类号:
-
DOI:
10.1007/s11804-023-00342-w
Abstract:
Ship propulsion performance heavily depends on cavitation, increasing the recent interest in this field to lower ship emissions. Academic research on the effects of cavitation is generally based on the open-water propeller performance but the interactions of the cavitating propeller with the ship hull significantly affect the propulsion performance of the ship. In this study, we first investigate the INSEAN E779A propeller by a RANSE-based CFD in open-water conditions. The numerical implementation and the selected grid after sensitivity analysis partially succeeded in modeling the cavitating flow around the propeller. Satisfactory agreement was observed compared to experimental measurements. Then, using the open-water data as input, the propeller’s performance behind a full-scale ship was calculated under self-propulsion conditions. Despite being an undesired incident, we found a rare condition in which cavitation enhances propulsion efficiency. At σ = 1.5; the propeller rotation rate was lower, while the thrust and torque coefficients were higher.

References:

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Memo

Memo:
Received date:2022-09-08;Accepted date:2022-10-19。
Corresponding author:S.E. Belhenniche,E-mail:samir.belhenniche@univ-usto.dz
Last Update: 2023-06-02