Numerical Prediction of Propeller-Hull Interaction Characteristics Using RANS Method

• Published in: Polish maritime research Vol. 26; no. 2; pp. 163 - 172
• Main Authors: Tran Ngoc, Tu, Luu, Do Duc, Nguyen, Thi Hai Ha, Nguyen, Thi Thu Quynh, Nguyen, Minh Vu
• Format: Journal Article
• Language: English
• Published: Gdansk Sciendo 01.06.2019; De Gruyter Poland
• Subjects: Bulk carriers; Coefficients; Computer simulation; Evaluation; Finite element method; Free surfaces; hull; interaction; Mathematical models; Numerical prediction; Propeller; RANS equations; relative rotative efficiency; Rigid structures; Rigid-body dynamics; Rotating bodies; Rotation; Ships; thrust deduction; wake fraction
• ISSN: 2083-7429; 1233-2585; 2083-7429
• DOI: 10.2478/pomr-2019-0036

The paper presents the results of computational evaluation of the hull-propeller interaction coefficients, also referred to propulsive coefficients, based on the unsteady RANS flow model. To obtain the propulsive coefficients, the ship resistance, the open-water characteristics of the propeller, and the flow past the hull with working propeller were computed. For numerical evaluation of propeller open-water characteristics, the rotating reference frame approach was used, while for self-propulsion simulation, the rigid body motion method was applied. The rotating propeller was modelled with the sliding mesh technique. The dynamic sinkage and trim of the vessel were considered. The free surface effects were included by employing the volume of fluid method (VOF) for multi-phase flows. The self-propulsion point was obtained by performing two runs at constant speed with different revolutions. The well-known Japan Bulk Carrier (JBC) test cases were used to verify and validate the accuracy of the case studies. The solver used in the study was the commercial package Star-CCM+ from SIEMENS.