Grid Type and Turbulence Model Influence on Propeller Characteristics Prediction

Sikirica, Ante; Čarija, Zoran; Kranjčević, Lado; Lučin, Ivana

doi:10.3390/jmse7100374

Cited by 20 publications

(9 citation statements)

References 23 publications

(30 reference statements)

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“…The highest level of errors for the open water efficiency coefficients reaches a value slightly larger than 5% for the highest advance ratio, at which the thrust and torque have the lowest values over the domain, as Figure 4 bears out. The numerical solutions reported here are very similar to those reported in [38], even though the solvers were different and the closure to turbulence was achieved by using different models. Moreover, the present solutions are in a good agreement with most of those reported in [39], where various solvers were used to solve the benchmark case of the PPTC propeller by 14 attendees of the symposium.…”

Section: Grid Convergence Testsupporting

confidence: 67%

A DES-SST Based Assessment of Hydrodynamic Performances of the Wetted and Cavitating PPTC Propeller

Lungu

2020

JMSE

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The paper describes an investigation of the hydrodynamic performances of a five-bladed controllable pitch propeller, whose geometry was provided by Schiffbau-Versuchsanstalt (SVA) Potsdam GmbH Model Basin. Both cavitating and non-cavitating regimes are numerically simulated for different advance ratio coefficients. The numerical approach is based on a finite volume approach in which closure to the turbulence is achieved through detached eddy simulation (DES). Propeller open water (POW) characteristics are computed, and the numerical solutions are validated through extensive comparisons with experimental data. In addition, the bi-phasic flow for the cavitating regime is simulated, for which comparisons with the cavitation sketches are performed to check the ability of the solver to estimate the cavitation extent. Grid convergence tests are performed for both working regimes together with validation and verification checks, not only to size the level of the numerical errors, but also to prove the robustness of the chosen numerical approach. Finally, a set of final remarks will conclude the present research.

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Section: Grid Convergence Testsupporting

confidence: 67%

A DES-SST Based Assessment of Hydrodynamic Performances of the Wetted and Cavitating PPTC Propeller

Lungu

2020

JMSE

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“…Therefore, it was selected as the preferred approach for this study. Previous researches have shown that k- model and sliding mesh deliver sufficient accurate results [2,4,6]. Therefore, the k-epsilon turbulence model is conducted for each simulation case.…”

Section: The Numerical Methodology and Physical Modelmentioning

confidence: 99%

“…The numerical approach utilized for solving the Reynolds-averaged Navier-Stokes (RANS) equation is currently extensively utilized, yielding enhanced accuracy in the determination of solutions and flow characteristics [1]. Sikirica et al [2] investigated the effects of grid type and turbulence model on the prediction of propeller characteristics. Similar findings were obtained by the Realizable k- and SST k- models, however the Realizable model proved to be more precise and consistent.…”

Section: Introductionmentioning

confidence: 99%

Estimation of the required power of bow thruster based on numerical simulation

Danh,

Mai Linh,

Hai Ha

2023

IOP Conf. Ser.: Earth Environ. Sci.

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The paper presents the results of hydrodynamic characteristics of bow thruster (thrust coefficient K T , torque coefficient K Q ) in various pitch angles using RANSE method and compared to the experiment data provided by Maritime Advanced Research Centre (CTO S.A.), Gdansk, Poland. The required power of the bow thruster is estimated based on those numerical simulations. To get a better energy efficiency, the thrust-to-power ratio with pitch angle can be compared. The simulation of a rotating propeller is done using the sliding mesh approach. The k-epsilon turbulence model is utilized with commercial code ANSYS CFX when analyzing bow thruster performance. The results show that the difference between numerical and experiment results is quite high. Moreover, the power and the thrust-to-power ratio increase with the pitch angles and the bow thruster performs the best efficiency at the pitch angle of around 19°.

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“…Sikiraka et al analyzed marine propeller using structured grid and unstructured grid. Analysis is performed for open water characteristics and cavitating flow on Potsdam VP1304 [33]. For cavitating flows, the error is less than 2% compared to experimental results.…”

Section: Literature Reviewmentioning

confidence: 99%

Design Optimization of Marine Propeller using Elitist Particle Swarm Intelligence

Khan

Shoukat

Shah

et al. 2023

Preprint

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Marine transportation is still the primary source of global transportation. The propeller, which is a critical componentof the propulsion system, must be designed with multiple constraints and objectives to satisfy the need. Recent studies propose that utilizing an improved optimization algorithm and computational analysis would explore better designs than conventionalmethods. In the present study, Elitist Particle Swarm Optimization (EPSO) technique is implemented to optimize the design ofa marine propeller. Potsdam’s Conventional Propeller VP 1304 is used as a benchmark design case. Reynold’s Averaged NavierStokes equation based Computational Fluid Dynamics (CFD) along with Vortex Lattice Method (VLM) and Fluid StructureInteraction (FSI) model is used for computational analysis. The results obtained in this study are validated against the previously published experimental data. An optimized propeller design is proposed based on the Elitist Particle Swarm Optimization technique.It is observed that the proposed design shows improved open water performance for lower advance coefficient (J) valuesbased on the given constraints. It’s also observed that open water efficiency is improved by 7 percent for J=0.6 compared tothe original design. The one-way Fluid Structure Interaction analysis shows that the proposed design is structurally stable underopen water test conditions

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Grid Type and Turbulence Model Influence on Propeller Characteristics Prediction

Cited by 20 publications

References 23 publications

A DES-SST Based Assessment of Hydrodynamic Performances of the Wetted and Cavitating PPTC Propeller

A DES-SST Based Assessment of Hydrodynamic Performances of the Wetted and Cavitating PPTC Propeller

Estimation of the required power of bow thruster based on numerical simulation

Design Optimization of Marine Propeller using Elitist Particle Swarm Intelligence

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