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Impact of propeller emergence on hull, propeller, engine, and fuel consumption performance in regular head waves

Treść / Zawartość
Identyfikatory
Warianty tytułu
Języki publikacji
EN
Abstrakty
EN
In this study, the impact of propeller emergence on the performance of a ship (speed), propeller (thrust, torque, and RPM), a diesel engine (torque and RPM) and fuel consumption are analysed under severe sea conditions. The goal is to describe the variation in the system variables and fuel consumption rather than analysing the motion of the ship or the phenomenon of propeller ventilation in itself. A mathematical model of the hull, propeller, and engine interactions is developed in which the propeller emergence is included. The system parameters are set using model experiments, empirical formulae, and available data for the engine. The dynamic response of the system is examined in regular head waves under submerged and emerged conditions of the propeller. The pulsatility and the extent of variation of 20 selected variables for the coupled system of hull, propeller, and engine are elaborated using quantitative and qualitative terms and absolute and relative scales. The simulation begins with a ship moving on a straight path, in calm water, with a constant speed for the ship, propeller and engine under steady conditions. The ship then encounters regular head waves with a known time series of the total resistance of the ship in waves. Large motions of the ship create propeller emergence, which in turn reduces the propeller thrust and torque. This study shows that for a specific ship, the mean ship speed, shaft angular velocity, and engine power were slightly reduced in submerged conditions with respect to calm water. We compared the mean values of the variables to those in the emerged condition, and found that the shaft angular velocity was almost the same, the ship speed was considerably reduced, and the engine power significantly dropped with respect to calm water. The ratios of the amplitude of fluctuation to the mean (Amp/Mean) for the ship speed and angular velocity of the shaft under both conditions were considerable, while the Amp/Mean for the power delivered by the engine was extremely high. The outcomes of the study show the degree of influence of propeller emergence on these variables. We identify the extent of each change and categorise the variables into three main groups based on the results.
Rocznik
Tom
Strony
56--76
Opis fizyczny
Bibliogr. 40 poz., rys., tab.
Twórcy
  • Gdańsk University of Technology Faculty of Mechanical Engineering and Ship Technology Gdańsk Poland
  • Amirkabir University of Technology Faculty of Maritime Technology Iran
Bibliografia
  • 1. K. Rudzki, P. Gomulka, and A. T. Hoang, “Optimization model to manage ship fuel consumption and navigation time,” Polish Maritime Research, 3 (115) vol. 29, pp. 141-153, 2022, doi: 10.2478/pomr-2022-0034.
  • 2. T. T. Ngoc, D. D. Luu, T. H. H. Nguyen, and M. V. Nguyen, “Numerical prediction of propeller-hull interaction characteristics using RANS method,” Polish Maritime Research, 2 (102) vol. 26, pp. 163-172, 2019, doi:10.2478/ pomr-2019-0036.
  • 3. M. B. Samsul, “Blade cup method for cavitation reduction in marine propellers,” Polish Maritime Research, 2 (110) vol. 28, pp. 54-62, 2021, doi: 10.2478/pomr-2021-0021.
  • 4. Y. Zhang, X. P. Wu, M. Y. Lai, G. P. Zhou, and J. Zhang, “Feasibility study of RANS in predicting propeller cavitation in behind-hull conditions,” Polish Maritime Research, 4 (108) vol. 27, pp. 26-35, 2020, doi: 10.2478/ pomr-2020-0063.
  • 5. B. Lou and H. Cui, “Fluid–structure interaction vibration experiments and numerical verification of a real marine propeller,” Polish Maritime Research, 3 (111) vol. 28, pp. 61-75, 2021, doi: 10.2478/pomr-2021-0034.
  • 6. L. Guangnian, Q. Chen, and Y. Liu, “Experimental study on dynamic structure of propeller tip vortex,” Polish Maritime Research, 2 (106) vol. 27, pp. 11-18, 2020, doi: 10.2478/pomr-2020-0022.
  • 7. P. K. Quang, P. V. Hung, N. C. Cong, and T. X. Tung, “Effects of rudder and blade pitch on hydrodynamic performance of marine propeller using CFD,” Polish Maritime Research, 2 (114) vol. 29, pp. 55-63, 2022, doi: 10.2478/pomr-2022-0017.
  • 8. A. Nadery and H. Ghassemi, “Numerical investigation of the hydrodynamic performance of the propeller behind the ship with and without WED,” Polish Maritime Research, (108) vol. 27, pp. 50-59, 2020, doi: 10.2478/pom r-2020 – 0065.
  • 9. K. Koushan, “Dynamics of ventilated propeller blade loading on thrusters due to forced sinusoidal heave motion,” in Proceedings of the 26th Symposium on Naval Hydrodynamics, Rome, Italy, 2006.
  • 10. A. M. Kozlowska, S. Steen, and K. Koushan, “Classification of different type of propeller ventilation and ventilation inception mechanism,” in Proceedings of the First International Symposium on Marine Propulsors, 2009.
  • 11. K. Koushan, S. J. Spence, and T. Hamstad, “Experimental investigation of the effect of waves and ventilation on thruster loadings,” in Proceedings of the 1st International Symposium on Marine Propulsors (SMP’09), 2009.
  • 12. A. Califano and S. Steen, “Analysis of different propeller ventilation mechanisms by means of RANS simulations,” in Proceedings of the First International Symposium on Marine Propulsors, 2009.
  • 13. M. Palm, D. Jürgens, and D. Bendl, “Numerical and experimental study on ventilation for azimuth thrusters and cycloidal propellers,” in Proc. 2nd Int. Symp. Marine Propulsors SMP, 2011.
  • 14. K. Koushan, S. Spence, and L. Savio, “Ventilated propeller blade loadings and spindle moment of a thruster in calm water and waves,” in Proceedings of the Second International Symposium on Marine Propulsors, SMP, 2011.
  • 15. A. M. Kozlowska, K. Wöckner, S. Steen, T. Rung, K. Koushan, and S. Spence, “Numerical and experimental study of propeller ventilation,” in Proceedings of the Second International Symposium on Marine Propulsors, Hamburg, Germany, 2011.
  • 16. K. J. Paik, “Numerical study on the performance of a partially submerged propeller in bollard condition,” in Proceedings of the Fifth International Symposium on Marine Propulsors (SMP’17), Session C, 2017.
  • 17. C. Yvin, P. Muller, and K. Koushan, “Numerical study of propeller ventilation,” in Proceedings of the Fifth International Symposium on Marine Propulsors, Espoo, Finland, 2017.
  • 18. A. M. Kozłowska, “Hydrodynamic loads on marine propellers subject to ventilation and out of water condition,” Norwegian University of Science and Technology (NTNU), 2019.
  • 19. A. M. Kozlowska, Ø. Ø. Dalheim, L. Savio, and S. Steen, “Time domain modeling of propeller forces due to ventilation in static and dynamic conditions,” Journal of Marine Science and Engineering, vol. 8, p. 31, 2020, doi: 10.3390/jmse8010031.
  • 20. V. I. Lanchukovsky, “Safe operation of marine power plants,” Institute of Marine Engineering, Science and Technology, 2009.
  • 21. T. Szelangiewicz and K. Żelazny, “Prediction of the influence of propeller emergence on its thrust reduction during ship navigation on waves,” 21 Scientific Journals of the Maritime University of Szczecin, pp. 83-87, 2010.
  • 22. T. Szelangiewicz and K. Żelazny, “The influence of propeller emergence on the load of a marine engine of a ship sailing on irregular wave,” Zeszyty Naukowe/Akademia Morska w Szczecinie, 2013.
  • 23. G. Theotokatos and V. Tzelepis, “A computational study on the performance and emission parameters mapping of a ship propulsion system,” in Proceedings of the Institution of Mechanical Engineers, Part M: Journal of Engineering for the Maritime Environment, vol. 229, pp. 58-76, 2015.
  • 24. B. Taskar, “The effect of waves on marine propellers and propulsion,” Norwegian University of Science and Technology (NTNU), 2017.
  • 25. E. Tokgoz, P. C. Wu, S. Takasu, Y. Toda, “Computation and experiment of propeller thrust fluctuation in waves for propeller open water condition,” Transactions of the Japan Society of Naval Architects and Ocean Engineers, vol. 25, pp. 55-62, 2017, doi: 10.2534/jjasnaoe.25.55.
  • 26. Y. Kitagawa, O. Bondarenko, and Y. Tsukada, “An experimental method to identify a component of wave orbital motion in propeller effective inflow velocity and its effects on load fluctuations of a ship main engine in waves,” Applied Ocean Research, vol. 92, p. 101922, 2019, doi: 10.1016/j.apor.2019.101922.
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  • 28. K. Minsaas, O. Faltinsen, and B. Persson, “On the importance of added resistance, propeller immersion and propeller ventilation for large ships in a seaway,” in PRADS 83—2nd International Symposium on Practical Design in Shipbuilding, Tokyo and Seoul, 17-22 Oct., 1983.
  • 29. K. Minsaas K, H. Thon, and W. Kauczyński, “Influence of ocean environment on thruster performance,” in Proc. Int. Symp. Propeller and Cavitation, 1986.
  • 30. K. Koushan, “Environmental and interaction effects on propulsion systems used in dynamic positioning: An overview,” in Proceedings of the 9th International Symposium on Practical Design of Ships and other Floating Structures (PRADS), 2004.
  • 31. Ø. N. Smogeli, “Control of marine propellers: From normal to extreme conditions,” Norwegian University of Science and Technology (NTNU), 2006.
  • 32. O. Bendarenko and K. Masashi, “Dynamic behaviour of ship propulsion plant in actual seas,” Marine Engineering, vol. 45, pp. 1012-1016, 2010, doi.org/10.5988/jime.45.1012.
  • 33. S. Saettone, “Ship propulsion hydrodynamics in wave,” Danish Technical University (DTU), 2020.
  • 34. H. Zeraatgar and M. H. Ghaemi, “The analysis of overall ship fuel consumption in acceleration manoeuvre using hull-propeller-engine interaction principles and governor features,” Polish Maritime Research, vol. 26, pp. 162-173, 2019, doi: 10.2478/pomr-2019-0018.
  • 35. M. H. Ghaemi and H. Zeraatgar, “Analysis of hull, propeller and engine interactions in regular waves by a combination of experiment and simulation,” Journal of Marine Science and Technology, vol. 26, pp. 257-272, 2021, doi: 10.1007/ s00773-020-00734-5.
  • 36. E. M. Lewandowski, The Dynamics of Marine Craft: Maneuvering and Seakeeping. World Scientific, WSPC, 2004.
  • 37. H. Zeraatgar, A. Moghaddas, and K. Sadati, “Analysis of surge added mass of planing hulls by model experiment,” Ships and Offshore Structures, vol. 15, pp. 310-317, 2020, doi: 10.1080/17445302.2019.1615705.
  • 38. B. Everitt, The Cambridge Dictionary of Statistics. Cambridge: Cambridge University Press, 1998.
  • 39. M. H. Ghaemi, “Performance and emission modelling and simulation of marine diesel engines using publicly available engine data,” Polish Maritime Research, 4 (112), Vol. 28, pp. 63-87, 2021, doi: 10.2478/pomr-2021-0050.
  • 40. O. M. Faltinsen, “Prediction of resistance and propulsion of a ship in a seaway,” in Proceedings of the 13th Symposium on Naval Hydrodynamics, Tokyo, 1980.
Uwagi
Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-67f60c91-8301-4a97-82c8-123a5554700d
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