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2020 | 27 | 1 |

Tytuł artykułu

Research on ship hull optimisation of high-speed ship based on viscous flow/potential flow theory

Autorzy

Warianty tytułu

Języki publikacji

EN

Abstrakty

EN
In order to quickly obtain practical ship forms with good resistance performance, based on the linear wave-making resistance theory, the optimal design method of ship forms with minimum total resistance is discussed by using the non-linear programming (NLP) method. Taking the total resistance as the objective function (the Michell integral is used to calculate the wave-making resistance and the equivalent plate friction resistance formula is used to calculate the frictional resistance), the hull surface offset as the design variable and appropriate displacement as the basic constraints, and considering the additional constraints, the hull bow shape and the whole ship are optimised, and an improved hull form is obtained. The resistance of the ship before and after optimisation is calculated by the CFD method to further evaluate the resistance reduction effect and performance after optimisation. Finally, an example of optimisation calculation of an actual high-speed ship is given. The obvious resistance reduction results confirm the reliability of the optimisation design method

Słowa kluczowe

Wydawca

-

Rocznik

Tom

27

Numer

1

Opis fizyczny

p.18-28,fig.,ref.

Twórcy

autor
  • Shanghai Maritime University, 1550 Haigang Av, 201306 Shanghai, China

Bibliografia

  • 1. Kim H. J., Choi J. E., Chun H. H. (2016): Hull-form optimization using parametric modification functions and particle swarm optimization. Journal of Marine Science and Technology, 21, 129–144.
  • 2. Li G. L., Long L. H., Tan Z. S. (1990): Energy-saving ship design. National Defense Industry press, Beijing, China.
  • 3. Liu X. Y., Wu J. W., Wan D. C. (2016): Ship type optimization based on genetic algorithm and NM theory. Hydrodynamic Research and Development, 31(5), 535–541.
  • 4. Li Z. Z. (2005): Research on ship type optimization based on wave resistance value calculation. Dalian University of Technology, China.
  • 5. Luo W. L., Lan L. Q. (2017): Design Optimization of the Lines of the Bulbous Bow of a Hull Based on Parametric Modeling and Computational Fluid Dynamics Calculation. Math Computation. Appl., 22(1), 43–54.
  • 6. Masut S., Suzuki K. (2001): Experimental Verification of Optimized Hull Form Based on Rankine Source Method. J. Kansai Soc. N. A., Japan, 236, 27–32.
  • 7. Ma K., Ichiro T. (1994): A study of minimum resistance hull form with consideration of separation (1st Report). J. Kansai Soc. N. A., Japan, 221, 9–15.
  • 8. Ma K., Zhang M. X., Ji Z. S. (2003): Ship floating calculation based on nonlinear programming. Journal of Dalian University of Technology, 43(3), 329–331.
  • 9. Huang F. X., Wang L. J., Yang C. (2015): Hull Form Optimization for Reduced Drag and Improved Seakeeping Using a Surrogate-Based Method. 25th International Ocean and Polar Engineering Conference, Kona, Big Island, Hawaii, USA.
  • 10. Hirt C. W., Nichols B. D. (1981): Volume of fluid (VOF) method for the dynamics of free boundaries. Journal of Computational Physics, 39(1), 201–225.
  • 11. Hsiung C. C. (1981): Optimal Ship Forms for Minimum Wave Resistance. Journal of Ship Research, 25(2), 95–116.
  • 12. Hsiung C. C. (1984): Optimal Ship Forms for Minimum Total Resistance. Journal of Ship Research, 28(3), 163–172.
  • 13. Wang S., Chen J. P., Wei J. F. (2013): The development and application research of an integrated optimization system based on the resistance in calm water and added resistance due to waves. 25th National Hydrodynamics Seminar and 12th National Hydrodynamics Academic Conference, Zhejiang, Zhoushan, 928–933.14. Wu J. W., Liu X. Y. and Wan D. C. (2016): MultiObjective Hydrodynamic Optimization of Ship Hull Based on Approximation Model. Proceedings of 26th (2016) International Ocean and Polar Engineering Conference Rhodes, Greece.
  • 15. Ye H. K. (1985): The wave resistance calculation and optimization of ship form with the tent function. Shipbuilding of China, 1985, 28–39.
  • 16. Zhang W. X. (2012): Comprehensive optimization of hull form for containership in wave based on EEDI. Wuhan University of Technology, China, Wuhan.
  • 17. Zhang S. L., Zhang B. J., Tezdogan T. et al. (2017): Computational fluid dynamics based hull form optimization using approximation method. Engineering Applications of Computational Fluid Mechanics, 12(3), 1–8.
  • 18. Zhang S. L., Zhang B. J., Tezdogan T. et al. (2017): Research on bulbous bow optimization based on the improved PSO algorithm. China Ocean Engineering, 33(4), 487–494.
  • 19. Zhang S. L., Tezdogan T., Zhang B. J. et al. (2017): Hull form optimization in waves based on CFD technique. Ships & Offshore Structures, 12(2), 1–16.
  • 20. Zhang B. J., Zhang S. L. (2018): Research on ship design and optimization based on simulation-based design (SBD) Technique. Shanghai Jiaotong University Press and Springer.
  • 21. Zou Y. (2012): Research on optimization method for high performance vessel Research on optimization method for high performance vessel. Dalian Maritime University, China, Dalian.

Typ dokumentu

Bibliografia

Identyfikatory

Identyfikator YADDA

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