Volume 18, Issue 35 (5-2022)                   Marine Engineering 2022, 18(35): 141-150 | Back to browse issues page

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1- Persian Gulf University
Abstract:   (426 Views)
In this paper, the aim is to analyze the interaction of a commercial container vessel with irregular surface water waves by computational fluid dynamics and also to calculate the marine parameters of this structure, namely the response amplitude (RAO) operator, the kinetic response spectrum in the motion of the structure. Analysis tool in this research is STAR CCM + software based on computational fluid dynamics, which is one of the most powerful software in performing simulation and numerical analysis for the above problem. In this paper, after reviewing and analyzing the validation of the numerical model and analysis tools, the various marine and dynamic parameters for a commercial container vessel in the superficial state in different directions of irregular wave collision to the vessel are investigated.
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Type of Study: Research Paper | Subject: Ship Hydrodynamic
Received: 2022/05/22 | Accepted: 2022/08/31

1. Mohammed Moonesun, "Handbook of naval architecture engineering", first edition, 2012, pp. 130: 135. (In Persian)
2. Mohammad Saeed Seif, Amin Najafi, "Dynamic of Marine Vehicle", Sharif university Press, 2013. (In Persian)
3. Bhattacharyya, R., "DYNAMICS OF MARINE VEHICLES". Ocean Engineering,Wiley Series, 1978.
4. Lloyd., A. R. J. M. "Seakeeping: Ship Behaviour in Rough Weather". A.R.J.M. Lloyd, 1998.
5. Versteeg, H. K. and Malalasekera, W., "An Introduction to Computational Fluid Dynamics", Second Edition, PEARSON, 2007.
6. Gasparotti. C, Rusu. E, (2013), "Seakeeping Numerical Analysis in Irregular Waves of a Containership", University of Galati.
7. Ghasemi Hassan, Majdafar Sohrab, Gil Valiullah and Toheidi Hadi, 2014, "Numerical analysis of the effect of dimensional changes on the seakeeping behavior of DDG 51", Iranian Journal of Marine Science And Technology. (In Persian)
8. Stansberg, C.T., Baarholm, R. et al, "Extreme Wave Amplification and Impact Loads on Offshore Structures", Offshore Technology Conference, Houston, TX, U.S.A, May 2005. [DOI:10.4043/17487-MS]
9. Chephine. M, Ribbel. M, (2007), "Hydrodynamic Coefficient of Multihull Ship", PHD Thesis, University of Sao Paulo.
10. Jiao, J., Sun, S., Li, J., Adika Adenya, C., Ren, H., Chen, C., Wang, D. "A comprehensive study on the seakeeping performance of high speed hybrid ships by 2.5D theoretical calculation and different scaled model experiments". Ocean Engineering,Vol. 160, pp. 197-223, 2018. [DOI:10.1016/j.oceaneng.2018.04.051]
11. Shariati, S. K., Mousavizadegan, S. H., "The effect of appendages on the hydrodynamic characteristics of an underwater vehicle near the free surface". Applied Ocean Engineering,Vol. 64, pp. 31-43, 2017. [DOI:10.1016/j.apor.2017.07.001]
12. Gertler, M., Hagen, G.R., "Standard Equations of Motion for Submarine Simulation". Naval Ship Research and Development Center, USA, 1967. [DOI:10.21236/AD0653861]
13. Sezen, S., Dogrul, A., Delen, C., Bal, S., "Investigation of self-propulsion of DARPA Suboff by RANS method". Ocean Engineering,Vol. 150, pp. 258-271, 2018. [DOI:10.1016/j.oceaneng.2017.12.051]
14. Venture. S, (2001),"Expremental seakeeping test of vessel in Deep Water"15-STAR-CCM+: User guide, tutorials, knowledge base, Simcenter, Siemens, 2020.
15. Ovegard, E., "Numerical simulation of parametric rolling in waves". Master thesis, KTH Centre for Naval Architecture, February 2009.
16. Koskinen, K., "Numerical simulation of ship motion due to waves and manoeuvring". Degree project in Naval Architecture, Second cycle, Stockholm, Sweden 2012
17. Koskinen, K., "Numerical simulation of ship motion due to waves and manoeuvring". Degree project in Naval Architecture, Second cycle, Stockholm, Sweden 2012.

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