Write your message

Volume 10 - Summer and Autumn 2018                   ijmt 2018, 10 - Summer and Autumn 2018: 25-35 | Back to browse issues page

XML Print

Download citation:
BibTeX | RIS | EndNote | Medlars | ProCite | Reference Manager | RefWorks
Send citation to:

Seyyedi S M, Shafaghat R, Donyavizadeh N. A Review on the Hydrodynamic Characteristics of the SPP Concerning to the Available Experimental Data and Evaluating Regression Polynomial Functions. ijmt 2018; 10 :25-35
URL: http://ijmt.ir/article-1-640-en.html
1- Babol University of Technology
Abstract:   (5175 Views)
Surface-piercing propellers have been widely used in light and high-speed vessels because of their superior performance. One of the major steps in propeller selection algorithm is the determination of thrust as well as torque hydrodynamic coefficients. For the purpose of simplifying design and selection procedure, some relations are presented for determining hydrodynamic coefficients in some studies, precision, and accuracy of which must be validated due to the importance of the issue as well as having high development and operational costs. Therefore, these issues are evaluated in this study by field study and recognizing the presented relation set as well as acquiring experimental test data. The acquired results show lack of full agreement between semi-experimental relations and experimental data. In the following, due to the limitations of the regression relations presented in the determination of hydrodynamic coefficients, the database was developed from experimental data, the number of series is determined by extracting the regression relations for each series, these relations are used to determine the hydrodynamic coefficient of thrust and torque in the propeller selection algorithm. Finally, a suitable algorithm for selecting the surface-piercing propeller was presented and discussed.
Full-Text [PDF 798 kb]   (2228 Downloads)    
Type of Study: Research Paper | Subject: Ship Hydrodynamic
Received: 2018/05/27 | Accepted: 2018/08/14

1. B. S., Yin Lu Young, and M. S., (2002), Numerical Modeling of Supercavitating and Surface-Piercing Propellers, Report No. 02−1 Thesis (Ph. D.), Department of civil engineering, The university of Texas at Austin, TX 78712, Environmental and water resources engineering.
2. Yangajeh, M.A, Seif, M.S. and Mehdigholi, H., (2009), Determination of propeller speed in experimental model of surface-piercing propeller, 11th international conference of Iranian marine industries, Kish island. (In Persian)
3. Montazeri, N. and Ghassemi, H., (2009), Determination of hydrodynamic coefficients of the surface-piercing propeller by regression method, 6th annual conference of design principles and applications of high-speed craft, chaloos, Iran.(In Persian)
4. Ferrando, M., (2007), Performance of family of surface piercing propellers, pp. 63-70.
5. Ghassemi, H., Hassanvand, M., Nazari, A., Hashemi, H., and Ghasabzade, M., (2009), Hydrodynamic analysis of Surface-piercing propeller, 6th annual conference of design principles and applications of high-speed craft, chaloos, Iran.(In Persian)
6. Memarian, H., Zeraatgar, H., Bakhshande rostami, A., (2009), Designing of the surface-piercing propeller for a high-speed craft, 11th international conference of Iranian marine industries, Kish island Iran. (In Persian)
7. Hadler, J.B., and Hecker, R., (1968), Performance of Partially Submerged Propellers, Proc 7th ONR Symposium on Naval Hydrodynamics, Rome.
8. Rose, J.C., and Kruppa, C. F., (1991), Methodical Series Model Test Results, FAST,91," Trondheim, Norway. Procs. Publ by Tapir Publishers, Trondheim, vol. 2, p. 1129.
9. Olofsson, N., (1996), Force and flow characteristics of a partially submerged propeller, Doctoral Thesis, Department of Naval Architecture and Ocean Engineering, Goteborg: Chalmers University of Technology.
10. Dyson, P.K., (2000), Modelling, testing and design, of a surface piercing propeller drive.
11. Nozawa, K., (2002), Hydrodynamic Performance and Exciting Force of SPP.
12. Ferrando, M., and Scamardella, A., (1996), Surface Piercing Propellers: Testing Methodologies, Result Analysis and Comments on Open Water Characteristics, pp. 1-27.
13. Ferrando, M., (1997), Surface piercing propellers: state of the art, Oceanic Eng. International, 1(2): 40–49.
14. Ferrando, M., and Scamardella, (1999), Surface-piercing propellers: model tests procedures and comments on related a dimensional parameters, Proceedings 5th Symposium on High-Speed Marine Vehicles, Capri, 24–26.
15. Ferrando, M., Viviani, M., Crotti, S., Cassella, P., Caldarella, S., (2006), Influence of Weber number on Surface Piercing Propellers model tests scaling, Proceedings of 7th International Conference on Hydrodynamics (ICHD), Ischia, 4–6.
16. Lorio, J.M., (2011), Open Water Testing of a Surface Piercing Propeller with Varying Submergence, Yaw Angle and Inclination Angle, Master of Science in Ocean Engineering, The College ofjabia Engineering and Computer Science, Boca Raton, Florida.
17. Misra, S.C., Gokan, R.P., Sha, O.P., Suryanarayana, Ch., and Suresh, R.V., (2012), Development of a Four-Bladed Surface Piercing Propeller Series Naval Engineering Journals, No. 124-4.
18. Carlton, J., (2007), Marine propellers and propulsion, Second edition, Butterworth-Heinemann.
19. Rajabiani, E., Imantalab, A., (2009), Mathematical analysis of a new model of the surface-piercing propeller by finite element method," national conference of maritime and shipping , chabahar, Iran.(In persian)
20. Pustoshny, A.V., Bointsov, V.P., Lebedev, E.P., and Stroganov, A., (2007), Development of 5-blade SPP series for fast speed boat Ninth international Conference on Fast Sea, Shanghai.

Send email to the article author

Rights and permissions
Creative Commons License This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.

Creative Commons License
International Journal of Maritime Technology is licensed under a

Creative Commons Attribution-NonCommercial 4.0 International License.