New method for predicting full-scale power performance of pumpjet propulsion system based on statistical learning

Qiongfang YANG; Rui WU; Minmin ZHENG; Xuequan MA; Heng LIU; Yilin YANG

doi:10.19693/j.issn.1673-3185.02600

Chinese Journal of Ship Research, Volume. 17, Issue 6, 70(2022)

New method for predicting full-scale power performance of pumpjet propulsion system based on statistical learning

Qiongfang YANG¹, Rui WU², Minmin ZHENG², Xuequan MA², Heng LIU², and Yilin YANG²

Author Affiliations

¹College of Power Engineering, Naval University of Engineering, Wuhan 430033, China

²Shanghai Ship and Shipping Research Institute Co., Ltd., Shanghai 200137, China

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References(14)

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[3] ESLAMDOOST A, LARSSON L, BENSOW R. Analysis of the thrust deduction in waterjet propulsion–the Froude number dependence[J]. Ocean Engineering, 152, 100-112(2018).

[4] [4] BULTEN N W H. Numerical analysis of a waterjet propulsion system[D]. Eindhoven: Technische Universiteit Eindhoven, 2006.

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[6] [6] CDI Marine Company. Waterjet pump nozzle assembly designed f main propulsion of an advanced 50 knots monohull cargo ship[R]. [S. l. ]: Califnia State University CCDoTT Rept No. 7488, 2003.

[7] [7] HOYT J III, CHOI G I, LAMBERTI B, et al. The specialist committee on waterjets: final rept recommendations to the 22nd ITTC[C] Proceedings of the 22nd International Towing Tank Conference. herls: ITTC, 1999.

[8] [8] TERWISGA T J C, HOYT III J G, ZANGENEH M, et al. The specialist committee on validation of waterjet test procedures: final rept recommendations to the 23rd ITTC[C] Proceedings of the 23rd International Towing Tank Conference. herls: ITTC, 2002.

[9] [9] ZANGENEH M, CHOI G I, OLOFFSON N, et al. The specialist committee on validation of waterjet test procedures: final rept recommendations to the 24th ITTC[C]Proceedings of the 24th International Towing Tank Conference. Edinburgh, UK: ITTC , 2005.

[10] [10] WOUD H K, STAPERSMA D. Design of propulsion electric power generation systems[M]. London: The Institute of Marine Engineers, 2002.

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[13] [13] BRENNEN C E. Hydrodynamics of pumps[M]. Nwich, VT, USA: Concepts ETI Inc. , 1994.

[15] ALTOSOLE M, BENVENUTO G, FIGARI M et al. Dimensionless numerical approaches for the performance prediction of marine waterjet propulsion units[J]. International Journal of Rotating Machinery, 2012, 321306(2012).

[16] [16] CDI Marine Company, Systems Development Division. Waterjet selfpropulsion model test f application to a highspeed sealift ship, center f the commercial deployment of transptation technologies (CCDoTT)[R]. Los Angeles, CA: Califnia State University, 2007.

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Qiongfang YANG, Rui WU, Minmin ZHENG, Xuequan MA, Heng LIU, Yilin YANG. New method for predicting full-scale power performance of pumpjet propulsion system based on statistical learning[J]. Chinese Journal of Ship Research, 2022, 17(6): 70

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Paper Information

Category:

Received: Nov. 21, 2021

Accepted: --

Published Online: Mar. 26, 2025

The Author Email:

DOI:10.19693/j.issn.1673-3185.02600

Topics

laser devices and laser physics

Lasers and Laser Optics

Laser physics

laser manufacturing

Instrumentation, Measurement and Metrology