The Coupling Effect on Torsional and Longitudinal Vibrations of
Marine Propulsion Shaft System

ÖZSOYSAL, Osman Azmi; Halilbeşe, Akile Neşe

doi:10.4274/jems.2021.68094

The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System

Akile Neşe Halilbeşe, (Ordu Üniversitesi, Deniz Mühendisliği Bölümü, Ordu, Türkiye)

Osman Azmi Özsoysal (İstanbul Teknik Üniversitesi, Gemi İnşaatı ve Gemi Mühendisliği Bölümü, İstanbul, Türkiye)

Journal of Eta Maritime Science

15 1

Yıl: 2021 Cilt: 9 Sayı: 4 Sayfa Aralığı: 274 - 282 Metin Dili: İngilizce DOI: 10.4274/jems.2021.68094 İndeks Tarihi: 31-05-2022

The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System

Öz:

The propulsion shaft system is one of the essential parts of the ships due to its reliability and stabilization directly affecting the safety in operation. The propulsion system transmits the torque generated by the engine to the propeller via the main shaft. During its navigation, torsional, longitudinal, and transversal vibrations inevitably occur, and precautions must be taken during the design stage to prevent system damage and reduce power transmission efficiency. In this article, three dissimilar models numerically generated by the lumped- mass method are used to investigate the harmonic conclusions of forced coupled torsional and longitudinal vibrations of the system. Numerical results correlated with the experimental results at rotational speed and load acting onto the propulsion shaft system. A further finding is to create a third method upon discussing the facts revealed by analyzing the advantages and disadvantages of the models, especially considering differences between the first two models

Anahtar Kelime:

Belge Türü: Makale Makale Türü: Araştırma Makalesi Erişim Türü: Erişime Açık

[1] I. Andersen, and J. Jensen, “Measurements in a container ship of wave-induced hull girder stresses in excess of design values,” Marine Structures, vol. 37, pp. 54-85, Jul 2014.
[2] L. Murawski, and A. Charchalis, “Simplified method of torsional vibration calculation of marine power transmission system,” Marine Structures, 39,335-349, Dec 2014.
[3] H., Han, K. Lee, and S. Park, “Estimate of the fatigue life of the propulsion shaft from torsional vibration measurement and the linear damage summation law in ships,” Ocean Engineering, vol. 107, pp. 212-221, Oct 2015.
[4] Q. Huang, X. Yan, C. Zhang, and H. Zhu, “Coupled transverse and torsional vibrations of the marine propeller shaft with multiple impact factors,” Ocean Engineering, vol. 178, pp. 48-58, April 2019.
[5] A. N. Halilbese, C. Zhang, and O. A., Özsoysal, “Effect of coupled torsional and transverse vibrations of the marine propulsion shaft system,” Journal of Marine Science and Application, vol. 20, pp. 201-212, Jun 2021.
[6] L. Brydum, and S. B Jakobsen, “Vibration characteristics of two-stroke, low speed diesel engines,” International Marine Propulsion Conference, 9th, MAN B&W Diesel a/s, Copenhagen, pp. 1-16, London, 1987.
[7] Y. Huang, and C. Horng, “Analysis of torsional vibration systems by the extended transfer matrix method,” Journal of Vibration and Acoustics, vol. 121, pp. 250-255, April 1999.
[8] J. S. Wu, and I. H. Yang, “Computer method for torsion-and- flexure coupled forced vibration of shafting system with damping,” Journal of Sound and Vibration, vol. 180, pp. 417-435, Feb 1995.
[9] Q. Huang, X. Yan, and Y. Wang, “Numerical and experimental analysis of coupled transverse and longitudinal vibration of a marine propulsion shaft,” Journal of Mechanical Science and Technology, vol. 30, pp. 5405-5412, Dec 2016.
[10] L. Murawski, “Axial vibrations of a propulsion system taking into account the couplings and boundary conditions,” Journal of Marine Science and Technology, vol. 9, pp. 171-181, Dec 2004.
[11] I. Senjanovića, I. Ančića, G. Magazinovićb, N. Alujevića, N. Vladimira, and D. Choc, “Validation of analytical methods for the estimation of the torsional vibrations of ship power transmission systems,” Ocean Engineering, vol. 184, pp. 107-120, Jul 2019
[12] L. Xiang, S. Yang, and C. Gan, “Torsional vibration of a shafting system under electrical disturbances,” Shock and Vibration, vol. 19, 1-11, 2012.
[13] D. Zou, J. Xu, J. Zhang, F. Lv, N. Ta, and Z. Rao, “The hydroelastic analysis of marine propellers considering the effect of the shaft: theory and experiment,” Ocean Engineering, vol. 221, pp. 108547, Feb 2021.
[14] Z. Gan-boa, and Z. Yaoa, “Reduced-order modeling method for longitudinal vibration control of propulsion shafting,” 2nd International Conference on Mechanical, Industrial, and Manufacturing Engineering, IERI Procedia, vol. 1, pp. 73-80, 2012.
[15] L. Dai, Z. Zhang, and D. Sun, “A study on axial, later and torsional coupled vibration of marine propulsion system with transfer matrices method, Shipbuilding of China, vol. 4, pp. 98-106, 1989. (in Chinese),”
[16] Q. Huang, X. Yan, Y. Wang, C. Zhang, and Z. Wang, “Numerical modeling and experimental analysis on coupled torsional- longitudinal vibrations of a ship’s propeller shaft,” Ocean Engineering, vol. 136, pp. 272-282, May 2017.
[17] M. Parsons, “Mode coupling in torsional and longitudinal shafting vibration,” Marine Technology, vol. 20, pp. 257-271, Jul 1983.
[18] D. Zou, C. Jiao, N. Ta, and Z. Rao, “Forced vibrations of a marine propulsion shafting with geometrical nonlinearity (primary and internal resonances),” Mechanism and Machine Theory, vol. 105, pp. 304-319, Nov 2016.
[19] D. Zou, L. Liu, Z. Rao, and N. Ta, “Coupled longitudinal-transverse dynamics of a marine propulsion shafting under primary and internal resonances,” Journal of Sound and Vibration, vol. 372, pp. 299-316, Jun 2016.
[20] S. Hassan, and G. Mehrdaad, “Free vibration of Timoshenko beam with finite mass rigid tip load and flexural-torsional coupling,” International Journal of Mechanical Sciences, vol. 48, pp. 763-779, Jul 2006.
[21] Q. Huang, J. Liu, C. Zhang, and X. Yan, “Analysis on propulsion shafting coupled torsional-longitudinal vibration under different applied loads,” Inter-noise, Conference paper Melbourne, Australia, 2014.
[22] D. Zou, Z. Rao, and N. Ta, “Coupled longitudinal-transverse dynamics of a marine propulsion shafting under super harmonic resonances,” Journal of Sound and Vibration, vol. 346, pp. 248- 264, Jun 2015.
[23] Q. Huang, H. Liu, and J. Cao, “Investigation of lumped-mass method on coupled torsional-longitudinal vibrations for a marine propulsion shaft with impact factors,” Journal of Marine Science and Engineering, vol. 7, pp. 95, April 2019.
[24] G. Kouroussis, and O. Verlinden, “Prediction of railway ground vibrations: accuracy of a coupled lumped mass model for representing the track/soil interaction,” Soil Dynamics and Earthquake Engineering, vol. 69, pp. 220-226, Feb 2015.
[25] Z. Tian, “Study of vibration model for large scale ship shafting subjected to hull deformations and main engine excitations,” Ph.D. dissertation, Wuhan University of Technology, China, 2016.

APA	Halilbeşe A, ÖZSOYSAL O (2021). The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System. , 274 - 282. 10.4274/jems.2021.68094
Chicago	Halilbeşe Akile Neşe,ÖZSOYSAL Osman Azmi The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System. (2021): 274 - 282. 10.4274/jems.2021.68094
MLA	Halilbeşe Akile Neşe,ÖZSOYSAL Osman Azmi The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System. , 2021, ss.274 - 282. 10.4274/jems.2021.68094
AMA	Halilbeşe A,ÖZSOYSAL O The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System. . 2021; 274 - 282. 10.4274/jems.2021.68094
Vancouver	Halilbeşe A,ÖZSOYSAL O The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System. . 2021; 274 - 282. 10.4274/jems.2021.68094
IEEE	Halilbeşe A,ÖZSOYSAL O "The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System." , ss.274 - 282, 2021. 10.4274/jems.2021.68094
ISNAD	Halilbeşe, Akile Neşe - ÖZSOYSAL, Osman Azmi. "The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System". (2021), 274-282. https://doi.org/10.4274/jems.2021.68094

APA	Halilbeşe A, ÖZSOYSAL O (2021). The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System. Journal of Eta Maritime Science, 9(4), 274 - 282. 10.4274/jems.2021.68094
Chicago	Halilbeşe Akile Neşe,ÖZSOYSAL Osman Azmi The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System. Journal of Eta Maritime Science 9, no.4 (2021): 274 - 282. 10.4274/jems.2021.68094
MLA	Halilbeşe Akile Neşe,ÖZSOYSAL Osman Azmi The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System. Journal of Eta Maritime Science, vol.9, no.4, 2021, ss.274 - 282. 10.4274/jems.2021.68094
AMA	Halilbeşe A,ÖZSOYSAL O The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System. Journal of Eta Maritime Science. 2021; 9(4): 274 - 282. 10.4274/jems.2021.68094
Vancouver	Halilbeşe A,ÖZSOYSAL O The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System. Journal of Eta Maritime Science. 2021; 9(4): 274 - 282. 10.4274/jems.2021.68094
IEEE	Halilbeşe A,ÖZSOYSAL O "The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System." Journal of Eta Maritime Science, 9, ss.274 - 282, 2021. 10.4274/jems.2021.68094
ISNAD	Halilbeşe, Akile Neşe - ÖZSOYSAL, Osman Azmi. "The Coupling Effect on Torsional and Longitudinal Vibrations of Marine Propulsion Shaft System". Journal of Eta Maritime Science 9/4 (2021), 274-282. https://doi.org/10.4274/jems.2021.68094