Analysis of Crane Ship Lifting Load Swaying Character with Multi-Factors Coupling

Hui Li Ren; Ling Fu; Pan Li; Chang Chun Gao

doi:10.4028/www.scientific.net/AMM.321-324.3

Paper Titles

Preface and Conference Organization

Analysis of Crane Ship Lifting Load Swaying Character with Multi-Factors Coupling
p.3

Analysis of Dynamic Characteristics of Gear Transmission System Based on Wind Turbine Gearbox
p.9

Bifurcation and Strange Behavior for a Nonlinear Viscoelastic Rod System
p.13

Design of the Interval between Reaction Mass and Foundation in Vibration Test System
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Dynamometer Development of Motorcycle Engine Applied Kalman Filter
p.23

Effect of Track Measuring Beam on the Dynamic Properties of Rail Inspection Car
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Free Vibration Measurements of Single-Lap Cantilevered SPR Beams
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Influence upon Kinematics Performance of a Family of 3-PRS Parallel Mechanisms Affected by Kinematic Chain Layout
p.37

HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 321-324Analysis of Crane Ship Lifting Load Swaying...

Analysis of Crane Ship Lifting Load Swaying Character with Multi-Factors Coupling

Abstract:

Nonlinear movement will be generated on the crane ship lifting load with multi-factors coupling such as marine environmental loads, mass of load and the length of wire rope. The thesis bases on the technique of virtual prototype to establish a rigid-flexible multiply model of the crane ship with utilizing the software platform of ADAMS and ANSYS. Through analyzing the characteristics motion of the lifting load, providing a basis for the effective control of the crane ship lifting load.

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Periodical:

Applied Mechanics and Materials (Volumes 321-324)

Pages:

3-8

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.321-324.3

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Online since:

June 2013

Authors:

Hui Li Ren*, Ling Fu, Pan Li, Chang Chun Gao

Keywords:

Crane Ship, Environmental Loads, Swaying Character, Virtual Prototype Model

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References

[1] Witez, J.: J. Ocean Engineering, Vol.22, 411-420, (1995)

Google Scholar

[2] S.Surendran, Ramana Reddy & J. Venkata. J. Ocean Engineering, Vol.30, Issue 10, 1305-1317, (2003)

DOI: 10.1016/s0029-8018(02)00109-9

Google Scholar

[3] S. Surendran, S. K. Lee, J. Venkata Reddy and Gyoungwoo. Lee: Volume 32, Issues 14-15, October 2005:1818-1828

Google Scholar

[4] M. M. Idres, K. S. Youssef, & A. H. Nayfeh. A Nonlinear 8-DOF Coupled Crane-ship Dynamic Model[J].Structural Dynamic, and Materials Conference, 2003.

DOI: 10.2514/6.2003-1855

Google Scholar

[5] X.Y. Zhang, Y.L. Jin, H.R. Jing: J. Navigation of China (in Chinese)

Google Scholar

[6] L. Chen, C. Zhang, X.Y. Zhang: J. Journal of System Simulation (in Chinese)

Google Scholar

[7] H.L. Ren, X.L. Wang, Y.J. C.G. Hu: J.Journal of System Simulation (in Chinese)

Google Scholar

[8] Z.G. Li: Entry-Detailed and instances, National defense industry press, 2010 (in Chinese)

Google Scholar

[9] Release10.0 Documentation for ANSYS

Google Scholar

[10] F.C. Wang. Finite element analysis theory and engineering applications for ansys10.0, Publishing House of Electronics Industry, (2006)

Google Scholar

[11] J.M. Wu. Research on Dynamic Simulation of the Rotary Floating Crane Structure System Based on ADAMS, 2012 (in Chinese)

Google Scholar

[12] X.Y. You. Dynamic Analysis of Crane Ship in Regular Waves, (2009)

Google Scholar

[13] Schellin, T. E., Jiang, T., & Sharma, S. D.: J. Journal of Offshore Mechanics and Arctic Engineering, Vol. 113, 211-218, 1991.

Google Scholar