Wire rope contact model and crane control method for the advanced simulation and automation of block erection

이혜원 2020년

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논문상세정보

- 저자 이혜원
- 기타서명 블록 탑재 자동화 및 시뮬레이션 고도화를 위한 와이어 로프 접촉 모델 및 크레인 제어 방법
- 형태사항 iii, 219 p.: 삽화, 표: 26 cm
- 일반주기 참고문헌 수록
- 학위논문사항 서울대학교 대학원, 2020. 2, 조선해양공학과, 학위논문(박사) -
- DDC 623.8, 22
- 발행지 서울
- 언어 eng
- 출판년 2020
- 발행사항 서울대학교 대학원
- 주제어 Block erection operation Constraint-based wire rope Crane Frictional contact Interference Mooring system Physics based simulation Seabed interaction Control Multibody dynamics Underactuated system
- 참고문헌( 65)
유사주제 논문( 383)

인용/피인용

Wire rope contact model and crane control method f ...

' Wire rope contact model and crane control method for the advanced simulation and automation of block erection' 의 주제별 논문영향력

논문영향력 요약
동일주제 총논문수	논문피인용 총횟수	주제별 논문영향력의 평균
주제	Block erection operation Constraint-based wire rope Crane Frictional contact Interference Mooring system Physics based simulation Seabed interaction control multibody dynamics underactuated system
394	0	0.0%

논문영향력
주제		주제별 논문수	주제별 논문영향력
주제어	Block erection operation	1	0.0%
	Constraint-based wire rope	1	0.0%
	Crane	13	0.0%
	Frictional contact	2	0.0%
	Interference	73	0.0%
	Mooring system	8	0.0%
	Physics based simulation	1	0.0%
	Seabed interaction	1	0.0%
	control	266	0.0%
	multibody dynamics	24	0.0%
	underactuated system	4	0.0%
계		394	0.0%
* 다른 주제어 보유 논문에서 피인용된 횟수

' Wire rope contact model and crane control method for the advanced simulation and automation of block erection' 의 참고문헌

``Simulation ofContacts between wire rope and shell plate of a block for shipbuilding industry based on multibody dynamics
no . 5 , pp . 324-332 , [2012]
``Development and validation of a simulation-based safety evaluation program for a mega floatingCrane ,
pp . 101-116 , [2017]
[8] T.S. Walton and H. Polachek, Calculation of nonlinear transient motion of cables (technical report). David Taylor Model Basin, Washington, D.C., 1959.
[7] O.M. Faltinsen, Sea loads on ships and offshore structures. Cambridge University Press, New York, 1990.
[63] W. Blajer and K. Kolodziejczyk, “A geometric approach to solving problems of control constraints: Theory and a DAE framework,” Multibody System Dynamics, vol. 11, pp. 343-364, 2004.
[61] R. Altmann and J. Heiland, “Simulation of multibody systems with servo constraints through optimal control,” Multibody System Dynamics, vol. 40, pp. 75-98, 2017.
[59] R. Seifried and W. Blajer, “Analysis of servo-constraint problems for underactuated multibody systems,” Mech. Sci., vol. 4, pp. 113-129, 2013.
[58] W. Blajer and K. Kolodziejczyk, “Control of underactuated mechanical systems with servo-constraints,” Nonlinear Dyn., vol. 50, pp. 781-791, 2007.
[57] A. Zelei and G. Stepan, “Case studies for computed torque control of constrained underactuated systems,” Mechanical Engineering, vol. 56, no. 1, pp. 73-80, 2012.
[54] W. Blajer, R. Seifried, and K. Kolodziejczyk, “Servo-constraint realization for underactuated mechanical systems,”Arch. Appl. Mech., vol. 85, pp. 1191-1207, 2015.
[53] R. Taylor and P. Valent, Design guide for drag embedment anchors. Naval Civil Engineering Laboratory (USA), TN No N-1688, 1984.
[50] F.P. Bowden and D. Tabor, The friction and lubrication of solids. Clarendon Press, 2001.
[48] T. Möller and B. Trumbore, “Fast, minimum storage ray-triangle intersection,” Journal of Graphic Tools, vol. 2, no. 1, pp. 21-28, 1997.
[42] A. A. Shabana, Dynamics of multibody systems. Cambridge University Press, 2005.
[40] O.A. Bauchau, Flexible multibody dynamics. Springer, New York, 2011.
[39] E. Eich and M. Hanke, “Regularization methods for constrained mechanical multibody systems,” ZAMM - J. Appl. Math. Mech. / Zeitschrift für Angew. Math. und Mech., vol. 75, no. 10, pp. 761–773, 1995.
[36] F. Crivelli, The Störmer-Verlet method. Swiss Federal Institute of Technology, Zurich, 2008.
[32] J. M. Wendlandt and J. E. Marsden, “Mechanical integrators derived from a discrete variational principle,” Phys. D Nonlinear Phenom., vol. 106, no. 3–4, pp. 223–246, Aug. 1997.
[31] R. Featherstone, Rigid body dynamics algorithms. Springer, New York, 2008.
[29] K. Changizi and A.A. Shabana, “A recursive formulation for the dynamic analysis of open loop deformable multibody systems,” Journal of Applied Mechanics, vol. 55, no. 3, pp. 687-693, 1988.
[25] A.A. Shabana, Dynamics of multibody systems. Cambridge University Press, New York, 1998.
[24] F.M.L. Amirouche, Computational methods in multibody dynamics. Prentice Hall, 1992.
[23] A.A. Shabana, Computational dynamics. John Wiley & Sons, New York, 1994.
[11] K.J. bathe, Finite element procedures. 2nd Edition, Prentice Hall, Watertown, 2014.
Variational time integrators in computational solid mechanics
vol . [2003]
Tracking control of an underactuated gantry crane using an optimal feedback controller
pp . 830-839 , [2013]
Tracking control for an underactuated two-dimensional overhead crane ,
pp . 597-606 , [2012]
Time-domain numerical simulation of ocean cable structures
vol . 33 , pp . 1373-1400 [2006]
Study on the FEM analysis of mooring line for floating multibody system ,
pp . 927-931 [2017]
Stabilization of constraints and integrals of motion in dynamical systems
[1972]
Simulation of load lifting with equalizers used in shipyards ,
vol . 61 , pp . 98-111 , [2016]
Recursive Lagrangian dynamics of flexible manipulator arms ,
vol . 3 , pp . 87-101 , [1984]
On the dynamics of a multicomponent mooring line
vol . 22 , pp . 311-334 [1986]
Numerical methods for the inverse dynamics simulation of underactuated mechanical systems
'' [2017]
Non-linear dynamic analysis of the response of moored floating structures ,
pp . 116-137 , [2016]
Multibody dynamic analysis of a heavy load suspended by a floating crane with constraint-based wire rope ,
vol . 109 , pp . 145–160 , [2015]
Integrated simulation method based on multibody dynamics for production design verification in ships and offshore structures
'' [2018]
Hybrid , multiresolution wires with massless frictional contacts
vol . 17 , no . 7 , pp . 970-982 , [2011]
Ghosts and machines : regularized variational methods for interactive simulations of multibodies with dry frictional contacts
[2007]
Geometric-PBC based control of 4-DOF underactuated overhead crane system
pp . 1232-1237 [2014]
Geometric numerical integration illustrated by the StörmerVerlet method
vol . 12 , [2003]
Flexible multibody dynamics : review of past and recent developments
vol . 1 , pp . 189-222 , [1997]
Finite element nonlinear analysis for catenary structure considering elastic deformation ,
vol . 63 , pp . 29-45 , [2010]
Faking dynamics of ropes and springs
vol . 17 , pp . 31-39 , [1997]
Event-based scenario manager for multibody dynamics simulation of heavy load lifting operations in shipyards
pp . 83-101 [2016]
Effects of different influence factors on static and dynamic analysis of mooring line
vol . 7 , no . 2 , pp . 95-102 , [2015]
Dynamics of dual pontoon floating structure for cage aquaculture in a two-dimensional numerical wave tank
pp . 918-936 , [2011]
Dynamics and flatness-based control of a kinematically undetermined cable suspension manipulator
vol . 16 , pp . 155-177 , [2006]
Dynamics analysis and active control of a floating crane , Tehnicki vjesnik , vol.22 , no.6
pp . 1383-1391 , [2015]
Dynamic tension of mooring system in deep sea with finite element method
vol . 27 , pp . 10-15 [2009]
Dynamic effect of a flexible riser in a fully connected semisubmersible drilling rig using the absolute nodal coordinate formulation
vol . 139 , [2017]
Dynamic analysis of spatial flexible multibody systems using joint co-ordinates
vol . 32 , no . 8 , pp . 1799-1812 , [1991]
Discrete mechanics and variational integrators
vol . 10 , pp . 357–514 , [2001]
Development of simple models for the elastic forces in the absolute nodal co-ordinate formulation
vol . 235 , no . 4 , pp . 539–565 , [2000]
Coupled analysis method of a mooring system and a floating crane based on flexible multibody dynamics considering contact with seabed ,
pp . 555-569 , [2018]
Cooperative control system of the floating cranes for the dual lifting ,
pp . 95-102 , [2018]
Computer methods for ordinary differential equations and differential-algebraic equations .
'' [1998]
Comparison of linear spring and nonlinear FEM methods in dynamic coupled analysis of floating structure and mooring system
pp . 205-227 , [2013]
Block turnover simulation considering the interferences between the block and wire ropes in shipbuilding
pp . 60-75 [2016]
Applied mechanics
[1982]
Application and validation of production planning simulation in shipbuilding
vol . 114 , pp . 154-167 , [2016]
Analysis of rigid body dynamic models for simulation of system with frictional contacts
vol . 68 , pp . 118-128 [2001]
A survey of underactuated mechanical systems
vol . 7 , no . 7 , pp . 921-935 , [2013]
A dry friction model to realize stick for simulation of the system with friction and accuracy verification of the friction model
vol . 22 , no . 8 , pp . 748-755 [2012]
A collaborative simulation in shipbuilding and the offshore installation based on the integration of the dynamic analysis , virtual reality , and control devices
pp . 699-722 [2019]

Wire rope contact model and crane control method for the advanced simulation and automation of block erection

유사주제 논문( 383)

' Wire rope contact model and crane control method for the advanced simulation and automation of block erection' 의 주제별 논문영향력

주제별 논문영향력

' Wire rope contact model and crane control method for the advanced simulation and automation of block erection' 의 참고문헌

' Wire rope contact model and crane control method for the advanced simulation and automation of block erection' 의 유사주제( ) 논문