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Frontiers of Mechanical Engineering

ISSN 2095-0233

ISSN 2095-0241(Online)

CN 11-5984/TH

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Front. Mech. Eng.    2014, Vol. 9 Issue (1) : 58-70    https://doi.org/10.1007/s11465-014-0289-7
RESEARCH ARTICLE
Analyzing the nonlinear vibrational wave differential equation for the simplified model of Tower Cranes by Algebraic Method
M.R. AKBARI1,D.D. GANJI2,*(),A.R. AHMADI3,Sayyid H. Hashemi KACHAPI2
1. Department of Civil Engineering, The University of Pardisan Mazandaran and Department of Chemical Engineering, University of Tehran, P.O. Box 66456-43516, Iran
2. Department of Mechanical Engineering, Babol University of Technology, P.O. Box 484, Babol, Iran
3. Department of Mechanical Engineering, Sari Branch, Islamic Azad University, Sari, P.O. Box 48161-19318, Iran
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Abstract

In the current paper, a simplified model of Tower Cranes has been presented in order to investigate and analyze the nonlinear differential equation governing on the presented system in three different cases by Algebraic Method (AGM). Comparisons have been made between AGM and Numerical Solution, and these results have been indicated that this approach is very efficient and easy so it can be applied for other nonlinear equations. It is citable that there are some valuable advantages in this way of solving differential equations and also the answer of various sets of complicated differential equations can be achieved in this manner which in the other methods, so far, they have not had acceptable solutions. The simplification of the solution procedure in Algebraic Method and its application for solving a wide variety of differential equations not only in Vibrations but also in different fields of study such as fluid mechanics, chemical engineering, etc. make AGM be a powerful and useful role model for researchers in order to solve complicated nonlinear differential equations.
Keywords Algebraic Method (AGM)      tower crane      oscillating system      angular frequency     
Corresponding Author(s): D.D. GANJI   
Issue Date: 16 May 2014
 Cite this article:   
M.R. AKBARI,D.D. GANJI,A.R. AHMADI, et al. Analyzing the nonlinear vibrational wave differential equation for the simplified model of Tower Cranes by Algebraic Method[J]. Front. Mech. Eng., 2014, 9(1): 58-70.
 URL:  
https://academic.hep.com.cn/fme/EN/10.1007/s11465-014-0289-7
https://academic.hep.com.cn/fme/EN/Y2014/V9/I1/58
F(t)External force exerting on the system
MMass of the block
a,bLength and height of the block
EIElastic modulus
mMass of the rigid beam(the horizontal beam)
hHeight of the non-rigid beam(the vertical one)
k=E.AhAxial rigidity
cDamping coefficient
LLength of the rigid beam
I1Moment of inertia for the rigid beam (the horizontal one)
I2Moment of inertia for the block
ωAngular frequency
Tab.1  Nomenclature
Fig.1  The schematic diagram of the physical model
Fig.2  The displacement diagram of the mentioned system
Fig.3  The achieved solution, θ(t), by AGM
Fig.4  The resulted phase plane by AGM
t0481216202428323640
θ(t)0.2-0.1810.129-0.0537-0.03160.111-0.1700.198-0.1890.146-0.0752
dθdt00.0753-0.1360.172-0.1760.148-0.09320.0200.0564-0.1222-0.1651
Tab.2  The obtained results for θ(t) and its derivative according to the Numerical solution of Eq. (27)
Fig.5  Comparing the obtained solution by AGM and Numerical Method
Fig.6  A comparison between the resulted phase planes by AGM and Numerical Method
Fig.7  A comparison among the obtained phase planes by AGM on the basis of the different amplitudes of vibration
Fig.8  The obtained solution by AGM
Fig.9  The resulted phase planes by AGM
t02468101214161820
θ(t)0.10.013-0.0518-0.00460.02670.00131-0.0138-0.0001240.0071-0.000219-0.00363
dθdt0-0.05970.00230.0305-0.0024-0.01560.001850.00793-0.00126-0.004020.000811
Tab.3  The obtained results for θ(t) and its derivative according to the Numerical Solution of Eq. (42)
Fig.10  Comparing the obtained solution by AGM and Numerical Method
Fig.11  A comparison between the resulted phase planes by AGM and Numerical Method
Fig.12  A comparison among the obtained phase planes by AGM based on the four different damping coefficients
Fig.13  The chart of the obtained solution by AGM
Fig.14  The resulted phase plane by AGM
t036912151821242730
θ(t)0.1-0.0320.06430.10240.01050.2097-0.05730.2683-0.1290.268-0.1984
dθdt0-0.3870.0531-0.3370.120-0.21170.178-0.04470.2030.11980.1764
Tab.4  The obtained results for θ(t) and its derivative according to the Numerical Solution of Eq. (56)
Fig.15  A comparison between the obtained solution by AGM and Numerical Method
Fig.16  Comparing the resulted phase planes by AGM and Numerical Method
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