Abstract
Based on Hamilton’s principle, a nonlinear differential equation considering the effect of dead loads is formulated for box beams. By using Galerkin method, the effect of dead load on the natural frequencies of box beams with various restraint conditions being simply supported, fixed at both ends, cantilevered and fixed at one end and simply supported at the other end is studied. The effects of major physical parameters, including the magnitude of dead load, sectional inertia moment and inertia radius, span length, and restraint conditions are discussed, and the natural frequencies are presented for these box beams, with the nonlinear effect of dead load taken into account. The results show that the deterrent effect of dead loads has significant effect on the increase of the natural frequencies of box beams. It is further observed that this behavior is more apparent at lower-order natural frequencies; the varying deterrent effect of dead loads relates to the stiffness of structures and is more significant for more flexible structures.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
In general, engineering structures and components are mostly subjected to a combination of constant initial loads and variable additional loads [1]. The combination of these loads can be considered as live loads and is found to have significant effect on the sustainability and durability of the structures. When the structure bears these live loads, its deformation starts from the reference state of constant initial loads that mainly contain the initial stress which causes the subsequent deformation. The stress generated by constant initial load will produce deterrent effect, which will change the internal force and deformation of the structure under live loads. The deterrent effect is not only caused by the initial middle surface tension, but also induced by the initial bending. Brunelle [2] demonstrates the effect caused on structures due to the influence of initial middle surface tension. However, studies regarding the effect due to initial bending are found scarce. The stiffening effect caused by the initial bending stress of dead load is called dead load effect according to Takabatake [3].
Takabatake [3] considered the effects of dead loads on the static characteristics of beam for the first time and derived the static force differential equation of uniform beam under dead loads. He also studied the response under the dead loads of simply supported beam and clamped–clamped beam in addition. He reported the effect of dead loads on the dynamic characteristics of beams and plates [4, 5]. Zhou and Zhu [6,7,8,9] analyzed the effect of dead loads on the natural frequencies of beams and plates by means of finite element method. Zhang et al. [10,11,12,13,14,15] have studied the influence of dead loads effect on static and dynamic characteristics of arch beams. At this end, most of the studies and their findings are primarily based on solid beam. However, these studies did not involve the impact on the thin-walled box structures.
In this paper, the effect of dead loads on the thin-walled boxes structure is analyzed. A nonlinear differential equation considering the effect of dead loads is formulated for box beams, based on Hamilton’s principle. By using Galerkin method, the effect of dead load on the natural frequencies of box beams with various restraint conditions being simply supported, fixed at both ends, cantilevered and fixed at one end and simply supported at the other end. The effects of key physical parameters mainly, magnitude of dead load, sectional inertia moment and inertia radius, span length, and restraint conditions are subsequently discussed as a function of natural frequencies by taking into account the nonlinear effect of dead load.
Establishment of Differential Equation
Basic Assumption
The cross section and coordinate system which are used for deriving basic are shown in Figs. 1 and 2. Figure 2 represents the formula and force–deformation conditions of the beam when \(\hat{v}\) represents the deflection of beam under dead loads (\(\hat{p}\)); \(\bar{v}\) represents the deflection of beam under live loads (\(\bar{p}\)). The deflection state of beam under dead loads is used as the reference state, and \(\bar{v}\) is derived from this reference state.
At the assumption of the deformation of beam obeying the hypothesis of Bernoulli–Euler beam equation,the linear strain–displacement relationship can be written as [16],
where top slab
Bottom slab
Web slab
The nonlinear strain–displacement relationship can be written as
where top slab
Bottom slab
Web slab
where εx is the strain of beam; v is the deflection of beam.
Total Energy Expression
The strain energy under live loads can be written as
where \(\hat{U}\) is the strain energy under dead loads (\(\hat{p}\)); \(\bar{U}\) is the strain energy under live loads (\(\bar{p}\)),
where the positive stress \(\left( {\hat{\sigma }_{x} ,\bar{\sigma }_{x} } \right)\) is the bending normal stress produced by dead loads (\(\hat{p}\)) and live loads (\(\bar{p}\)), respectively. It should be noted that the direct stress \(\left( {\hat{\sigma }_{x} } \right)\) is a constant stress caused by dead loads, but the direct strain \(\left( {\bar{\varepsilon }_{x} } \right)\) is a strain caused by live loads. The linear strain–displacement relationship provided by Eq. (1) is used for the calculation of \(\bar{U}\). The nonlinear strain–displacement relationship provided by Eq. (5) is used for the calculation of \(\hat{U}\). It should be noted that the dead load’s effect of this part is the deterrent effect caused by both the middle surface tension of beam and the bending state stress of dead loads \(\left( {\hat{\sigma }_{x} } \right)\). It is assumed that the stress–strain relation is linear.
All the strain energy caused by live loads (\(\bar{p}\)) can be expressed as follows:
The strain energy of top slab
The strain energy of bottom slab
The strain energy of web slab
So, the strain energy caused by live loads (\(\bar{p}\)) can be written as
All kinds of strain energy caused by dead loads (\(\hat{p}\)) can be expressed as follows:
The strain energy of top slab
The strain energy of bottom slab
The strain energy of web slab
So, the strain energy caused by live loads (\(\hat{p}\)) can be given as
The total strain energy of the box beam becomes
The potential energy of external loads is
With the effect of rotational inertia neglected, the kinetic energy of beam can be expressed as follows:
Controlling Differential Equation
According to Hamilton’s principle, as an object move from a location at the time (t1) to another location at the time (t2), to all the distance the object may experience, the distance follows Newton’s law at every moment is the distance makes the value of Lagrangian function average on time become the extreme value [16, 17] ,
Substituting Eqs. (22), (23), (24) into Eq. (25) gives
where, as the beam is subjected to dead loads, one can get the following equation,
The boundary conditions are that,
In Eq. (26), considering the effect of dead loads on bending deformation, the control differential equation of the beam can be written as
The boundary conditions are that
The Solution of Differential Equation
Considering the effect of dead loads, controlling Eq. (29) can be modified as
The boundary conditions are
The displacement (\(\bar{v}\)) can be expressed as
Substituting Eq. (33) into Eq. (31) gives
Among them,
Define the parameter \(\bar{v}\) as
Among them, the definition of fn is defined as follows:
For simply supported box beam,
For box beam fixed at both ends,
For cantilevered box beam,
For box beam fixed at one end and simply supported at the other end,
By using Galerkin method, the controlling differential equation for the effect of bending deformation on the natural frequencies of beam can be expressed as
As the effect of initial bending deformation is considered, the natural frequencies of beam should be
Without considering the effect of initial bending deformation, the natural frequencies of beam are
Among them, the parameter k0n is defined as follows:
For simply supported box beam,
For box beam fixed at both ends,
For cantilevered box beam,
For box beam fixed at one end and simply supported at the other end,
Example and Analysis
The following parameters are adopted for the beam: E = 210 GPa; I0 = 2.5 × 10−4 m4; L0 = 8 m, A0 = 0.01 m2 (the reference value of gyration radius is that: \(r_{0} = \sqrt {I_{0} /A_{0} } = 0.158\;{\text{m}}\)). The dead load intensity is assumed to be: \(\hat{p}_{0} = 6.8\;{\text{kN}}/{\text{m}}\). The variables (\(\hat{p}\), l, I, r) can be expressed as follows: \(\hat{p} = \alpha_{{\hat{p}}} \hat{p}_{0}\), \(l = \alpha_{l} l_{0}\), I = αII0, r = αrr0. The numerical results change by the above parameters.
The effect of initial bending deformation on the natural frequencies of simple box beam is analyzed. So, in the following expression, ωi represents the circular frequencies of the ith vibration mode effected by initial bending deformation. ωi0 represents the circular frequencies of the ith vibration mode without the effect of initial bending deformation. \(\hat{p}_{0}\) represents a reference dead load per unit length of the beams. \(\hat{p}\) represents the practical value of initial load per unit length of the beams. Dimensionless form of coordinate, linear coordinate and logarithmic coordinate are adopted, respectively, for the lateral axis (\(\bar{p}_{0} /\hat{p}\)), while linear coordinate is used for the vertical axis \(\left( {\Delta = \left( {\omega_{i} - \omega_{i0} } \right)/\omega_{i0} \times 100\% } \right)\).
The relationship between the natural frequencies of the box beam and the change of initial load is shown in Fig. 3. It’s evident that natural frequencies of simple box beams have improved with increase loads. Further, the improvement is more obvious for the first natural frequency. Here the increase of natural frequencies should be regarded as a real increase of the natural frequencies produced by initial load stress. It is different from the natural frequencies those vary with the normal change of beam quality (m) at unit length [3].
Figures 4, 5 and 6 show the relationship between ∆ (affected by the change of sectional inertia moment αI, span length αL and gyration radius αr, respectively) and \(\bar{p}_{0} /\hat{p}\) (affected by different constraint conditions). Among them, the gyration radius changes under the condition that the area changes and the sectional inertia moment keep constant. Figure 7 shows comparison of effects of initial loads when the above parameters (αI, αL and αr) of simply supported beam changes. It is demonstrated that the smaller the sectional inertia moment or the gyration radius (the area changes and the sectional inertia moment keeps constant) is or the larger the span length is, the larger effect of dead loads on the natural frequencies of beam will be. Among them, the change of span length makes the largest effect.
Conclusion
This paper analyzes the effect of dead loads on the thin-walled box structures. A nonlinear differential equation considering the effect of dead loads is taken into account for formulating box beam model, based on Hamilton’s principle. By using Galerkin method, the effect of dead load on the natural frequencies of various box beams, with various restraint conditions being simply supported, fixed at both ends, cantilevered and fixed at one end and simply supported at the other end. The effects of key physical parameters, including the magnitude of dead load, sectional inertia moment and inertia radius, span length, and restraint conditions are discussed, and the natural frequencies are presented for these box beams, with the nonlinear effect of dead load is taken into account.
The following conclusions can be drawn:
- 1.
The bending deformation generated by dead loads will produce deterrent effect which causes an increase of the natural frequencies of box beam. This trend will get more obvious when the natural frequencies belong to a lower-order range or larger weight.
- 2.
The stiffness of box beam has an impact on the deterrent effect which caused by the initial bending deformation. It is concluded that more flexible structures which have a smaller sectional inertia moment, a larger span length or a lower gyration radius, the effect becomes more significant. Among them, the change of span length makes the largest effect.
References
X. Zhang, P. Zhang, X. Peng, Problems of small deformation on pre-stressed configuration. Eng. Mech. 20(3), 125–128 (2003). (in Chinese)
E.J. Brunelle, The statics and dynamics of a transversely isotropic Timoshenko beam. Compos. Mater. 4, 404–416 (1990)
H. Takabatake, Effects of dead loads in static beam. J. Struct. Eng. ASCE 116(4), 1102–1120 (1990)
H. Takabatake, Effects of dead loads on natural frequencies of beam. J. Struct. Eng. ASCE 117(4), 1102–1120 (1991)
H. Takabatake, Effects of dead loads in dynamic plate. J. Struct. Eng. ASCE 118(1), 34–51 (1992)
S. Zhou, X. Zhu, Analysis of effect of dead loads on natural frequencies of beam. J. China Railway Soc. 17(4), 98–103 (1995). (in Chinese)
X. Zhu, S. Zhou, A finite element method for analyzing the effect of dead loads. Eng. Mech. 13(3), 54–60 (1996). (in Chinese)
S. Zhou, X. Zhu, Analysis of effect of dead loads on natural frequencies of beam using finite element techniques. J. Struct. Eng. ASCE 122(5), 512–516 (1996)
S. Zhou, Stiffness method for non-linear analysis of effect of dead loads on plate. J. Vib. Shock 26(2), 33–36 (2007). (in Chinese)
J. Zhang, H. Liu, Z. Yang, Finite element analysis for effect of initial load on dynamic characteristic of a beam. J. Vib. Shock 31(12), 120–124 (2012). (in Chinese)
J. Zhang, S. Liu, P. Wu, The finite element analysis for effect of dead load on static responses of beam. Chin. J. Appl. Mech. 30(5), 762–767 (2013). (in Chinese)
J. Zhang, S. Zhou, Analysis of effect of dead loads on natural frequencies of arch beam. J. Vib. Shock 28(8), 163–167 (2009). (in Chinese)
S. Zhou, J. Zhang, Analysis of the effect of dead loads on static arch beam. Eng. Mech. 27(7), 120–125 (2010). (in Chinese)
J. Zhang, S. Zhou, Approximate solutions of static arch beam considering dead loads effect. Chin. J. Comput. Mech. 27(4), 655–660+666 (2010). (in Chinese)
J. Zhang, Nonlinear effect of initial load on mechanical behavior of beam. Lanzhou Jiaotong University Doctoral thesis (Lanzhou, 2010) (in Chinese)
K. Washizu, Variational Methods in Elasticity and Plasticity (Pergaman Press, New York, 1982)
S. Sutar, R. Madabhushi, K.R. Chellapilla et al., Determination of natural frequencies of fluid conveying pipes using Muller’s method. J. Inst. Eng. India Ser. C (2018). https://doi.org/10.1007/s40032-018-0446-6
Acknowledgements
The work described in this paper was financially supported by the National Natural Science Foundation of China (No. 50368035), the Natural Science Foundation of Gansu Province, China (No. 145RJZA210) and Gansu Provincial Department of Housing and Urban–Rural Development (No. JK2014-16), to which the authors are grateful.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made.
About this article
Cite this article
Zhang, J., Luo, F., Liu, T. et al. Galerkin Analysis of Effect of Dead Load on Natural Frequencies of Box Beam. J. Inst. Eng. India Ser. C 100, 949–954 (2019). https://doi.org/10.1007/s40032-018-0494-y
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s40032-018-0494-y