Skip to main content
EXTENDED SEARCH
Log in
Top
Journal of Engineering Mathematics
Published in:

Open Access 01-08-2024

Buckling phenomenon of vertical beam/column of variable density carrying a top mass

Author: Mustafa Turkyilmazoglu

Published in: Journal of Engineering Mathematics | Issue 1/2024

Activate our intelligent search to find suitable subject content or patents.

search-config
insite
CONTENT
download
DOWNLOAD
print
PRINT
insite
SEARCH
loading …

Abstract

The study delves into the buckling phenomenon of vertical columns with variable density supporting a top mass. It focuses on determining the optimal cross-sectional shapes and analyzing the stability of these columns under dynamic loading. The research employs both statistical and dynamical approaches to formulate the cross-sectional areas and scrutinize the vibrational modes of the columns. Key findings include the importance of the cross-sectional area over the shape of the columns, the influence of the top mass on stability, and the identification of exponential, parabolic, and linear cross-sectional structures as effective designs. The research also highlights the different vibrational behaviors of freely moving top and sliding top configurations, with exponentially supported columns showing enhanced stability against buckling. The study concludes by emphasizing the practical implications for designing stable vertical columns in structural engineering.
AI Generated

This summary of the content was generated with the help of AI.

Notes

Publisher's Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Abbreviations
abm
Parameters controlling the density variation along tower
\(c_1\)
Elasticity constant
A
Horizontal cross-sectional area of tower
E
Young’s modulus
\(F_1\)
Force due to top load
\(F_2\)
Pressure force owing to stress
g
Gravitational acceleration
I
Inertial moment
L
Height of tower column
\(m_T\)
Mass of top load
t
Time
u
Transverse beam deflection
x
Vertical location from bottom to top of tower
Y
Vibrating column mode
\(Y_s\)
Shape of tower from solids of revolution

1 Introduction

Determining the design parameters that influence the shape and stability of columns, beams, and towers is crucial in structural engineering. This knowledge allows for optimal design of both uniform and nonuniform beam structures [16]. This study focuses on exploring the shapes of nonuniform vertical columns supporting a constant top mass, with a subsequent analysis of how sudden changes in the shape affect their vibrational dynamics.
Many scholars have been working on the subject of Euler beam/column and its stability features under various physical mechanisms. Only the recent literature review associated with diverse engineering applications will be given here omitting the older valuable efforts on the topic. To cite, conservative loading effects of buckling considering follower axial force on the structural frames were studied numerically in [7]. In [8], light weight structures of tower carrying wind power were optimized by means of tapered tubular structure. Mechanical actuation and energy harvesting applications of bistable and multistable structures under axial load were analyzed through buckling phenomenon in [9]. Impact loading effects of precast concrete segmental columns were simulated in [10]. Stability of steel cold formed silo column was given in [11], based on axisymmetric and non-axisymmetric loads. [12] explored mono-symmetric channels from the perspective of lateral buckling using finite element method. Statics and dynamics of beams were compared in [13] with Sheremetev-Pelekh-Reddy-Levinson micro-beam model. The performance of tall mass-timber buildings against wind-induced vibrations was explored in-depth in [14]. A general formulation for the steel columns, beams, and beam-columns of variable geometry, loads, and supports was reported in [15]. Dynamic stability of curvilinear size-dependent beam with large deflections was analyzed in [16]. Thin-walled metallic and composite beam structures were examined in [17]. Primary and secondary external resonance situations in vibration of cantilever structures were studied in [18]. The research in [19] reported on the buckling estimates of thin shells of high-strength materials with huge thickness of the elements. Masonry walls subjected to blasts were reviewed from experimental and numerical approaches in Godi et all 2021. A simple computation method for length factors on framed stepped columns was proposed in [21]. One-three dimensional formulations of Euler-Bernoulli and Timoshenko nonlinear beams were presented in [22]. Kirchhoff plate equations were modified in [23] with insertion of couple stress model in determining the buckling and elastic properties of the graphene sheet. Further recent applications can be found in [24, 25], and [26]. Experimental and theoretical studies were also conducted for elaborating seismic response of powered columns in terms of the bearing capacity, corrosion endurance, ductility, cyclic loading, single-cycle energy dissipation, combined loadings, ultimate torsion, and stiffness in [27], in [28, 29], in [30], and in [31]. Various buckling phenomena were furthermore explored recently, for estimating core and nanocomposite skin characteristics of anisogrid lattice-core sandwich plates in [32], for testing centric pull-out of helically ribbed bars with nine different diameters on the bond strength in [33], and for assessing impacts of inertial load for huge slenderness piles in [34].
A vast body of research in the literature explores the shapes and dynamic properties of various beams. This study builds upon that foundation by focusing on two key aspects: (i) Identifying the cross-sectional shapes of vertical towers: We consider towers supporting a constant top mass and composed of material with a variable density. Base density-to-stress ratio, top mass-to-stress ratio, and density distribution parameters play crucial roles in determining the shape of the column. Our analysis reveals that exponential, parabolic, or linear ideal cross-sections are most effective in accommodating the top load, (ii) Analyzing the stability of these columns: Our goal is to understand the vibrational conditions leading to buckling phenomena under the combined influence of the top mass and the column’s rigidity. We focus on two configurations: freely moving top with a clamped bottom and clamped bottom with a sliding top. Both numerical and analytical methods are employed to examine the deflection modes and stability of these columns. Our results demonstrate that lighter tops are more susceptible to instabilities compared to heavier ones. Towers with more pronounced exponential bases exhibit enhanced stability against buckling. This study contributes to the field of structural engineering by providing insights into the optimal design of towers with variable-density materials, considering both shape and stability under dynamic loading.

2 The Column Beam Model

Fig. 1
A vertical nonuniform beam column configuration of height L holding a mass \(m_T\) on the top
A tall L tower column holding a mass load \(m_T\) on top it, as depicted in Fig. 1, is considered. The practical viability and scientific application in structural engineering could be Taiwan’s tallest building, Taipei 101, carrying a 660 tone pendulum on the top. Therefore, we are interested in determining the potential cross-sectional area A(x) subject to the subsequent constraints, in a manner to identify the shape of a load carrying column. An Euler beam is assumed without inertial rotation and shear defect. We further assume a variable density \(\rho (x)\) of the material as a function of vertical location x in the power form
$$\begin{aligned} \rho (x)= & {} \mu (1+ax)^m. \end{aligned}$$
(1)
Today’s world also witnesses structures like this with graduating materials and a tip mass for multi purposes. For instance, construction of skyscrapers with helipads at the top, or high buildings/hotels with infinity pools at the top.
With such scientific and industrial background in mind, at any position x, a finite thickness slice \( {\text {d}}x\) of cylindrical shell having infinitesimal mass
$$\begin{aligned} {\text {d}}M= & {} \rho A {\text {d}}x \end{aligned}$$
(2)
is exerted a gravitational force due to the gravitational acceleration g in the form
$$\begin{aligned} {\text {d}}F_1= & {} {\text {d}}M g. \end{aligned}$$
(3)
It is clear that at the top of the building when \(x=L\), the force \(F_1\) is only due to load \(m_T\) given by
$$\begin{aligned} F_1(x=L)= & {} m_T g. \end{aligned}$$
(4)
On the other hand, the cross-sectional area A(x) exposed to a uniform tension \(\tau \) can stand the mechanical pressure force
$$\begin{aligned} F_2(x)= & {} \tau A(x), \end{aligned}$$
(5)
whose differential is
$$\begin{aligned} {\text {d}}F_2= & {} \tau {\text {d}}A. \end{aligned}$$
(6)
At the equilibrium state, since no upward force is present, the net force by summing the forces in (3) and (6) must balance the zero force owing to the Newton’s law, resulting in the following initial-value problem regarding the function A(x) on account of (4)
$$\begin{aligned} {1\over A}{ {\text {d}}A\over {\text {d}}x}= & {} -{g\rho \over \tau } (1+ax)^m,\quad 0\le x <L \nonumber \\ A(1)= & {} {m_T g\over \tau }. \end{aligned}$$
(7)
Upon making the quantities dimensionless, the area by \(L^2\) and the x coordinate by L, it is further possible to convert the system (7) into its dimensionless form
$$\begin{aligned} {1\over A}{ {\text {d}}A\over {\text {d}}x}= & {} -\alpha (1+bx)^m,\quad 0\le x <1 \nonumber \\ A(1)= & {} \beta , \end{aligned}$$
(8)
where
$$\begin{aligned} \alpha ={\mu g L\over \tau },\quad \beta ={m_T g\over \tau L^2},\quad b=aL \end{aligned}$$
are the dimensionless physical parameters governing the statics of the tower. We see that \(\alpha \) measures the ratio of base mass to stress, while \(\beta \) measures the ratio of top load mass to stress, when g and L are maintained.
Having solved the initial-value problem in (8) yields the analytical solution
$$\begin{aligned} A(x)= & {} e^{\frac{\left( (1+b)^{1+m}-(1+b x)^{1+m}\right) \alpha }{b(1+m)}} \beta , \end{aligned}$$
(9)
whose form when \(m=-1\) can be achieved by taking the limit of (9)
$$\begin{aligned} A(x)= & {} \left( \frac{1+b}{1+b x}\right) ^{\frac{\alpha }{b}} \beta . \end{aligned}$$
(10)

3 Dynamic behavior of the column beam

The structural stability of towers laid in formula (9) can be studied from vibrational analysis making use of the dynamic beam equation [3538])
$$\begin{aligned} (E I u_{xx})_{xx}+(F_2u_x)_x+\rho A u_{tt}= & {} 0, \end{aligned}$$
(11)
Assuming an oscillation of frequency \(\omega \) represented by the wave modes
$$\begin{aligned} u(x,t)= & {} Y(x)e^{i\omega t}+c.c., \end{aligned}$$
(12)
the dimensionless form of the dynamic equation (11) can be rewritten as
$$\begin{aligned} \nu (A^2Y'')''+(AY')'-\alpha \Omega ^2A (1+b x)^m Y= & {} 0, \end{aligned}$$
(13)
where the normalized frequency is \(\Omega =\omega (L/g)^{1/2}\) and the normalized Young’s modulus is \(\nu =cE/\tau \).
In order to examine the vibration dynamics, various beam boundary conditions can be taken into account as usual in the beam stability analysis. We prefer here a free top with a clamped base and a sliding top with a clamped base. The relevant boundary conditions are then
$$\begin{aligned} Y(0)= & {} 0,\quad Y'(0)\;=\;0,\quad Y''(1)\;=\;0\qquad (FC),\nonumber \\ Y(0)= & {} 0,\quad Y'(0)\;=\;0,\quad Y'(1)\;=\;0\qquad (SC). \end{aligned}$$
(14)
Alongside with (14), a fourth boundary condition associated with both cases can be accomplished via balancing load momentum with the transverse shear stress at the top, yielding
$$\begin{aligned} \nu (A^2Y'')'+AY'= & {} -\beta \Omega ^2Y, \quad (x=1). \end{aligned}$$
(15)
A final normalization A by the factor \(\beta \) and \(\Gamma ^2=\nu \beta \) reveals that the complete dynamics can be simulated from the perturbation boundary-value problem
$$\begin{aligned} \Gamma ^2(A^2Y'')''+(AY')'-\alpha \Omega ^2A (1+b x)^m Y= & {} 0,\nonumber \\ \Gamma ^2(A^2Y'')'+AY'+\Omega ^2Y= & {} 0,\quad (x=1) \nonumber \\ Y(0)\;=\;0,\quad Y'(0)\;=\;0,\quad Y''(1)= & {} 0\qquad (FC),\nonumber \\ Y(0)\;=\;0,\quad Y'(0)\;=\;0,\quad Y'(1)= & {} 0\qquad (SC). \end{aligned}$$
(16)
From (16), the vibrational dynamics is governed by the ratio of base mass to stress parameter \(\alpha \), the frequency \(\Omega \), the scaled rigidity \(\Gamma \), and the cross-section area function A. An exact solution of the vibrating beam modes for the general cross-sectional areas A(x) from (16) cannot be unfortunately gained. However, for certain special parameters, exact solutions can be determined, as can be literally outlined in the Appendix. Accordingly, for instance, the threshold SC buckling modes (with \(\Omega =0\)) when \(m=-1\), \(\alpha =-2b=1\) possess the reduced scaled Young’s moduli
$$\begin{aligned} \Gamma= & {} \frac{2}{\sqrt{9+\frac{4\pi ^2 k^2}{\ln ^2 2}}},\quad k=1,2,3,\cdots , \end{aligned}$$
(17)
while in the case of constant cross-sectional area when the base density is negligible (with \(\alpha =0\)), the stationary critical modes are found from
$$\begin{aligned} \Gamma= & {} \frac{1}{(2k-1)\pi },\qquad k=1,2,3,\cdots \quad (SC),\nonumber \\ \Gamma= & {} \frac{2}{(2k-1)\pi },\qquad k=1,2,3,\cdots \quad (FC). \end{aligned}$$
(18)

4 Numerical/analytical simulation results and discussions

The analytical formula (9) and its numerical/analytical stability treatment will be presented in this section.

4.1 Equilibrium column beams

The main result in (9) clearly indicates that the shape of the tower is insignificant, because the cross-sectional area takes the crucial structural role of the tower. For example, if solids of revolution are taken into account, the shape of tower can be determined by revolving the below function about the \(x-\)axis
$$\begin{aligned} Y_s(x)= & {} \sqrt{A(x)\over \pi }, \end{aligned}$$
(19)
given A(x) in (9). It is worthy to note that the base cross-sectional area arising from (9) is formulated through
$$\begin{aligned} A(0)= & {} e^{\frac{\left( -1+(1+b)^{1+m}\right) \alpha }{b(1+m)}}\beta . \end{aligned}$$
(20)
This is significant to understand the base supportive area of the tower influenced by the design parameters \(\alpha ,\beta ;b,m\). Actually, the total weight of the loaded tower is met precisely by the base area A(0) in (20), since the dimensionless
$$\begin{aligned} total\; mass=\alpha \beta \int _0^1 (1+bx)^mA(x) {\text {d}}x+1=\beta A(0). \end{aligned}$$
Moreover, the column’s cross-sectional area is represented via natural exponential function
$$\begin{aligned} A(x)= & {} e^{\alpha -x \alpha } \beta , \end{aligned}$$
(21)
when m or b is zero. This special case exactly matches with the constant density analysis in [39], hence validating our present findings. Indeed, the corresponding buckling modes to \(\alpha =0\) as derived above through formulas (18) completely collide with those given in [39].
It is also intriguing to see from (10) that purely tapered conical towers are obtained, for instance,
$$\begin{aligned} A(x)= & {} \frac{(1+b x) \beta }{1+b},\quad (\alpha =-b),\nonumber \\ A(x)= & {} \frac{(1+b x)^2 \beta }{(1+b)^2},\quad (\alpha =-2b). \end{aligned}$$
(22)
Fig. 2
Density distributions across the vertical beam. a \(m=2\), b \(m=1\), c \(m=-1\) and d \(m=-2\)
The density variations across the tower are depicted in Fig. 2a–d for a variety of parameters m and b. Although not shown, \(m=0\) corresponds to constant density distribution, as also the case when \(b=0\), see Fig. 2a–d. It is observed that for a fixed positive power m, density increases from the bottom and the top of the tower will be heaviest if \(b>0\), the lightest otherwise. The scenario of course reverses when instead a fixed negative power m is considered.
The resultant cross-sectional areas of the load supporting column normalized by \(\beta \) are demonstrated next through Fig. 3a–f for various parameters m, b, and \(\alpha \). It is inferred from the figures that exponential (refer to Fig. 3a–c for \(m\ge 0\)), parabolic (refer to Fig. 3d, f for \(m=-1,-2\)), and linear (refer to Fig. 3e for \(m=-1\)) cross-sectional structures are possible. Arbitrary mixture of parameters are selected from the domain to seize diverse column characters. We anticipate that the common feature of the towers is to possess narrowing cross-sections starting from the base, except the limiting cases of \(\alpha ,b,m\) tending to zero. In the case of a positive power index m, as b reverts its sign from negative to positive, the vertical column beam should be supported with a much widening exponential base in order to compensate for the heavier upper narrowing portions. Otherwise, more straight bases are adequate to carry the top load through the equilibrium tower profiles. For negative power index m, the same support aforementioned toward the heavier top due to sign switch of b from positive to negative should be provided by means of parabolic or linear structural shapes. Notice the purely exponential cross-section in Fig. 3c from Eq. (21) and the tapered conical sections in Fig. 3e from equation (22). It is remarked that capturing the correct cross-sectional profile influenced by a variable density as illustrated through Fig. 3a–f is important in structural design engineering.
Fig. 3
Tower cross-sectional areas across vertical locations for a variety of b. a \(m=2\), \(\alpha =1\), b \(m=1\), \(\alpha =1\), c \(m=0\), d \(m=-1\), \(\alpha =3/4\), e \(m=-1\), \(\alpha =-b\), and f \(m=-2\), \(\alpha =3/4\)

4.2 Vibrating column beams

It is recalled that buckling phenomenon of beams occurs when \(\Omega <0\), thus the conditions at the critical vibration frequency \(\Omega =0\) is crucial. Table 1 lists the critical buckling modes (\(\Omega =0\)) for some selected parameters associated with five FC modes, and also SC modes in Table 2. They are numerically computed from (16), which are also in full agreement with the analytical formulas (17), (18), and (27) (refer to Fig. 10). Overall, columns with SC modes require smaller design parameters.
Table 1
First five critical buckling modes at several picked values of \(\alpha \), m, and \(b=-1/2\) for FC column
\(\Gamma \)
First Mode
Second Mode
Third Mode
Fourth Mode
Fifth Mode
\(\alpha =0.0,m=2\)
0.63662
0.21221
0.12732
0.09094
0.07074
\(\alpha =0.3,m=2\)
0.58466
0.20371
0.12275
0.08779
0.06831
\(\alpha =0.5,m=2\)
0.55338
0.19818
0.11981
0.08576
0.06676
\(\alpha =0.8,m=2\)
0.51096
0.19010
0.11554
0.08284
0.06453
\(\alpha =1.0,m=2\)
0.48538
0.18487
0.11278
0.08096
0.06309
\(\alpha =0.0,m=0\)
0.63662
0.21221
0.12732
0.09094
0.07074
\(\alpha =0.3,m=0\)
0.54087
0.19488
0.11776
0.08428
0.06560
\(\alpha =0.5,m=0\)
0.48694
0.18411
0.11185
0.08017
0.06245
\(\alpha =0.8,m=0\)
0.41831
0.16904
0.10362
0.07447
0.05807
\(\alpha =1.0,m=0\)
0.37949
0.15967
0.09852
0.07095
0.05537
\(\alpha =0.0,m=-1\)
0.63662
0.21221
0.12732
0.09094
0.07074
\(\alpha =0.3,m=-1\)
0.50315
0.18625
0.11291
0.08089
0.06299
\(\alpha =0.5,m=-1\)
0.43251
0.17082
0.10436
0.07493
0.05841
\(\alpha =0.8,m=-1\)
0.34774
0.15014
0.09292
0.06697
0.05228
\(\alpha =1.0,m=-1\)
0.30252
0.13782
0.08610
0.06223
0.04865
Table 2
First five critical buckling modes at several picked values of \(\alpha \), m, and \(b=-1/2\) for SC column
\(\Gamma \)
First Mode
Second Mode
Third Mode
Fourth Mode
Fifth Mode
\(\alpha =0.0,m=2\)
0.31831
0.10610
0.06366
0.04547
0.03537
\(\alpha =0.3,m=2\)
0.30464
0.10243
0.06151
0.04394
0.03418
\(\alpha =0.5,m=2\)
0.29558
0.10007
0.06012
0.04296
0.03342
\(\alpha =0.8,m=2\)
0.28215
0.09665
0.05813
0.04155
0.03233
\(\alpha =1.0,m=2\)
0.27337
0.09445
0.05686
0.04065
0.03163
\(\alpha =0.0,m=0\)
0.31831
0.10610
0.06366
0.04547
0.03537
\(\alpha =0.3,m=0\)
0.29433
0.09848
0.05911
0.04222
0.03284
\(\alpha =0.5,m=0\)
0.27837
0.09376
0.05630
0.04022
0.03129
\(\alpha =0.8,m=0\)
0.25481
0.08715
0.05241
0.03746
0.02914
\(\alpha =1.0,m=0\)
0.23957
0.08305
0.05000
0.03575
0.02782
\(\alpha =0.0,m=-1\)
0.31831
0.10610
0.06366
0.04547
0.03537
\(\alpha =0.3,m=-1\)
0.28475
0.09469
0.05680
0.04057
0.03155
\(\alpha =0.5,m=-1\)
0.26251
0.08785
0.05273
0.03767
0.02930
\(\alpha =0.8,m=-1\)
0.23005
0.07863
0.04728
0.03379
0.02629
\(\alpha =1.0,m=-1\)
0.20946
0.07310
0.04403
0.03148
0.02450
Beam deflection buckling modes corresponding to constant cross-sectional area in the case of negligible density with \(\alpha =0\) are illustrated in Fig. 4a, b. Only three modes with \(\Gamma \) from (18) are given through the graphs. Apparently, bending vibration is higher for FC modes owing to the freely moving top. Higher modes have also shorter amplitudes than the first fundamental (first) mode, indicating that they will oscillate much widely than the fundamental mode.
Fig. 4
Beam deflection modes for constant cross-section areas. a FC and b SC
Fig. 5
Buckling domain and modes for freely vibrating top at \(b=-1/2\). a, b First critical buckling mode, c, d second critical buckling mode, and e, f third critical buckling mode for the selected physical parameters
Fig. 6
Buckling domain and modes for freely vibrating top at \(b=1/2\). a, b First critical buckling mode, c, d second critical buckling mode, and e, f third critical buckling mode for the selected physical parameters
Figures 5a–f and 6a–f illustrate the evolution of the physical parameter range and buckling modes for the first three FC column modes across a vast parameter interval, for \(b=-1/2\) and \(b=1/2\), respectively. Bending vibrations are analyzed at \(\alpha =2\). Notably, similar trends are observed for both b values because the slight changes in design parameters lead to minor deviations in wave amplitudes. Interestingly, the figures reveal that for these modes, exponentially supported columns require higher design parameters but experience less bending compared to parabolically supported ones. This suggests that towers with a parabolic base might be more susceptible to instabilities. As shown in Figs. 5(f) and 6(f), higher modes exhibit more pronounced and potentially uncontrollable oscillatory twisting behavior.
Fig. 7
Buckling domain and modes for sliding top at \(b=-1/2\). a, b First critical buckling mode, c, d second critical buckling mode, and e, f third critical buckling mode for the selected physical parameters
Fig. 8
Buckling domain and modes for sliding top at \(b=1/2\). a, b First critical buckling mode, c, d second critical buckling mode, and e, f third critical buckling mode for the selected physical parameters
Figures 7a–f and 8a–f depict the physical parameter range and buckling modes for SC modes across a wide parameter interval, for cases where \(b=-1/2\) and \(b=1/2\), respectively. Consistent with the observations from Figs. 4(a,b), SC modes exhibit smaller bending vibrations due to the sliding top. In other aspects, they share similar characteristics with the modes presented in Figs. 5 and 6, with the key difference being that higher-order SC modes vibrate at higher frequencies. This suggests that SC modes may have lower resistance to vibrations, potentially leading to greater instability.
Based on the cross-sectional area formula in equation (9), we can conclude that the mass on top of the tower (represented by parameter \(\beta \)) has minimal influence (as a multiplying factor) during the determination of the column beam’s size. However, the mass parameter \(\Gamma \) plays a significant role in identifying the vibrating modes. A heavier top mass leads to a more stable vertical column because \(\beta \) is larger for the fundamental modes investigated. The effectiveness of a tuned mass damper was demonstrably illustrated during the April 2024 earthquake in Taiwan. The steel ball at the top of the Taipei 101 skyscraper acted as a damper, allowing the structure to gently sway and dissipate energy, thereby contributing to its stability. It is important to clarify that the top mass refers to a hanging mass, not a heavy impact load. Impact loads can cause irreversible damage to the structure’s natural vibration characteristics through external shock waves, unless properly absorbed.
The analysis revealed the key strengths of the employed analytical algorithm. It offers a simple and direct method for predicting the behavior of axially graded high-rise structures and towers with top masses. This includes evaluating their buckling modes and displacements, which can be invaluable for designers in constructing stable vertical columns. However, the current limitations lie in its inability to incorporate seismic sensitivity, necessitating further research. Additionally, the model neglects inertial rotation and shear deformation to some extent. Therefore, employing Timoshenko nonlinear beam theory would be a more accurate approach. Furthermore, the growing trend of constructing new shaped high-rises and modern skyscrapers with piecewise continuous density distributions and cross-sections necessitates further development. Future studies could focus on extending the current algorithm’s advantages to analyze these novel structures and explore its applicability in broader civil and mechanical engineering domains.

5 Conclusions

This research focuses on designing ideal shapes and analyzing the transverse vibration dynamics of column beams/towers with variable cross-sections and variable density, supporting a top load. In structural engineering, determining the design parameters that influence the shape and stability of vertical columns is crucial. This study employs both statical and dynamical approaches: (i) Statical approach: This enables us to formulate the cross-sectional areas of the columns, taking into account their variable density and top load, (ii) Dynamical approach: This allows us to scrutinize the characteristics of the vibrational modes of the derived ideal columns. To sum up the key findings; the cross-sectional area of nonuniform columns is more important than the shapes they receive. The top mass contributes as a multiplying factor of cross-sections. Whether the top of the tower will be heavier or lighter depends on the density distribution across the column. Vertical columns should be narrowing from the bottom to the top, supported with exponential, parabolic, or linear cross-sectional structures. Much widening base profiles are essential to accommodate the heavier top loads. FC towers demand higher design parameters for buckling phenomena rather than SC towers. Bending vibration is higher for FC modes owing to the freely moving top. Higher modes response with shorter amplitudes than the first fundamental mode. Towers with parabolic base are more prone to the instabilities, while exponentially supported columns are more durable. The SC modes are less resistive to the vibrational deflections, and hence are more likely to be unstable. The heavier top mass makes the vertical beam more stable.

Declarations

Conflict of interest

The author declares that he has no conflict of interest.
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://​creativecommons.​org/​licenses/​by/​4.​0/​.

Publisher's Note

Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
previous article Numerical simulations of shallow-water sloshing coupled to horizontal vessel motion in the presence of a time-dependent porous baffle
next article Perspective on the description of viscoelastic flows via continuum elastic dumbbell models
insite
CONTENT
download
DOWNLOAD
print
PRINT
Appendix

Appendix

Some analytical results of stability system (16) are presented in this Appendix.
The special case \(m=-1\)and \(\alpha =-2b=1\):
Replacing the second condition in (16) by the re-normalization of eigenfunctions with the constraint
$$\begin{aligned} Y''(0)= & {} 1 \end{aligned}$$
(23)
results in the mode shapes for FC
$$\begin{aligned} Y(x){} & {} = -\Bigg (\Big (16 e^{-2 i c \pi } (-2+x)^{\frac{1}{2} (-3-c)} \Big (i 2^{1+\frac{c}{2}} \left( -3+2^{\frac{5+c}{2}}+c\right) e^{\frac{5 i c \pi }{2}} (-2+x) \Gamma ^2 \left( -1+2 \Gamma ^2\right) \nonumber \\ {}{} & {} \qquad +2 i e^{\frac{3 i c \pi }{2}} (-2+x)^{1+c} \Gamma ^2 \left( 2^{c/2} \left( 5+c-4 (3+c) \Gamma ^2\right) +2 \sqrt{2} \left( -2+(5+c) \Gamma ^2\right) \right) \nonumber \\ {}{} & {} \qquad +e^{2 i c \pi } (-2+x)^{\frac{1+c}{2}} \Big (-2^{2+\frac{c}{2}} (-2+x) \Gamma ^2 \left( -4+(9+c) \Gamma ^2\right) -2 \sqrt{2} \left( -1+2 \Gamma ^2\right) \nonumber \\ {}{} & {} \quad \times \left( x+(-3+c) (-1+x) \Gamma ^2\right) +2^{\frac{1}{2}+c} \left( 2 x-(5+c) (-2+3 x) \Gamma ^2+8 (3+c) (-1+x) \Gamma ^4\right) \Big ) \Big )\Big )\nonumber \\ {}{} & {} \quad \Big /\left( (-1+c) (1+c)^2 \Gamma ^2 \left( -2^{2+ \frac{c}{2}} c \Gamma ^2+\sqrt{2} \left( 1+(-3+c) \Gamma ^2\right) + 2^{\frac{1}{2}+c} \left( -1+(3+c) \Gamma ^2\right) \right) \right) \Bigg ), \end{aligned}$$
(24)
with \(c=\sqrt{-4+9 \Gamma ^2}/\Gamma \). Enforcing the second of (16) then generates the eigenrelation
$$\begin{aligned} \Delta= & {} -\frac{32 \sqrt{2} \left( 1-2 \Gamma ^2\right) ^2 \left( -2 \left( 1+2^c\right) +\left( 3-c+2^{1+c} (3+c)\right) \Gamma ^2\right) }{(-1+c) (1+c)^2 \Gamma ^2 \left( -2^{2+\frac{c}{2}} c \Gamma ^2+\sqrt{2} \left( 1+(-3+c) \Gamma ^2\right) +2^{\frac{1}{2}+c} \left( -1+(3+c) \Gamma ^2\right) \right) }.\qquad \end{aligned}$$
(25)
Eventually, equating (25) to zero, the roots \(\Gamma \) are as shown in Fig. 9.
Fig. 9
Eigenvalues \(\Gamma \) (zero crossing points) from (25)
An analogous analysis yields fortunately exact eigenvalues for the SC modes computed from
$$\begin{aligned} \Gamma= & {} \frac{2}{\sqrt{9+\frac{4\pi ^2 k^2}{\ln ^2 2}}},\quad k=1,2,3,\cdots . \end{aligned}$$
(26)
The special case \(m=-1\)and \(\alpha =-b=1/2\):
Similar to the above analysis, the stationary modes are expressible in terms of lengthy Bessel functions this time, whose eigenrelations from second of (16) read
$$\begin{aligned} \Delta= & {} \frac{2 \sqrt{2} \pi \Gamma \left( -J_2\left( \frac{2}{\Gamma }\right) Y_1\left( \frac{2 \sqrt{2}}{\Gamma }\right) +J_1\left( \frac{2 \sqrt{2}}{\Gamma }\right) Y_2\left( \frac{2}{\Gamma }\right) \right) }{\Gamma ^2-\pi J_2\left( \frac{2}{\Gamma }\right) Y_0\left( \frac{2 \sqrt{2}}{\Gamma }\right) +\pi Y_2\left( \frac{2}{\Gamma }\right) \underset{0}{\overset{1}{F}}\left( 1,-\frac{2}{\Gamma ^2}\right) }, \quad (FC),\nonumber \\ \Delta= & {} \frac{-2 \sqrt{2} \pi \Gamma J_1\left( \frac{2}{\Gamma }\right) Y_1\left( \frac{2 \sqrt{2}}{\Gamma }\right) +4 \pi Y_1\left( \frac{2}{\Gamma } \right) \underset{0}{\overset{1}{F}}\left( 2,-\frac{2}{\Gamma ^2}\right) }{\Gamma -\pi J_1\left( \frac{2}{\Gamma }\right) Y_0\left( \frac{2 \sqrt{2}}{\Gamma }\right) +\pi Y_1\left( \frac{2}{\Gamma }\right) \underset{0}{\overset{1}{F}}\left( 1,-\frac{2}{\Gamma ^2}\right) },\quad (SC), \end{aligned}$$
(27)
Fig. 10
Eigenvalues \(\Gamma \) (zero crossing points) from (27). a FC and b SC
where, \(J_i and Y_i\)’s are the Bessel functions and \(\underset{0}{\overset{1}{F}}\) is the regularized hypergeometric function. The mutual eigenvalues \(\Gamma \) are demonstrated in Fig. 10a, b.
The special case \(\alpha =0\):
In this case, the whole vibrating modes can be found analytically, since the main equation in (16) reduces to simple ordinary differential equation
$$\begin{aligned} Y''+\Gamma ^2Y^{(4)}= & {} 0. \end{aligned}$$
(28)
Together with the normalization condition in (23), as well as the third and fourth conditions in (16) give rise to the mode shapes
$$\begin{aligned} Y(x)= & {} \Gamma \left( \Gamma -x \cot \left( \frac{1}{\Gamma }\right) - \Gamma \csc \left( \frac{1}{\Gamma }\right) \sin \left( \frac{1-x}{\Gamma }\right) \right) ,\quad (FC),\nonumber \\ Y(x)= & {} \Gamma \left( \Gamma -x \cot \left( \frac{1}{2 \Gamma }\right) - \Gamma \csc \left( \frac{1}{2 \Gamma }\right) \sin \left( \frac{1-2x}{2 \Gamma }\right) \right) ,\quad (SC). \end{aligned}$$
(29)
The second of equation (16) turns out to be
$$\begin{aligned} \Omega ^2 Y(1)+Y'(1)+\Gamma ^2Y^{(3)}(1)= & {} 0, \end{aligned}$$
(30)
generating the vibrating mode parameters
$$\begin{aligned} \Omega= & {} \frac{1}{\sqrt{\Gamma \tan \left( \frac{1}{\Gamma }\right) -1}}, \quad (FC),\nonumber \\ \Omega= & {} \frac{1}{\sqrt{-1+2\Gamma \tan \left( \frac{1}{2\Gamma }\right) }}, \quad (SC). \end{aligned}$$
(31)
The critical buckling conditions corresponding to \(\Omega =0\) in (31) lead to the thresholds for the studied columns
$$\begin{aligned} \Gamma= & {} \frac{1}{(2k-1)\pi },\qquad k=1,2,3,\cdots \quad (SC),\nonumber \\ \Gamma= & {} \frac{2}{(2k-1)\pi },\qquad k=1,2,3,\cdots \quad (FC). \end{aligned}$$
(32)
Literature
1.
Hill RD, Rozvany GIN, Wang CM, Leong KH (1979) Optimization, spanning capacity, and cost sensitivity of fully-stressed arches. J Struct Mech 7(4):375–410CrossRef
2.
Narayan R (1990) Beams and beam columns: stability and strength. CRC, Boca Raton
3.
Roman B, Pocheau A (2002) Postbuckling of bilaterally constrained rectangular thin plates. J Mech Phys Solids 50(11):2379–2401CrossRef
4.
Gustafsson D, Hehir J (2005) Stability of tall buildings. Master Thesis, Chalmers University of Technology, Sweden
5.
Builes-Mejia JC, Itani AM, Sedarat H (2010) Stability of bridge column rebar cages during construction. University of Nevada, TR0003 (REV 10/98)
6.
Marano GC, Trentadue F, Petrone F (2014) Optimal arch shape solution under static vertical loads. Acta Mech 225(3):679–686MathSciNetCrossRef
7.
Leung AYT (2009) Nonconservative dynamic axial-torsional buckling of structural frames using power series. Int J Mech Sci 51:807–815CrossRef
8.
Li Y, Lu J (2014) Lightweight structure design for wind energy by integrating nanostructured materials. Mater Des 57:689–696CrossRef
9.
Borchani W, Lajnef N, Burgueno R (2015) Energy method solution for the postbuckling response of an axially loaded bilaterally constrained beam. Mech Res Commun 70:114–119CrossRef
10.
Zhang X, Hao H, Li C (2016) Experimental investigation of the response of precast segmental columns subjected to impact loading. Int J Impact Eng 95:105–124CrossRef
11.
Rejowski K, Iwicki P (2016) Buckling analysis of cold formed silo column. Mech Mech Eng 20(2):109–120
12.
Nguyen TT, Thang PT, Lee J (2017) Lateral buckling analysis of thin-walled functionally graded open-section beams. Compos Struct 160:952–963CrossRef
13.
Krysko AV, Awrejcewicz J, Pavlov SP, Zhigalov MV, Krysko VA (2017) Chaotic dynamics of the size-dependent non-linear micro-beam model. Commun Nonlinear Sci Numer Simulat 50:16–28MathSciNetCrossRef
14.
Bezabeh MA, Bitsuamlak GT, Popovski M, Tesfamariam S (2018) Probabilistic serviceability-performance assessment of tall mass-timber buildings subjected to stochastic wind loads: Part I - structural design and wind tunnel testing. J Wind Eng Ind Aerodyn 181:85–103CrossRef
15.
Tankova TS (2018) Stability design of steel columns, beams and beamcolumns: behaviour, general formulation and reliability, PhD Dissertation, Universidade de Coimbra
16.
Krysko VA, Awrejcewicz J, Kutepova IE, Babenkova TV, Krysko AV (2019) Size-dependent non-linear dynamics of curvilinear flexible beams in a temperature field. Appl Math Model 67:283–296MathSciNetCrossRef
17.
Fazzolari FA (2020) A beam formulation with 3D capabilities for the free vibration analysis of thin-walled metallic and composite structures. Thin-Walled Struct 146:106441CrossRef
18.
Wang GX, Ding H, Chen LQ (2020) Gravitational effects and mode interactions of vertical cantilever beams. Int J Non-Linear Mech 123:103493CrossRef
19.
Neustadt YS, Grachev VA (2020) Relaxation oscillations and buckling prognosis for shallow thin shells. Z Angew Math Phys 71(4):142MathSciNetCrossRef
20.
Godio M, Portal NW, Flansbjer M, Magnusson J, Byggnevi M (2021) Experimental and numerical approaches to investigate the out-of-plane response of unreinforced masonry walls subjected to free far-field blasts. Eng Struct 239:112328CrossRef
21.
Tian W, Hao J, Zhong W (2021) Buckling of stepped columns considering the interaction effect among columns. J Constr Steel Res 177:106416CrossRef
22.
Krysko AV, Awrejcewicz J, Zhigalov MV, Bodyagina KS, Krysko VA (2021) On 3D and 1D mathematical modeling of physically nonlinear beams. Int J Non-Linear Mech 134:103734CrossRef
23.
Shabani F, Rash-Ahmadi S (2022) Length scale effect on the buckling behavior of a graphene sheets using modified couple stress theory and molecular dynamics method. Acta Mech 233:943–960MathSciNetCrossRef
24.
Cho JR (2022) Thermal buckling analysis of metal-ceramic functionally graded plates by natural element method. Struct Eng Mech 84(6):723–731
25.
Hashemi S, Ramezani S (2023) Evaluation of unilateral buckling of steel plates in composite concrete-steel shear walls. Struct Eng Mech 88(2):129–140
26.
Wang XM, Ke LL, Wang YS (2023) The dynamic response of the FGM coated half-plane with hysteretic damping under time harmonic loading. Struct Eng Mech 87(1):95–106MathSciNet
27.
Huang H, Huang M, Zhang W, Pospisil S, Wu T (2020) Experimental investigation on rehabilitation of corroded RC columns with BSP and HPFL under combined loadings. J Struct Eng 146
28.
Huang H, Huang M, Zhang W, Yang S (2021) Experimental study of predamaged columns strengthened by HPFL and BSP under combined load cases. Struct Infrastruct Eng 17:1210–1227CrossRef
29.
Huang H, Guo M, Zhang W, Zeng J, Yang K, Bai H (2021) Numerical investigation on the bearing capacity of RC columns strengthened by HPFL-BSP under combined loadings. J Build Eng 39:102266CrossRef
30.
Huang H, Yao Y, Liang C, Ye Y (2022) Experimental study on cyclic performance of steel-hollow core partially encased composite spliced frame beam. Soil Dyn Earthq Eng 163:107499CrossRef
31.
Huang H, Xue C, Zhang W, Guo M (2022) Torsion design of CFRP-CFST columns using a data-driven optimization approach. Eng Struct 251(A):113479CrossRef
32.
He L, Maalla A, Zhou X, Tang H (2024) Buckling and post-buckling of anisogrid lattice-core sandwich plates with nanocomposite skins. Thin-Walled Struct 199:111828
33.
Luo Y, Liao P, Pan R, Zou J, Zhou X (2024) Effect of bar diameter on bond performance of helically ribbed GFRP bar to UHPC. J Build Eng 91:109577CrossRef
34.
Zhang X, Wang S, Liu H, Cui J, Liu C, Men X (2024) Assessing the impact of inertial load on the buckling behavior of piles with large slenderness ratios in liquefiable deposits. Soil Dyn Earthq Eng 176:108322CrossRef
35.
Naprstek J (2015) Combined analytical and numerical approaches in dynamic stability analyses of engineering systems. J Sound Vibration 338(3):2–41CrossRef
36.
37.
Wang P, Rui X, Yu H, Zhang J (2019) Transverse vibration of the upper track of a tracked vehicle with tubular busing in the track pin. Mech Mach Theory 140:504–519CrossRef
38.
Kollar LP, Tarjan G (2021) Mechanics of civil engineering structures. Elsevier Science, pp 229–297
39.
Metadata
Title
Buckling phenomenon of vertical beam/column of variable density carrying a top mass
Author
Mustafa Turkyilmazoglu
Publication date
01-08-2024
Publisher
Springer Netherlands
Published in
Journal of Engineering Mathematics / Issue 1/2024
Print ISSN: 0022-0833
Electronic ISSN: 1573-2703
DOI
https://doi.org/10.1007/s10665-024-10378-8

Other articles of this Issue 1/2024

A hybrid potential flow model for shedding flow around a circular cylinder

  • Open Access

Lubrication flow in grinding

  • Open Access

Unsteady suspended sediment distribution in an ice-covered channel through fractional advection–diffusion equation

Numerical simulations of shallow-water sloshing coupled to horizontal vessel motion in the presence of a time-dependent porous baffle

  • Open Access

On modeling tear breakup dynamics with a nematic lipid layer

  • Open Access

Magnetohydrodynamic instability of fluid flow in a bidisperse porous medium

Premium Partners

    Image Credits