Jtam-A4.dvi


JOURNAL OF THEORETICAL

AND APPLIED MECHANICS

54, 1, pp. 41-52, Warsaw 2016
DOI: 10.15632/jtam-pl.54.1.41

ANALYTICAL AND EXPERIMENTAL VIBRATION ANALYSIS OF

TELESCOPIC PLATFORMS

Adil Yucel, Alaeddin Arpaci

Istanbul Technical University, Department of Mechanical Engineering, Taksin, Istanbul, Turkey

e-mail: adil.yucel@itu.edu.tr; arpacial@itu.edu.tr

In this study, vibration analysis of a telescopic platform is conducted, and the platform
structure is reconstructed to satisfy vibrational standards. The analysis is realised using so-
lidmodelling, finite elements and an analytical method. The results are verified using expe-
rimental modal techniques. Through the finite element and experimental modal approach
free vibration analysis is carried out and natural frequencies are determined. Additionally,
vibration accelerations of the structure are obtained by forced vibration analysis of themo-
del. All calculations one performed on the new reconstructed structure, and it is determined
whether the reconstructed structure satisfies the vibrational standards.

Keywords: telescopic platforms, modal analysis, Finite ElementMethod, vibration

1. Introduction

Platforms are crane-like machines that lift workers and their equipment to desired heights and
over various distances. The word ’platform’ was only used to describe static structures such
as bridges and ladders until the second half of the twentieth century. However, over the past
30 years, various types of platforms have been specified:

• jointed platforms

• trussed platforms

• load platforms

• telescopic platforms

• vertical platforms

In this study, we examine vibrations of telescopic platforms, which are widely used in con-
struction areas, airports and harbours. Telescopic platforms are structures that have at least
two long beams, with one sliding within the other, called booms. Usually, the second boom
operates through hydraulic cylinders, and the other subsequent booms operate through chains.
An example of a telescopic platformwith five booms is shown in Fig. 1.

A survey of the literature reveals that many studies have been conducted using the finite
elementmethod and three-dimensionalmodelling.Dayawansa et al. (2004) described cracks that
grow in weld joints (called clusters), which protect the booms from catastrophic collapse, and
themaintenance and repair techniques used to keep these joints in service. Karahan (2007) desi-
gned and analysed a two-level telescopic crane using the finite elementmethod. The parts of the
crane were designed in 3D using the Pro ENGINEER software program. The sheet thickness of
themain stationary boomcarrying the loadwas determined byperforming stress analysis in the
ANSYS workbench using the finite element method. Marjamaki and Makinen (2006) extended
the idea of modelling a flexible telescopic boom using a non-linear finite element method in
3D. The boom was assembled using Reissner’s geometrically exact beam elements. The sliding



42 A. Yucel, A. Arpaci

Fig. 1. An example of a five-boom telescopic platform

boom parts were coupled together by the elements where the slide-spring was coupled to the
beamwith the aid of themaster-slave technique. A special element with a revolute joint and an
element with an offset were developed. Telescopic movement was achieved by varying the length
of the element and the connecting chains. Ozkan (2005) analysed connection points of a frame
crane and investigated stress distributions of the connection point components. The commer-
cial finite element package ANSYS was used for finite element analysis. Themain objectives of
the study conducted by Rusiński et al. (2006) were to discuss design problems associated with
machines used in undergroundmining and to investigate the reasons why these problems arise
in the cracked boom of an undergroundminemachine. Numerical and experimental approaches
were pursued. The finite element method was used for numerical simulation. Fractographic and
microscopic evaluation, chemical analysis and hardness tests were used to evaluate the mate-
rials. The objectives were achieved by numerical simulation of a cracked loader boom, material
evaluations of specimens and comparison of the results obtained from both approaches. Nu-
merical simulations were performed based on a discrete model of a jib boom using predefined
boundary conditions. Thefinite element analysis of the jib boomprovided information regarding
stress distribution under extreme load conditions. The study involved macroscopic and fracto-
graphic inspection, microscopic evaluation as well as hardness testing of the materials used for
the jib boom. Erdol (2007) performed static finite element analysis and weight optimisation of
a box girder, which constitutes approximately 50% of the total weight of gantry crane struc-
tures. Trabka (2014) presented ten variants of a computational model for a telescopic boom
crane that differs in the number and selection of flexible components. Modelling and numerical
simulations were conducted using the finite element method. In the study, the compatibility of
the numerical simulation results and test results of a real structure was qualitatively and qu-
antitatively assessed. Time characteristics and frequency characteristics fter application of the
discrete Fourier transformation were also analysed in the study. Posiadała and Cekus (2008)
presented one degree of freedom discrete model representing vibration of the telescopic boom
of a truck crane in the rotary plane. In the model, the influence of the hydraulic cylinder on
the crane radius change was considered. Park andChang (2004) applied time delay control and
commandless input shaping technique, which is a modification-based on the concept of Input
Shaping Technique to increase the productivity of the boom of the telescopic handler. Lastly,
Sochacki (2007), considered the dynamic stability of a laboratory model of the truck crane. In
the study, the results in form of frequency curves for changing the geometry of the systemwere
presented. In this study, vibrational analyses of telescopic platforms are conducted, and these
structures are optimised to satisfy vibrational standards.



Analytical and experimental vibration analysis of telescopic platforms 43

2. Models

In this study, a telescopic platformwithfiveboomsandamaximumoperating height of 24mhas
been selected formodelling. The booms aremodelled in two different cross-sections: rectangular
and annular. The telescopic platform which is was constructed using annular cross sectional
booms, is named the ’reconstructed structure’ in the study.All of the components of theplatform
are modelled using the Pro/ENGINEER software. The model consists of the following main
parts: foundation, tower, booms, basket joint and basket. The first part that is modelled is
the foundation. The foundation is based on a 4920× 2100mm area, and profiles with cross-
-sections measuring 80× 160× 6mm are used for modelling where 80mm represents height,
160mm represents width and 6mm represents thickness of the thin-walled rectangular section.
The tower ismounted on the foundationusing a groupof gears located in the reduction gear box.
The next part that is modelled is called the tower. The base flange of the tower has thickness
of 20mm. It consists of 16×∅17 mmholes that are used tomount the gear box. The tower can
rotate 360◦ around its axis, but its operation angle is limited to 180◦. The piston that connects
the first boom to the tower is also modelled. The properties of the five booms modelled in this
study are presented inTables 1 and 2 for the rectangular and annular cross-section, respectively.
The solid models for the booms with rectangular and annular cross-sections are also presented
in Figs. 2 and 3, respectively.

Table 1.Dimensions of the booms with thin-walled rectangular cross-sections

Boom No. Length ℓi [mm] Cross-section [mm]

1 4580 292×510×8

2 3600 250×422×6

3 3600 210×340×5

4 3600 170×260×5

5 3600 132×202×5

Table 2.Dimensions of the booms with thin-walled annular cross-sections

Boom No. Length ℓi [mm] Cross-section [mm]

1 4580 ∅340×12

2 3600 ∅280×12

3 3600 ∅232×10

4 3600 ∅184×8

5 3600 ∅132×8

Fig. 2. A boomwith a rectangular cross-section



44 A. Yucel, A. Arpaci

Fig. 3. A boomwith an annular cross-section

One of the most important components of the model is the basket joint. The basket joint
is the vital part that connects the last boom to the basket in which the worker operates. The
last component of the model is the basket in which the work operates. The basket is modelled
using ∅30×2.5mm round profiles. It has base area of 900×1500mm and height of 1120mm.
The assemblies are constructed both for rectangular and annular section booms.

3. Finite element analysis for full assemblies

After the assembled 3D solidmodel of the telescopic platform is obtained, it is imported into the
commercial finite element analysis software programABAQUS for natural frequency andmode
shape analysis. The approximate mesh size of the finite element model is 100mm. Themeshed
finite element model is shown in Fig. 4. Linear tetrahedral solid elements are used in the mesh
and thematerial properties are taken as follows:

• density: 7850kg/m3

• Poisson’s ratio: 0.3

• modulus of elasticity: 210000MPa

Fig. 4. Finite element model

The first 10 natural frequencies are presented in Table 3. In Table 3, ’ip’ and ’op’ stand for
the in-plane (XZ plane) and out-of-plane (XY plane) mode shapes, respectively.
The source of the excitation is mainly the engine, and the origin of the excitation has been

accepted as the foundation; therefore, we conducted the forced vibration finite element analysis
by applying the force to the foundation of the platform. The operating (excitation) frequency of
the system is 12.875Hz. This is the frequency of the system when the engine runs idle and the



Analytical and experimental vibration analysis of telescopic platforms 45

Table 3.Natural frequencies

Mode Natural frequency [Hz] Natural frequency [Hz] Mode
No. (rectangular section) (annular section) shape

1 0.2987 0.2515 ip

2 0.4196 0.2668 op

3 1.1249 1.0035 ip

4 1.6382 1.0812 op

5 4.9468 4.1055 ip

6 7.1794 4.4389 op

7 12.125 10.105 ip

8 16.929 10.988 op

9 21.803 18.631 ip

10 31.183 19.926 op

workers are working in the basket. As shown in Table 3, the natural frequency is f =12.125Hz,
which is very close to the operating frequency of the system. This indicates a risk of resonance
under operating conditions. Therefore, the model has been reconstructed. After reconstruction
(annular boom profile), it has been clearly revealed that there is no natural frequency close to
the operating frequency of the system, which validates the reconstruction.

4. Analytical solution for the five-boom model

For flexural modes, the boom is modelled as shown in Fig. 5.

Fig. 5. Analytical model of the boom for flexural modes

Let thedeflection in the y directionbeν(z,t).The equation of vibration for thebeamelement
is given as

EI
∂4ν

∂z4
+µ
∂2ν

∂t2
=0 (4.1)

where µ is mass per unit length, ρ is mass density, A is cross-sectional area, t is time and
EI represents the flexural stiffness. As known

µ= ρA (4.2)

and

ν(z,t) =φ(z)sin(ωt) (4.3)

for harmonic motion. Substituting Eq. (4.3) into Eq. (4.1) gives

∂4φ

∂z4
−
µω2

EI
φ=0 (4.4)

The solution is

φ(z) =Acosh
λz

ℓ
+B sinh

λz

ℓ
+C cos

λz

ℓ
+Dsin

λz

ℓ
(4.5)



46 A. Yucel, A. Arpaci

whereA,B,C andD are the integration constants and

λ= ℓ
4

√

µω2

EI
(4.6)

For a five-boom structure, the equations are arranged as below. The model of the booms of a
telescopic platformwith a pointmass at the free end is shown in Fig. 6, whereM is mass of the
point mass, and J is mass moment of inertia of the point mass with respect to the x-axis for
in-plane and the y-axis for out-of-plane analysis

φi(z)=Aicosh
λiz

ℓi
+Bi sinh

λiz

ℓi
+Cicos

λiz

ℓi
+Di sin

λiz

ℓi
i=1,2,3,4,5 (4.7)

Fig. 6. Analytical model of the five-boom structure for flexural modes

Geometric boundary conditions are

φ1(0)= 0
dφ1

dz
(0)= 0 (4.8)

Transition boundary conditions are (i=1,2,3,4)

φi(ℓi)=φi+1(0)
dφi

dz
(ℓi)=

dφi+1

dz
(0)

EIi
d2φi

dz2
(ℓi)=EIi+1

d2φi+1

dz2
(0) EIi

d3φi

dz3
(ℓi)=EIi+1

d3φi+1

dz3
(0)

(4.9)

Natural boundary conditions are

EI5
d2φ5

dz2
(ℓ5)−ω

2J
dφ5

dz
(ℓ5)= 0 EI5

d3φ5

dz3
(ℓ5)+ω

2Mφ5(ℓ5)= 0 (4.10)

For torsional modes, the boom is modelled as shown in Fig. 7.

Fig. 7. Analytical model of the boom for torsional modes

Let the twist angle about the z-axis be ϕ(z,t). The equation of vibration for the beam
element is given as

ϕ=ϕ(z,t) GC
∂2ϕ

∂z2
= ρIp

∂2ϕ

∂t2
(4.11)

where GC is the torsional stiffness related to Saint-Venant’s principle. For harmonic motion,
substituting Eq. (4.12)1 into Eq. (4.11)2 gives Eq. (4.12)2

ϕ= θ(z)sin(ωt) c2
∂2θ

∂z2
+ω2θ=0 (4.12)



Analytical and experimental vibration analysis of telescopic platforms 47

where

c2 =
GC

Ip
(4.13)

The solution is

θ(z)=Asin
ωz

c
+Bcos

ωz

c
(4.14)

whereA andB are the integration constants. For the booms of the telescopic platform

θi(zi)=Ai sin
ωzi

ci
+Bicos

ωzi

ci
c2i =

GCi

ρ(Ip)i
i=1,2,3,4,5 (4.15)

Geometric boundary conditions are

θ1(0)= 0 θi(ℓi)= θi+1(0) i=1,2,3,4 (4.16)

Transition boundary conditions are

GCi
dθi

dz
(ℓi)=GCi+1

dθi+1

dz
(0) i=1,2,3,4 GC5

dθ5

dz
(ℓ5)=0 (4.17)

The results of the finite element analysis and analytical solutions for both rectangular and
annular cross-sectional five-boom systems are given inTables 4-7. InTable 4, ’ip’ and ’op’ stand
for the in-plane and out-of-plane mode shapes, respectively. The value of the point mass is
200kg, which is the sum of masses of the basket and the worker. The discrepancies in Tables
have been calculated according to the formula given below

Dis. [%]=
Analytical−FEA

Analytical
·100

Table 4. Flexural natural frequencies for rectangular cross-sections

Rectangular section Rectangular section Rectangular
Mode
shape

(five-boom without (five-boomwith section
point mass) point mass) (full assembly)

FEA Analytical Dis. [%] FEA Analytical Dis. [%] FEA

0.3045 0.3134 2.84 0.2987 ip

0.4286 0.4425 3.14 0.4196 op

1.3610 1.4180 4.02 1.1529 1.1924 3.31 1.1249 op

2.0196 2.1049 4.05 1.6864 1.7486 3.56 1.6382 op

5.1049 5.3411 4.42 5.1198 5.3358 4.05 4.9468 op

7.4014 7.7389 4.36 7.4375 7.7484 4.01 7.1794 op

12.027 12.649 4.92 12.291 12.884 4.60 12.125 op

17.324 18.258 5.12 17.714 18.629 4.91 16.929 op

22.285 23.643 5.74 22.862 24.182 5.46 21.803 op

31.995 34.076 6.11 32.811 34.881 5.93 31.183 op



48 A. Yucel, A. Arpaci

Table 5. Flexural natural frequencies for annular cross-sections

Annular section Annular cross-section Annular
(five-boom without (five-boomwith cross-section
point mass) point mass) (full assembly)

FEA Analytical Dis. [%] FEA Analytical Dis. [%] FEA

0.2549 0.2691 5.28 0.2515

1.2790 1.3410 4.62 1.0224 1.0745 4.85 1.0035

4.4066 4.6309 4.84 4.2253 4.4469 4.98 4.1055

10.366 11.010 5.85 10.425 11.134 6.37 10.105

19.119 20.419 6.37 19.339 20.875 7.36 18.631

31.444 33.434 5.95 31.584 33.926 6.90 30.105

48.990 52.014 5.81 48.927 52.673 7.11 46.439

65.911 70.520 6.54 65.163 71.154 8.42 61.458

Table 6.Torsional natural frequencies for rectangular cross-sections

Rectangular Rectangular
cross-section cross-section

(five-boommodel) (full assembly)

FEA Analytical Dis. [%] FEA

61.67 63.71 3.20 60.5784

110.96 112.10 1.02 105.988

167.98 169.81 1.08 156.036

214.76 230.28 6.74 190.169

Table 7.Torsional natural frequencies for annular cross-sections

Annular section Annular section
(five-boommodel) (full assembly)

FEA Analytical Dis. [%] FEA

76.44 79.47 3.81 74.7758

135.92 140.40 3.19 129.100

204.09 210.30 2.95 186.386

273.28 282.68 3.33 233.853

5. Experimental modal analysis

To conduct forced vibration analysis using the finite element method, we need to determine
the excitation force of the system. Due to the restrictions regarding the construction of the
telescopic platform, it is impossible to locate a force transducer to measure the excitation force
of the system. Instead, we measure the acceleration values of the foundation and basket. Then,
we conduct a series of forced vibration analyses using the finite elementmethod to satisfy these
acceleration valuesmeasuredat certain points using sensors on theplatform.Thus,weobtain the
excitation force value required to further reconstruct the structure. The positions of the sensors
on the systemare shown inFig. 8.AB&K4524B triaxial CCLDpiezoelectric accelerometer with
frequency range of 0.25-3000Hz and sensitivity of 100mV/g has been used in the experiments.
FFT analyses are conducted for 0-100Hz (800 lines – 0.125Hz resolution) with sampling rate of
256Hz (256 samples per second).

The first triaxial accelerometer is located on the connection part between the foundation
and the tower so we obtain the acceleration data for the foundation to create the simulation



Analytical and experimental vibration analysis of telescopic platforms 49

Fig. 8. Locations of the sensors on the foundation and basket

of forced vibration analysis. Secondly, another triaxial accelerometer is located on the floor of
the basket to obtain the acceleration data for the basket in order to use in the forced vibration
simulation.Thesedataobtainedby themeasurementson the foundationandbasket are thenused
as reference values in the forced vibration analysis, and a series of forced vibration simulations
are carried out to satisfy these reference values. The correct excitation force value is detected
when we reach the same values on the foundation and basket as the reference values. This
excitation force value which is obtained from forced vibration simulations is then used in the
forced vibration simulation of the reconstructed platform model (annular boom profile). Thus,
bothmodels have been excited by the same and correct excitation force for the forced vibration
simulations.

The results of spectral analyses of the acceleration data obtained by the sensors on the
foundation and basket are shown in Figs. 9 and 10.

Fig. 9. Spectral analysis of foundation vibration of the telescopic platform: (a)X direction,
(b) Y direction, (c)Z direction



50 A. Yucel, A. Arpaci

Fig. 10. Spectral analysis of basket vibration of the telescopic platform: (a)X direction,
(b) Y direction, (c)Z direction

The main units written at the top of the axes in Fig. 9 and Fig. 10 are m/s2. 2m means
2mm/s2 wherem stands formm. 500u means 500µm/s2 where u stands for µm.

Using the results of spectral analysis, the acceleration values at the operating frequencyhave
been determined. They are presented in Table 8.

Table 8.Experimentally obtained acceleration values at the operating frequency

Direction
Foundation Basket
]mm/s2] [mm/s2]

X 5.004 9.173

Y 24.455 5.494

Z 2.203 19.532

Having realised the forced vibration analysis using the finite element method to satisfy the
acceleration values, the distributed excitation force is determined to be 8.52 · 10−6 ton/mm2

(0.0836MPa). This force has been used to analyse both assemblymodels (with rectangular and
annular boom profiles).

6. Conclusions

In this study, vibrational analysis of a telescopic platformhasbeen conducted.This structurehas
been reconstructed to satisfy vibrational standards (applying to the industrial safety regulations)
and shift resonance frequencies. The vibrational analyses are conducted using solid modelling,
finite elements and an analytical method. The results of the analysis are also verified using the
experimental modal technique.



Analytical and experimental vibration analysis of telescopic platforms 51

The operating (excitation) frequency of the system is 12.875Hz. The table of natural frequ-
encies of the original model indicates that there is a natural frequency value of 12.125Hz that
is very close to the operating frequency of the system. This reveals a risk of resonance under
operating conditions. After reconstruction, it has been clearly revealed that there is no natural
frequency close to the operating frequency of the system, which validates the reconstruction.

Although it is impossible to locate a force transducer on the system and to measure the
acting force, the distributed force has been determined to be 8.52 ·10−6 ton/mm2 (0.0836MPa)
usingexperimentalmodal analysis by taking theacceleration values obtained experimentally into
account. We measured the accelerations in different points of the system and then conducted
a series of forced vibration finite element analyses with different force values until we achieved
the acceleration values obtained by the experiments. This force value can be used in anymodal
analysis of this model.

By examining the related standard, it has been observed that the acceleration values on the
basket are very high for workers. After the reconstruction, we observed a significant reduction
in the acceleration values. The acceleration values on the basket before and after reconstruction
are presented in Table 9. According to the related standard (ISO 2631), which defines the
maximum allowed acceleration values for a worker, the acceleration values on the basket after
reconstruction stay considerably under the limits for the operating frequency.

Table 9.Comparison of acceleration values on the basket

Direction
Rectangular cross-cection Annular cross-section
(original) [mm/s2] (reconstructed) [mm/s2]

X 9.597 1.358

Y 5.709 1.267

Z 20.636 3.528

Tables 4-7 indicate thatfive-boomanalyticalmodels canbeaccepted insteadof full assemblies
because parts other than the booms have little effect on the frequencies. Therefore, we can agree
that the telescopic platformcanbe taken as a connection of beamswithvarying cross-sections for
frequency calculations. The results also show that the point mass, which replaces themasses of
thebasket andworkers in theanalyticalmodel, causes very little differenceonnatural frequencies
but only changes the mode shapes. The point mass has no effect on torsional modes.

Acknowledgments

We want to thank Ms. Elif Naz Aladag and Mr. Mehmet Ozaltinoglu for their supports in the

preparation of solid models and analyses files.

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52 A. Yucel, A. Arpaci

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Manuscript received July 16, 2014; accepted for print June 20, 2015