International Journal of Engineering Materials and Manufacture (2018) 3(4) 200-207 
https://doi.org/10.26776/ijemm.03.04.2018.04 

 
M. Murthy , K. M. Babu and P. M. Jebaraj 
Department of Mechanical Engineering 
B.M.S. College of Engineering 
Bull Temple Road, Bengaluru 
Karnataka, India-560019 
 

E-mail: madhavmurthy.mech@bmsce.ac.in 
 

Reference: Murthy, M., Babu, K. M. and Jebaraj, P. M. (2018). Impact of Constraint Conditions and Cutouts on Natural Frequency 
of Glass Fibre Reinforced Plastic Composite. International Journal of Engineering Materials and Manufacture, 3(4), 200-207. 

 
 

Impact of Constraint Conditions and Cutouts on Natural Frequency of Glass 
Fibre Reinforced Plastic Composite 
 
 
Madhav Murthy, Kayala Mallikharjuna Babu and Peter Martin Jebaraj 
 

 

Received: 12 September 2018 
Accepted: 03 November 2018 
Published: 01 December 2018 
Publisher: Deer Hill Publications 
© 2018 The Author(s) 
Creative Commons: CC BY 4.0 

 
 
ABSTRACT 
Majority of the activities of a human being is associated with vibrations of one or other form. Application of 
vibrations can be found from a simple example like listening to music to challenging ones like design of complex 
machines and structures. Design of any system will not be rugged if it does not consider vibrations and its effects. The 
energy dissipated per cycle can be understood as damping. Presence of damping in a structure is represented by 
damping factor or damping ratio. Fibre reinforced plastic composites are a class of materials made from matrix and 
reinforcement. Matrix can be a resin system and reinforcement is usually fabric made of glass, carbon or aramid. The 
vibrating mechanical system causes resonance resulting in failure of machine components. By knowing the natural 
frequency and changing it from the range of operating machine member, resonance phenomenon could be avoided. 
This work focuses on finding the damping ratio and natural frequency of s glass fibre reinforced polymer composites 
through harmonic & modal analysis both by experimental method and FEM analysis for bare plate, plate with 
rectangular cutouts and plate with circular hole. The reduction in natural frequency and increase in damping 
corresponds to a change in stiffness and damping of the system. These changes are attributed to freeness of the system 
and introduction of cutouts in the laminate. 
 
Keywords: Vibrations, Damping factor, glass fibre reinforced composites, natural frequency 
 
 
1 INTRODUCTION 
Man became interested in vibration when he created the musical instruments like drums, whistles and other musical 
instruments. Since then, philosophers and musicians came up with the understanding of sound and sounds, which 
were used in creation of various musical instruments and were passed from generation to generation [1]. The motion 
that repeats itself after an interval of time can be called oscillation or vibration. The swinging of a simple pendulum, 
motion of a tuning fork and the spring balance are typical examples of vibration. Many a human activities involve 
sound and vibration in one or the other form. The theory of vibration deals with the study of oscillatory motion of 
bodies and forces associated with them. Vibration can be desirable or undesirable. Sound and vibration studies are 
interrelated. The types of vibration are free, forced, damped and undammed. 
 
1.1 Loss Factor 
When a structure is excited, the vibrations in the structure do not last forever and it therefore dampens out. The 
ability of structures, which dissipates vibrational energy, is an important parameter of a system called damping which 
is quantified as damping ratio (ζ) or loss factor (η) [2].Damping can be understood as the energy dissipated per cycle. 
When there is a presence of damping in a structure, it is generally represented by damping factor or damping ratio 
and when it is defined for a specific mode, it is known as modal damping factor. 

A structure can have many natural frequencies. For a design to be reliable, estimation of damping becomes 
important. Loss factor estimation is straightforward unlike other parameters like stiffness and mass. It is often 
evaluated during experimentation. Inconsideration of loss factor may not lead to a sound design. Hence, a suitable 
damping is to be provided for increasing the weight, whereas overestimation of loss factor may lead to unwanted 



Impact of Constraint Conditions and Cutouts on Natural Frequency of Glass Fibre Reinforced Plastic Composite 

201 

vibrations and sometimes breakdown of the structure prior to the designed life. Some of the common issues associated 
with loss factor estimation are to understand the limits and requirements in each method of loss factor estimation. It 
is crucial, as there is no single method suited for all situations [3]. Most techniques do not accurately estimate high 
loss factors, mostly because of insufficient/incorrectness of data provided. While taking measurements, the positioning 
of excitation point and sensors is vital since multiple input-output locations of the structure are involved. A structure 
should never be excited at a node line as this may cause rigid body response. It is also important not to measure 
response from any point on node line [4, 5]. For simulating a continuous system efficiently and removing spatial 
effect from measurements, long sets of time history of responses needs to be recorded and analysed from multiple 
locations, which best be randomly chosen. In cases where multiple input and output locations are involved, slope 
fitting can prove to be another challenge. When a great number of slope fits are required to be performed, human 
error is unavoidable which may lead to inaccuracy of results. Therefore, an automated slope fitting algorithm is 
recommended. To avoid any probable biased error, visual inspection helps to understand the decay curves for all 
slope fits [6]. 
 
1.2 Half Power Bandwidth Method 
It is a frequency domain method used for estimation of loss factor. The estimation of loss factor is carried out using 
frequency response functions. The expression of damping factor is given by ζ= (ωn2- ωn1)/2 ωn where ωn is the natural 
frequency, ωn2, ωn1 are half power points and the difference of these is called the bandwidth. The objective of this 
work is to estimate the damping factor of glass fibre reinforced composite plates (laminates) with no cutouts, circular 
cutouts and rectangular cutouts and varying boundary conditions [7, 8]. The boundary conditions considered in this 
work are clamped-clamped-clamped-clamped (CCCC), clamped-clamped-clamped-fixed (CCCF) and clamped-fixed 
-clamped-fixed (CFCF). The laminates were fabricated using resin transfer moulding (RTM) method. The matrix was 
the combination of resin and hardener in the ratio of 1:10. The matrix and reinforcement used in this study are Epoxy 
LY556 with HY951 as hardener and bidirectional S glass fibre as the reinforcement. The laminate was cured at room 
temperature. The machining of the laminates was carried out in abrasive water jet machining centre [9, 10]. 

The validation of experimental and FEA values of damping factor and natural frequency results were carried out. 
Fast Fourier transforms (FFT’s) were obtained from the experimental studies. The boundary conditions used for 
experiments to determine natural frequencies and FEA were the same. There was a variation between the FEA and 
experimental results (analytical vs experimental) which could be due to the mesh quality, section of the element and 
accuracy of boundary conditions, which should imitate the experimentation condition for validation of FEA results. 
All the plates used for experimentation are fabricated using S glass fibres with the epoxy resin LY556 and the hardener 
HY951. The composite laminate was fabricated by resin transfer moulding process. The plate dimensions were chosen 
as 420mm x 210mm x 2mm for the final laminate size. The numbers of layers of reinforcements used are 8 in addition 
to resin contributing to the rest of thickness and resin-hardener in the ratio of 1:10. The workpiece and experimental 
setup is shown in Figure 1 and Figure 2 respectively. Figure 1a, 1b & 1c indicates the laminates fabricated and machined 
to the dimensions and 1b -1c have rectangular and circular cutouts for testing the damping and six modes of frequency. 
 
2 METHODOLOGY 
2.1 Experimental Procedure 
The measurement of vibration characteristics depends on various factors such as position of exciter to excite the 
structure, placement of an accelerometer, and clamping of the plate etc. The brief procedure for the experimentation 
is as follows. 

The Plate is clamped firmly after the dimensions are measured for all the configurations (CCCC, CCCF & CFCF) 
and Smearing of wax on the uniaxial accelerometer is carried out before placing the accelerometer on the vibrating 
structure. The structure is then excited by sine sweep method. Then the response of structure is recorded using data 
acquisition system and compatible software. 
 

   
a b c 

Figure 1:Tthe workpiece (a) bare plate, (b) late with rectangular cutout, and (c) plate with circular cutout 
After the data acquired it is exported to an FFT analyser and read in frequency domain, which shows amplitude 
response corresponding to frequency. The amplitude response is as shown in Figure 3 in Hertz. Natural frequencies 
at various frequencies and intervals of time can be seen in Figure 3. 
  



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202 

2.2 Validation using FEM Approach 
The finite element analysis for the orthotropic laminates prepared with the above-mentioned boundary 
configurations is carried out. Frequency response curves obtained experimentally and through ANSYS is shown in the 
Figure 4. Quality factor is calculated for all the configurations using Half Bandwidth technique. In experimental 
method, frequency response curves are plotted as frequency v/s amplitude. The amplitude obtained experimentally 
is shown in terms of volts, larger the volts larger is the amplitude. The plate (laminate) response is taken from the 
analyser and the accelerometer sends the signals to the analyser in the form of volts as can be seen in figure 4. Voltage 
is a direct measure of amplitude. In Finite Element Analysis, the frequency response curve, magnitude of the amplitude 
can be obtained. Highest peak in experimental frequency responses via FFT and FE frequency response curves from 
ANSYS corresponds to the natural frequency of the structure 

The S Glass FRP laminates are used for the vibration analysis. With the fibre and resin composition of 60- 40% 
respectively. The plates are subjected to loads such as fatigue, point loads, bending etc. so the plate should have the 
capability to resist such loads. The Table 1 shows the physical properties of the reinforcement. Modulus, density and 
thickness are important parameters for carrying out simulation and experimental studies, which are given in Table 1. 
 
 
 

 
 

Figure 2: Experimental setup with the fixtures 
 
 
 

 
Figure 3: Amplitude response of bare plate with CCCC configuration (Hz) 

 
  



Impact of Constraint Conditions and Cutouts on Natural Frequency of Glass Fibre Reinforced Plastic Composite 

203 

2.3 Boundary conditions 
The orthotropic laminate is studied for different boundary conditions. The clamping is made on the edges of the 
plate. These three boundary conditions are shown in Figure 5. The various boundary conditions studied are CCCC 
(all ends clamped) for a bare plate (i.e., without any cut out), a plate with circular hole or cutout and a plate with 
rectangular cutout for carrying out further analysis as can be seen in figure 5. The finite element method analysis is 
considered and obtained for six mode shapes. In this article only the first mode shapes are discussed as shown in 
Figure 6, Figure 7 and Figure 8. Once the meshing is done and the constraints are defined the next step is to carry 
out the modal as well as harmonic analysis for the orthotropic plates by providing the inputs of the frequency and 
the obtained results is as shown in Figures 6-8. In Figure 6, Figure 7 and Figure 8 nodal solutions are obtained and 
further analysed. 
 
 

 
 

Figure 4: Plate with circular hole (CCCF condition)  
 

Table 1: Properties of S Glass Bidirectional fabric 
 

Properties Values 

E1 85GPa 
E2 3.5GPa 
E3 3.5GPa 
ν12 0.2 
ν 23 0.2 
ν31  0.35 
G12 36GPa 
G23 36GPa 
G31 36GPa 
Density 1822kg/m3 
Fabric thickness 0.25mm 

 
 

   
a b c 

 

Figure 5: CCCC boundary configuration of (a) bare plate, (b) plate with circular hole and (c) plate with rectangular 
cutout. 



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Figure 6: Plate with circular hole CFCF condition 
 
 
 
 

 
 

Figure 7: Plate with circular hole CCCF condition 
  



Impact of Constraint Conditions and Cutouts on Natural Frequency of Glass Fibre Reinforced Plastic Composite 

205 

 
 

Figure 8: Plate with circular hole CCCC condition 
 
 
3 RESULTS AND DISCUSSIONS 
Experimentation and validation: 
The laminates prepared were subjected to dynamic analysis and the natural frequencies were found out. The same 
are presented for first three modes. Finite element analysis for the various laminates of different boundary conditions 
was carried out and is as shown in Table 2. From Table 2 one can infer the various frequency values which helps in 
designing of structures and also for damping studies 

The bare plate shows reduced natural frequency when the laminate is under CFCF condition as compared to 
CCCC condition in 1st mode, which reveals that freeness in the system reduces the natural frequency of the system. 
The result holds good for remaining two modes. These results are in agreement with results from FEM approach. It 
can also be seen that there is a substantial increase in natural frequency of laminates with cutouts as compared to that 
of bare plate. However, there is a little variation in natural frequency among circular and rectangular cutouts. The 
calculated values of damping for various boundary conditions are as shown in Table 3. It can be seen clearly from 
the graphs as in Figure 9 that composite plates with rectangular cutouts have a higher damping followed by composite 
plate with circular hole. It can also be seen from Figure 9 that composite bare plate has got least damping as compared 
to plate with cutouts. 
 
 
 

Table 2: Comparison of natural frequencies from experiment and FEM method 
 

Plates Boundary 
Condition 

1st Mode 2nd Mode 3rd Mode 
Frequency (Hz) Frequency (Hz) Frequency (Hz) 

  FEM EXP FEM EXP FEM EXP 
Bare Plate CCCC 293 310 438 615 664 730 
 CCCF 251 250 334 490 490 730 
 CFCF 240 225 276 460 375 700 
Plate with Circular Hole CCCC 405 390 468 440 755 730 
 CCCF 324 315 427 410 517 490 
 CFCF 320 315 331 350 470 490 
Plate with Rectangular cutout CCCC 402 260 460 520 750 760 
 CCCF 323 200 421 420 510 625 
 CFCF 318 200 329 380 467 620 

 
  



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Table 3: Damping Ratio from Experiment  
 

Plate Boundary condition 

CCCC CCCF CFCF 

Bare Plate 0.012 0.016 0.025 
Plate with circular hole 0.015 0.020 0.032 
Plate with rectangular cutout 0.019 0.025 0.05 

 
 
 

 
 

Figure 9: Comparison of damping factor of various composite laminates  
 
 
It can be seen from the Figure 9 that there is an increase in damping when the configuration changes from CCCC to 
CFCF for plates with different geometries. The plate constrained in all directions has less damping compared to that 
of plate, which is constrained in two directions. It can also be observed that the plate with cutout have higher 
damping compared to bare plate. When geometry of the cutout is considered, there is an increase in damping in 
rectangular cutout followed by circular cutout and bare plate. The damping could be increased with increased size 
of cut out. 
 
4 CONCLUSIONS 
The structural glass fibre reinforced plastic laminates have shown that freeness in the system reduced the natural 
frequency of the system for bare plate and plates with cutout in all the three modes. If it is intended to increase the 
natural frequency, one can make cutout in the laminate. It is also seen that the type of cutout whether circular or 
rectangular has a little impact on natural frequency. Damping is highest in plate with rectangular cutout as compared 
to plate with circular hole and bare plate for all the types of configuration. It is evident that the damping is less in 
CCCC configuration for all the three types of plates and increases with increase in freeness of the system as in CFCF 
configuration. Damping contributes in attenuation of structural vibration mainly at natural frequencies. The freeness 
in the system reduces. 
 
Scope for Future work 
Laminates can be fabricated using other types of reinforcements and hybrid composites could as well be produced 
and the same analysis can be carried out on those laminates. Various resin systems can be used to fabricate the 
polymer composites such as polyester, polyether ether ketone etc. 
 
Acknowledgment 
This research was funded by T.E.Q.I.P-II. The authors are grateful to those who contributed directly and indirectly in 
producing this paper.  
  



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