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Modal and harmonic analysis of tapered composite i

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SRINIVASULU N V
SRINIVASULU N V

MODAL ANALYSIS OF TAPERED COMPOSITE BEAMS

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Modal And Harmonic Analysis Of Tapered Composite I- Beam With Big End Fixed Dr. N.V.Srinivasulu1, Dr.V.Veeranna2, S.Jaikrishna3 1.Associate Professor, Department of Mechanical Engineering, CBIT, Hyderabad- 500075.AP.India. Mail: vaastusrinivas@gmail.com 2. Professor, Department of Technology, Brindavan Institute of Tech and Science,Kurnool. 3. Sr.Assistant Professor,Deprtment of Mech. Engg., MJCET, Hyderabad. Abstract In this paper the tapered thin walled glass epoxy composite I-beam is taken with its big end fixed and small end is kept free. For harmonic analysis 1.0 N load is applied at free end of the cantilever beam and. the results obtained are presented in graphical form with displacement Vs natural frequency and results are presented in graphical form for various cases. Introduction: In the present study a thin-walled composite beam with I-section and length L = 8 m is considered in order to investigate the effects of various parameters namely fibre orientation, modulus ratio, height-to-thickness ratio and boundary conditions on the natural frequencies and mode shapes. The geometry of the I-section is shown in Fig. 1. Fig.1. Thin-walled composite I-beam. 1
Modal Analysis A composite cantilever I-beam is modelled with element shell99 and the material and modal analysis is carried out by fixing the bigger end and kept smaller end free. The effect of fibre angle rotation in top and bottom flanges, elastic modulii and height to thickness ratio on natural frequencies and mode shapes are discussed below. Effect of fibre angle rotation in top and bottom Flanges The top and bottom flanges are considered as angle-ply laminates [θ/ -θ], and the web laminate is assumed to be unidirectional. In this case, the lowest four natural frequencies by the finite element analysis exactly correspond to the first flexural mode in the x-direction, flexural mode in the y-direction, second flexural mode in the x-direction, and torsional mode by the orthotropic closed-form solution, respectively. It is clear that from fig.10.1, the natural frequencies are increasing with increase in fibre angle rotation. Very small variation in the natural frequencies for first three modes is observed from 00 and up to fibre angle 450. 10 9 ω1 Natural frequency,Hzs 8 ω2 7 ω3 6 ω4 5 4 3 2 1 0 0 15 30 45 60 75 90 Fiber angle, in degrees Fig 2. Variation of the non-dimensional natural frequencies of a tapered cantilever composite beam with big end fixed with respect to fibre angle change in flanges Mode shapes The mode shapes corresponding to the first four lowest modes with unidirectional fibre in web and fibre angle 45° in the top and bottom flanges are illustrated in fig.3. 2
(a).Mode 1 (b). Mode 2 (a).Mode 3 (b). Mode 4 Fig.3. Mode shapes of the tapered composite beam with fibre angle 45 0 in top and bottom flanges Effect of fibre angle rotation in web In this case the natural frequencies for first mode are constant for all fibre angles as shown in fig.4 For second, third and fourth modes frequency is constant from fibre angle 0- 450 and a small increment in each mode is observed . Effect of modular ratio The effects of modulus ratio ( E1 /E2) of composite beams on the natural frequencies and mode shapes for Tapered Cantilever composite beam is shown below. The stacking sequence of the top and bottom flanges are [0/90]s, and web is unidirectional. It is observed that the natural frequencies increase with increasing orthotropy ( E1 /E2). 3
5 4.5 Natural frequency, Hzs 4 3.5 3 ω1 ω2 2.5 ω3 2 ω4 1.5 1 0.5 0 0 15 30 45 60 75 90 Fiber angle, in degrees Fig.4. Variation of the non-dimensional natural frequencies of a Tapered cantilever composite beam with big end fixed with respect to fibre angle change in web. 16 ω1 14 ω2 Natural frequency, Hzs 12 ω3 ω4 10 8 6 4 2 0 0 10 20 30 40 Elastic modulus ratio Fig. 4. Variation of the non-dimensional natural frequencies of a Taper cantilever composite beam with big end fixed with respect to modulus ratio. 4
Harmonic analysis The harmonic analysis is carried out for a tapered cantilever composite I-beam and load of 1.0 N is applied at free end. The study is carried out by varying fibre angle rotation in top and bottom flanges of I- beam and elastic modular ratio and results are obtained and represented in the graphical form as Frequency Vs. Displacement. 3.00E-04 0 2.50E-04 15 2.00E-04 30 Displacement, in meters 45 1.50E-04 60 1.00E-04 75 90 5.00E-05 0.00E+00 -5.00E-05 -1.00E-04 -1.50E-04 -2.00E-04 0 5 10 15 20 25 Natural frequency, Hzs Fig5. Frequency vs. Displacement for fibre angle rotation in two flanges 3.00E-04 2.50E-04 0 15 Displacement, in meters 2.00E-04 30 1.50E-04 45 60 1.00E-04 75 5.00E-05 90 0.00E+00 -5.00E-05 -1.00E-04 -1.50E-04 -2.00E-04 0 5 10 15 20 25 Natural frequency,Hzs Fig.6. Frequency vs. Displacement for fibre angle rotation in web Effect of fibre angle rotation in top and bottom Flanges From the fig.5, it is clear that as the frequency increases, the value of the amplitude of vibration for a cantilever composite beam follows sinusoidal curve, for all fibre angles. For fibre angle 450, the value of amplitude of vibration is high at frequency of 5 Hz . 5
Effect of fibre angle rotation in web From the fig.10.6, it is seen that as the frequency increases, the value of the amplitude of vibration for a cantilever composite beam follows sinusoidal curve, for all fibre angles same as above case. Effect of modular ratio: From the fig.7, it is evident that there is a small variation in amplitude of vibration for all modular ratios except for modular ratio of 40. For modular ratio of 40, the minimum displacement is at frequency of 20 Hz. 4.00E-04 E1/E2=1 3.00E-04 E1/E2=10 E1/E2=20 Displacement, in meters 2.00E-04 E1/E2=30 1.00E-04 E1/E2=40 0.00E+00 -1.00E-04 -2.00E-04 -3.00E-04 -4.00E-04 0 5 10 15 20 25 Natural frequency, Hzs Fig.7. Frequency vs. Amplitude for various modular ratios. 6
Modal and Harmonic Analysis of Composite I-beam with three circular holes in web Dr. N.V.Srinivasulu, Associate Professor, Department of Mechanical Engineering, CBIT, Hyderabad-500075.AP.India. Mail: vaastusrinivas@gmail.com Abstract In this paper, uniform composite thin walled I- beam is considered and three circular holes are made in the web at 2m apart with holes diameter of 32 mm as shown in fig.1. The beam is modeled using ANSYS with the same material properties mentioned in the chapter 8. Modal and harmonic analysis is done for a cantilever boundary condition. Harmonic analysis is carried out by applying a load of 1.0 N at free end and nodal results at free end are obtained in the form of amplitude Vs natural frequency graphs for various fibre angle rotations and modular ratios. The Finite element model of a uniform doubly symmetric composite I-beam with holes in web is shown in fig.1. Fig.1. Uniform composite I-beam with circular holes in web Modal Analysis The modal analysis is carried out with the top and bottom flanges as angle-ply laminates [θ/ -θ], and the web laminate is assumed to be unidirectional in I beam. In this case, the lowest four natural frequencies by the finite element analysis exactly correspond to the first flexural mode in the x-direction, and flexural mode in the y-direction, second flexural mode in the x-direction, torsional mode by the orthotropic closed-form solution, respectively. 7
Effect of fibre angle rotation in top and bottom Flanges 14 12 ω Natural frequency,Hzs 10 1 8 ω 2 6 4 2 0 0 15 30 45 60 75 90 fiber angle, in degrees Fig.2. Variation of the non-dimensional natural frequencies of a cantilever Composite beam with circular holes in web with fibre angle change in flanges From fig.2, it is clear that natural frequencies for fourth mode increases with increasing fibre angle from 0 to 450 , maximum at 450 and then decreases afterwards. In second mode, the natural frequency at 450 fibre angle found to be minimum. Mode shapes The mode shapes corresponding to the first four lowest modes with unidirectional fibre in web and fibre angle 45° is taken in the top and bottom flanges are illustrated in Fig.3. (a).Mode 1 (b) Mode 2 8
(c) Mode 3 (d) Mode 4 Fig. 3. Mode shapes of the Cantilever composite beam with circular holes in web with fibre angle 45 0 in top and bottom flanges Effect of fibre angle rotation in web 12 10 Natural frequency, Hzs 8 6 4 ω 1 2 0 0 15 30 fiber angle, in60 45 degrees75 90 Fig4. Variation of the non-dimensional natural frequencies of a Cantilever composite beam with circular holes in web with to fibre angle change in flanges From fig.4, it is observed that natural frequencies of third mode increases with increasing fibre angle from 0 to 450 reaches maximum at 450 and then decreases afterwards. For all other modes, there is no variation in natural frequencies by changing the fibre angle in web. Effect of Elastic modular ratio: In this, it shows the effects of modulus ratio ( E1 /E2) of composite beams on the natural frequencies and mode shapes for uniform Cantilever composite beam with circular holes in web (Fig.5). The stacking sequence of the top and bottom flanges are [0/90]s, and web is unidirectional. It is observed that the natural frequencies increase with increasing orthotropy ( E1 /E2). 9
8 7 6 Natural frequency, Hzs 5 4 ω 3 1 ω 2 2 1 0 0 10 20 30 40 Elastic modular ratio Fig. 5. Variation of the non-dimensional natural frequencies of a Cantilever composite beam with circular holes in web with elastic modular ratio Harmonic Analysis The harmonic analysis is carried out for a cantilever composite uniform doubly symmetric I-beam and load of 1 Newton is applied at free end. The study is carried out by varying fibre angle rotation in top and bottom flanges of I- beam and elastic modular ratio and results are obtained and represented in the graphical form as Frequency vs. Displacement. Effect of fibre angle rotation in top and bottom Flanges From fig.6, the maximum displacement is observed at natural frequency of 20 Hz. for fibre angle 450 and displacement is maximum for fibre angle600 at frequency 5Hz. 3.00E-04 2.50E-04 0 1 2.00E-04 Displacement, in meters 5 3 1.50E-04 0 4 1.00E-04 5 5.00E-05 0.00E+00 -5.00E-05 -1.00E-04 0 5 10 15 20 25 Natural frequency, Hzs Fig.6. Frequency vs. Displacement for fibre angle rotation in two flanges 10
Effect of fibre angle rotation in web 4.00E-05 2.00E-05 0.00E+00 Displacement, in meters -2.00E-05 0 15 -4.00E-05 30 -6.00E-05 45 60 -8.00E-05 75 -1.00E-04 -1.20E-04 0 5 10 15 20 25 natural frequency, Hzs Fig.7. Frequency vs. Displacement for fibre angle rotation in web. From fig.7, it is observed that, for fibre angle 450, the maximum displacement is at natural frequency of 10 Hz. Effect of modular ratio: From fig.8, it is observed that, for modulus ratio of 30, the maximum displacement is at natural frequency of 5 Hz. 2.00E-04 1.00E-04 Displacement, in 0.00E+00 -1.00E-04 meters E1/E2=1 -2.00E-04 E1/E2=10 E1/E2=20 -3.00E-04 -4.00E-04 0 5 10 15 20 25 Natural frequency, Hzs Fig.8. Frequency vs. Displacement for various modular ratios. Conclusions: 11
References: 12

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Modal and harmonic analysis of tapered composite i

  • 1. Modal And Harmonic Analysis Of Tapered Composite I- Beam With Big End Fixed Dr. N.V.Srinivasulu1, Dr.V.Veeranna2, S.Jaikrishna3 1.Associate Professor, Department of Mechanical Engineering, CBIT, Hyderabad- 500075.AP.India. Mail: vaastusrinivas@gmail.com 2. Professor, Department of Technology, Brindavan Institute of Tech and Science,Kurnool. 3. Sr.Assistant Professor,Deprtment of Mech. Engg., MJCET, Hyderabad. Abstract In this paper the tapered thin walled glass epoxy composite I-beam is taken with its big end fixed and small end is kept free. For harmonic analysis 1.0 N load is applied at free end of the cantilever beam and. the results obtained are presented in graphical form with displacement Vs natural frequency and results are presented in graphical form for various cases. Introduction: In the present study a thin-walled composite beam with I-section and length L = 8 m is considered in order to investigate the effects of various parameters namely fibre orientation, modulus ratio, height-to-thickness ratio and boundary conditions on the natural frequencies and mode shapes. The geometry of the I-section is shown in Fig. 1. Fig.1. Thin-walled composite I-beam. 1
  • 2. Modal Analysis A composite cantilever I-beam is modelled with element shell99 and the material and modal analysis is carried out by fixing the bigger end and kept smaller end free. The effect of fibre angle rotation in top and bottom flanges, elastic modulii and height to thickness ratio on natural frequencies and mode shapes are discussed below. Effect of fibre angle rotation in top and bottom Flanges The top and bottom flanges are considered as angle-ply laminates [θ/ -θ], and the web laminate is assumed to be unidirectional. In this case, the lowest four natural frequencies by the finite element analysis exactly correspond to the first flexural mode in the x-direction, flexural mode in the y-direction, second flexural mode in the x-direction, and torsional mode by the orthotropic closed-form solution, respectively. It is clear that from fig.10.1, the natural frequencies are increasing with increase in fibre angle rotation. Very small variation in the natural frequencies for first three modes is observed from 00 and up to fibre angle 450. 10 9 ω1 Natural frequency,Hzs 8 ω2 7 ω3 6 ω4 5 4 3 2 1 0 0 15 30 45 60 75 90 Fiber angle, in degrees Fig 2. Variation of the non-dimensional natural frequencies of a tapered cantilever composite beam with big end fixed with respect to fibre angle change in flanges Mode shapes The mode shapes corresponding to the first four lowest modes with unidirectional fibre in web and fibre angle 45° in the top and bottom flanges are illustrated in fig.3. 2
  • 3. (a).Mode 1 (b). Mode 2 (a).Mode 3 (b). Mode 4 Fig.3. Mode shapes of the tapered composite beam with fibre angle 45 0 in top and bottom flanges Effect of fibre angle rotation in web In this case the natural frequencies for first mode are constant for all fibre angles as shown in fig.4 For second, third and fourth modes frequency is constant from fibre angle 0- 450 and a small increment in each mode is observed . Effect of modular ratio The effects of modulus ratio ( E1 /E2) of composite beams on the natural frequencies and mode shapes for Tapered Cantilever composite beam is shown below. The stacking sequence of the top and bottom flanges are [0/90]s, and web is unidirectional. It is observed that the natural frequencies increase with increasing orthotropy ( E1 /E2). 3
  • 4. 5 4.5 Natural frequency, Hzs 4 3.5 3 ω1 ω2 2.5 ω3 2 ω4 1.5 1 0.5 0 0 15 30 45 60 75 90 Fiber angle, in degrees Fig.4. Variation of the non-dimensional natural frequencies of a Tapered cantilever composite beam with big end fixed with respect to fibre angle change in web. 16 ω1 14 ω2 Natural frequency, Hzs 12 ω3 ω4 10 8 6 4 2 0 0 10 20 30 40 Elastic modulus ratio Fig. 4. Variation of the non-dimensional natural frequencies of a Taper cantilever composite beam with big end fixed with respect to modulus ratio. 4
  • 5. Harmonic analysis The harmonic analysis is carried out for a tapered cantilever composite I-beam and load of 1.0 N is applied at free end. The study is carried out by varying fibre angle rotation in top and bottom flanges of I- beam and elastic modular ratio and results are obtained and represented in the graphical form as Frequency Vs. Displacement. 3.00E-04 0 2.50E-04 15 2.00E-04 30 Displacement, in meters 45 1.50E-04 60 1.00E-04 75 90 5.00E-05 0.00E+00 -5.00E-05 -1.00E-04 -1.50E-04 -2.00E-04 0 5 10 15 20 25 Natural frequency, Hzs Fig5. Frequency vs. Displacement for fibre angle rotation in two flanges 3.00E-04 2.50E-04 0 15 Displacement, in meters 2.00E-04 30 1.50E-04 45 60 1.00E-04 75 5.00E-05 90 0.00E+00 -5.00E-05 -1.00E-04 -1.50E-04 -2.00E-04 0 5 10 15 20 25 Natural frequency,Hzs Fig.6. Frequency vs. Displacement for fibre angle rotation in web Effect of fibre angle rotation in top and bottom Flanges From the fig.5, it is clear that as the frequency increases, the value of the amplitude of vibration for a cantilever composite beam follows sinusoidal curve, for all fibre angles. For fibre angle 450, the value of amplitude of vibration is high at frequency of 5 Hz . 5
  • 6. Effect of fibre angle rotation in web From the fig.10.6, it is seen that as the frequency increases, the value of the amplitude of vibration for a cantilever composite beam follows sinusoidal curve, for all fibre angles same as above case. Effect of modular ratio: From the fig.7, it is evident that there is a small variation in amplitude of vibration for all modular ratios except for modular ratio of 40. For modular ratio of 40, the minimum displacement is at frequency of 20 Hz. 4.00E-04 E1/E2=1 3.00E-04 E1/E2=10 E1/E2=20 Displacement, in meters 2.00E-04 E1/E2=30 1.00E-04 E1/E2=40 0.00E+00 -1.00E-04 -2.00E-04 -3.00E-04 -4.00E-04 0 5 10 15 20 25 Natural frequency, Hzs Fig.7. Frequency vs. Amplitude for various modular ratios. 6
  • 7. Modal and Harmonic Analysis of Composite I-beam with three circular holes in web Dr. N.V.Srinivasulu, Associate Professor, Department of Mechanical Engineering, CBIT, Hyderabad-500075.AP.India. Mail: vaastusrinivas@gmail.com Abstract In this paper, uniform composite thin walled I- beam is considered and three circular holes are made in the web at 2m apart with holes diameter of 32 mm as shown in fig.1. The beam is modeled using ANSYS with the same material properties mentioned in the chapter 8. Modal and harmonic analysis is done for a cantilever boundary condition. Harmonic analysis is carried out by applying a load of 1.0 N at free end and nodal results at free end are obtained in the form of amplitude Vs natural frequency graphs for various fibre angle rotations and modular ratios. The Finite element model of a uniform doubly symmetric composite I-beam with holes in web is shown in fig.1. Fig.1. Uniform composite I-beam with circular holes in web Modal Analysis The modal analysis is carried out with the top and bottom flanges as angle-ply laminates [θ/ -θ], and the web laminate is assumed to be unidirectional in I beam. In this case, the lowest four natural frequencies by the finite element analysis exactly correspond to the first flexural mode in the x-direction, and flexural mode in the y-direction, second flexural mode in the x-direction, torsional mode by the orthotropic closed-form solution, respectively. 7
  • 8. Effect of fibre angle rotation in top and bottom Flanges 14 12 ω Natural frequency,Hzs 10 1 8 ω 2 6 4 2 0 0 15 30 45 60 75 90 fiber angle, in degrees Fig.2. Variation of the non-dimensional natural frequencies of a cantilever Composite beam with circular holes in web with fibre angle change in flanges From fig.2, it is clear that natural frequencies for fourth mode increases with increasing fibre angle from 0 to 450 , maximum at 450 and then decreases afterwards. In second mode, the natural frequency at 450 fibre angle found to be minimum. Mode shapes The mode shapes corresponding to the first four lowest modes with unidirectional fibre in web and fibre angle 45° is taken in the top and bottom flanges are illustrated in Fig.3. (a).Mode 1 (b) Mode 2 8
  • 9. (c) Mode 3 (d) Mode 4 Fig. 3. Mode shapes of the Cantilever composite beam with circular holes in web with fibre angle 45 0 in top and bottom flanges Effect of fibre angle rotation in web 12 10 Natural frequency, Hzs 8 6 4 ω 1 2 0 0 15 30 fiber angle, in60 45 degrees75 90 Fig4. Variation of the non-dimensional natural frequencies of a Cantilever composite beam with circular holes in web with to fibre angle change in flanges From fig.4, it is observed that natural frequencies of third mode increases with increasing fibre angle from 0 to 450 reaches maximum at 450 and then decreases afterwards. For all other modes, there is no variation in natural frequencies by changing the fibre angle in web. Effect of Elastic modular ratio: In this, it shows the effects of modulus ratio ( E1 /E2) of composite beams on the natural frequencies and mode shapes for uniform Cantilever composite beam with circular holes in web (Fig.5). The stacking sequence of the top and bottom flanges are [0/90]s, and web is unidirectional. It is observed that the natural frequencies increase with increasing orthotropy ( E1 /E2). 9
  • 10. 8 7 6 Natural frequency, Hzs 5 4 ω 3 1 ω 2 2 1 0 0 10 20 30 40 Elastic modular ratio Fig. 5. Variation of the non-dimensional natural frequencies of a Cantilever composite beam with circular holes in web with elastic modular ratio Harmonic Analysis The harmonic analysis is carried out for a cantilever composite uniform doubly symmetric I-beam and load of 1 Newton is applied at free end. The study is carried out by varying fibre angle rotation in top and bottom flanges of I- beam and elastic modular ratio and results are obtained and represented in the graphical form as Frequency vs. Displacement. Effect of fibre angle rotation in top and bottom Flanges From fig.6, the maximum displacement is observed at natural frequency of 20 Hz. for fibre angle 450 and displacement is maximum for fibre angle600 at frequency 5Hz. 3.00E-04 2.50E-04 0 1 2.00E-04 Displacement, in meters 5 3 1.50E-04 0 4 1.00E-04 5 5.00E-05 0.00E+00 -5.00E-05 -1.00E-04 0 5 10 15 20 25 Natural frequency, Hzs Fig.6. Frequency vs. Displacement for fibre angle rotation in two flanges 10
  • 11. Effect of fibre angle rotation in web 4.00E-05 2.00E-05 0.00E+00 Displacement, in meters -2.00E-05 0 15 -4.00E-05 30 -6.00E-05 45 60 -8.00E-05 75 -1.00E-04 -1.20E-04 0 5 10 15 20 25 natural frequency, Hzs Fig.7. Frequency vs. Displacement for fibre angle rotation in web. From fig.7, it is observed that, for fibre angle 450, the maximum displacement is at natural frequency of 10 Hz. Effect of modular ratio: From fig.8, it is observed that, for modulus ratio of 30, the maximum displacement is at natural frequency of 5 Hz. 2.00E-04 1.00E-04 Displacement, in 0.00E+00 -1.00E-04 meters E1/E2=1 -2.00E-04 E1/E2=10 E1/E2=20 -3.00E-04 -4.00E-04 0 5 10 15 20 25 Natural frequency, Hzs Fig.8. Frequency vs. Displacement for various modular ratios. Conclusions: 11