Numerical Study of Vibro-Acoustic Responses of Un-Baffled Multi-Layered Composite Structure under Various End Conditions and Experimental Validation

Sharma, Nitin; Mahapatra, Trupti Ranjan; Panda, Subrata Kumar

doi:10.1590/1679-78253830

Nitin Sharma

Ph.D Stu., Sch. of Mech. Engineering, KIIT University, Bhubaneswar, Odisha, India, nits.iiit@gmail.com

Trupti Ranjan Mahapatra

Assoc. Prof., Sch. of Mech. Eng., KIIT University, Bhubaneswar, Odisha, India, trmahapatrafme@kiit.ac.in truptiranjan01@gmail.com

Subrata Kumar Panda

Asst. Prof., Dept. of Mech. Eng., NIT, Rourkela, Odisha, India, call2subrat@gmail.com

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Figure 1
Geometry and lay-up scheme of laminated composite flat panel.

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Figure 2
Un-baffled flat panel in acoustic medium.

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Figure 3
Experimental set-up for measuring natural frequencies and SPL of cantilever laminated composite flat panels: (1). Laminated composite plate, (2). Fixture, (3). Impact hammer, (4). Accelerometer, (5). Microphone, (6). NI PXIe 1071.

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Figure 4
Diagram of circuit designed in LABVIEW to record vibration and acoustic response of laminated flat panels.

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Figure 5
Validation study of sound power level (a) Excitation type 1, (b) Excitation type 2.

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Figure 6
Experimental validation study of SPLs for the vibrating plate structure (a) six layered cantilever woven glass/epoxy flat panel and (b) four layered cantilever angle-ply laminated carbon/epoxy flat panel.

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Figure 7
Influence of thickness ratio on the (a) Radiation efficiency; (b) Radiated sound power; (c) Sound pressure level directivity for mode (1,1) and (d) Sound pressure level directivity for mode (2,1) of the laminated composite flat panel (CCCC, four layered symmetric cross-ply, (0º/90º)_s).

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Figure 8
Influence of aspect ratio on the (a) Radiation efficiency and (b) Radiated sound power of the laminated composite flat panel (HHHH four layered anti-symmetric cross-ply, [45º/-45º]₂).

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Figure 9
Influence of modular ratio on the (a) Radiation efficiency and (b) Radiated sound power of the laminated composite flat panel (SSSS 4-layered anti-symmetric angle-ply, [45º/-45º]₂).

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Figure 10
Influence of lay-up scheme on the (a) Radiated sound pressure and (b) Radiated sound power of the laminated composite flat panel (CFFF 4-layered).

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Figure 11
Influence of support condition on the (a) Sound pressure level at field point (0-1000 Hz); (b) Radiated sound power (0-1000 Hz) and (c) Radiated sound power of the laminated composite flat panel (0-5000 Hz)(4-layered anti-symmetric angle-ply [45º/-45º]]₂).

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Figure 12
Comparison of acoustic responses from the laminated flat panel of different composite materials (a) Sound pressure level directivity for mode (1,1); (b) Sound pressure level directivity for mode (2,1); (b) Radiation efficiency and (d) Radiated sound power.

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Table 1
Material properties of glass/epoxy and carbon/epoxy laminated composite plates used for the experimental analysis.

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Table 2
Material properties of Carbon/epoxy composite (Park et al., 2003Park, J., Mongeau, L., Siegmund, T., (2003). Influence of support properties on the sound radiated from the vibrations of rectangular plates. Journal of Sound and Vibration 264:775-794.).

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Table 3
Convergence and validation of natural frequencies of a clamped square isotropic plate.

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Table 4
Convergence and validation of natural frequencies of a simply supported rectangular laminated composite plate.

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Table 5
Experimental validations of the natural frequencies of six layered woven glass/epoxy composite flat panel (M1) and four layered symmetric angle-ply carbon/epoxy flat panel (M2) under CFFF boundary condition.

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Table 6
SPL values for different lay-ups.

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Table 7
Composite material properties of various laminated flat panels used for computation in the case study.

(1)

(2)

(3)

(4)

(5)

(6)

(7)

(8)

(9)

(10)

(11)

(12)

(13)

(14)

(15)

(16)

(17)

(18)

(19)

Parameters	Glass/epoxy (Material: M1)	Carbon/epoxy (Material: M2)
Lamination Scheme	[0ᵒ/90ᵒ]₃	[±45ᵒ]_s
a	0.15 m	0.15 m
b	0.15 m	0.15 m
h	0.002 m	0.00375 m
_^E1	7.205×10⁹ Pa	6.469×10⁹ Pa
_{^{E2= E3}}	6.327×10⁹ Pa	5.626×10⁹ Pa
_{^{ν12= ν23= ν13}}	0.17	0.3
_{^{G12= G13}}	2.8×10⁹ Pa	2.05×10⁹ Pa
_^G23	1.4×10⁹ Pa	1.025×10⁹ Pa
ρ	1420.05 kgm^-3	1388 kgm^-3

Carbon/epoxy (Material: M3)
_^E1	1.725×10¹¹ Pa
_{^{E2 = E3}}	6.9×10⁹ Pa
_{^{ν12 = ν23 = ν13}}	0.25
_^G12 = _^G13	3.45×10⁹ Pa
_^G23	0.5×_^G12
ρ	1600 kgm^-3

	Natural Frequency (Hz)
Mesh Size	Mode 1	Mode 2	Mode 3	Mode 4	Mode 5
2×2	234.70	1715.70	1715.70	3176.40	3176.40
4×4	236.51	498.94	498.94	773.31	913.04
6×6	223.63	457.50	457.50	683.94	828.49
8×8	222.66	452.58	452.58	665.77	809.82
10×10	222.52	451.65	451.65	662.86	805.33
12×12	222.48	451.39	451.39	662.16	803.81
14×14	222.47	451.28	451.28	661.93	803.18
(Jeyaraj 2010Jeyaraj, P., (2010). Vibro-acoustic behavior of an isotropic plate with arbitrarily varying thickness. European Journal of Mechanics - A/Solids 29:1088-1094.)	224	456	456	673	819

	Natural Frequency (Hz)
Mesh Size	Mode 1	Mode 2	Mode 3	Mode 4	Mode 5	Mode 6
2×2	221.10	1703.30	2615.5	2747.20	2786.80	6977.30
4×4	157.10	317.48	457.00	608.82	761.50	999.64
6×6	156.21	296.56	444.13	504.35	633.24	801.68
8×8	156.16	295.46	443.03	496.18	624.36	767.34
10×10	156.15	295.29	442.78	494.76	623.32	760.66
12×12	156.15	295.24	442.69	494.32	623.08	758.51
14×14	156.15	295.22	442.65	494.14	623.00	757.61
(Wu and Huang 2015Wu, J., Huang, L., (2013). Natural frequencies and acoustic radiation mode amplitudes of laminated composite plates based on the layerwise FEM. International Journal of Acoustics and Vibration 18:134-140.)	154	291	442	489	614	755

Mode No.	Natural Frequency (Hz)
	Material: M1			Material: M2
	Present experimental	Present numerical	% diff.	Present experimental	Present numerical	% diff.
1	28	29.431	4.862	62.5	56.038	-11.531
2	68	79.319	14.270	152	140.29	-8.347
3	164	183.4	10.578	378	340.2	-11.111
4	234	236.26	0.957	485	441.53	-9.845
5	267	278.97	4.291	561	503.23	-11.480

Lay-up	[45ᵒ/-45ᵒ]_s	[45ᵒ/-45ᵒ]₂	[0ᵒ/90ᵒ]_s	[0ᵒ/90ᵒ]₂
Average SPL	60.125	59.424	58.496	58.364

Properties	Graphite-epoxy (Kumar et al., 2010Kumar, B. R., Ganesan, N., Sethuraman, R., (2010). Vibro-acoustic analysis of composite elliptic disc with various orthotropic properties. Journal of Composite Materials 44:1179-1200.)	Boron-epoxy (Kumar et al., 2010Kumar, B. R., Ganesan, N., Sethuraman, R., (2010). Vibro-acoustic analysis of composite elliptic disc with various orthotropic properties. Journal of Composite Materials 44:1179-1200.)	Kevlar-epoxy (Kumar et al., 2010Kumar, B. R., Ganesan, N., Sethuraman, R., (2010). Vibro-acoustic analysis of composite elliptic disc with various orthotropic properties. Journal of Composite Materials 44:1179-1200.)	Glass-epoxy (Daneshjou et al., 2007Daneshjou, K., Nouri, A., Talebitooti, R., (2007). Sound transmission through laminated composite cylindrical shells using analytical model. Archives of Applied Mechanics 77:363-379.)
_^E1	1.37×10¹¹ Pa	2.04×10¹¹ Pa	76×10⁹ Pa	38.6×10⁹ Pa
_^E2 = _^E3	8.9×10⁹ Pa	18.3×10⁹ Pa	5.5×10⁹ Pa	8.2×10⁹ Pa
_^ν12 = _^ν23 = _^ν13	0.28	0.23	0.23	0.26
_^G12 = _^G13	7.1×10⁹ Pa	5.5×10⁹ Pa	2.4×10⁹ Pa	4.2×10⁹ Pa
_^G23	0.5×_^G12	0.5×_^G12	0.5×_^G12	0.5×_^G12
ρ	1600 kgm^-3	2000 kgm^-3	1460 kgm^-3	1900 kgm^-3

\begin{array}{l} u (x, y, z, t) = u_{0} (x, y) + z θ_{x} (x, y) \\ v (x, y, z, t) = v_{0} (x, y) + z θ_{y} (x, y) \\ w (x, y, z, t) = w_{0} (x, y) + z θ_{z} (x, y) \end{array}

J = 2 \int_{S} j ω ρ μ_{x} V_{n, y} + \int_{S} \int_{S} μ_{x} μ_{y} \frac{\partial^{2} G_{x y}}{\partial n_{x} \partial n_{y}} d S_{x} d S_{y}

\begin{array}{l} \int_{S} \int_{S} μ_{x} μ_{y} \frac{\partial^{2} G_{x y}}{\partial n_{x} \partial n_{y}} d S_{x} d S_{y} = \int_{S} \int_{S} G_{x y} [k^{2} μ_{x} μ_{y} (n_{x} \cdot n_{y}) - (\nabla \times μ_{x}) \cdot (\nabla \times μ_{y})] d S_{x} d S_{y} \\ = 〈 μ 〉 [D (ω)] {μ} \end{array}}

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Numerical Study of Vibro-Acoustic Responses of Un-Baffled Multi-Layered Composite Structure under Various End Conditions and Experimental Validation

Abstract