Sound transmission loss of composite and sandwich panels in thermal environment

Abstract Composite sandwich structures are extensively applied in automotive, marine, aircraft because of superior stiffness-to-weight ratios. These structures are invariably exposed to the thermal and noise environment in their service life especially as a component of the hypersonic aircraft. The paper is originally focused on the sound transmission loss (STL) of the sandwich panels constituted of orthotropic materials in thermal environment. Firstly, the governing equations are obtained by applying Hamilton's principle. Both the natural frequencies and corresponding mode functions are derived with thermal stresses taking into account. The formulation of STL is obtained by using the mode superposition method. Then the published experimental result and numerical simulation are demonstrated to validate the accuracy of the analytical solution. Finally, the influences of temperature, elevation angle and azimuth angle of incident sound on the STL of finite sandwich panels are investigated systematically. It is observed that natural frequencies of the panel decrease and peaks of the STL tend to drop and flow to the lower frequencies with the increment of the temperature. The STL decreases with the increment of the elevation angle.

[2]  Ryszard Buczkowski,et al.  Nonlinear buckling and post-buckling response of stiffened FGM plates in thermal environments , 2017 .

[3]  B. Watters,et al.  New Wall Design for High Transmission Loss or High Damping , 1959 .

[4]  Atul Bhaskar,et al.  Sound transmission through a double-panel construction lined with poroelastic material in the presence of mean flow , 2013 .

[6]  Noureddine Atalla,et al.  The transmission loss of curved laminates and sandwich composite panels , 2005 .

[7]  M. Apalak,et al.  Low velocity bending impact behavior of foam core sandwich beams: Experimental , 2017 .

[8]  Jie Zhou,et al.  Optimization for sound transmission through a double-wall panel , 2013 .

[9]  Joshua D. Summers,et al.  The Effect of Honeycomb Core Geometry on the Sound Transmission Performance of Sandwich Panels , 2014 .

[10]  Zhaofeng Chen,et al.  Acoustic properties of glass fiber assembly-filled honeycomb sandwich panels , 2016 .

[11]  M. Crocker,et al.  Sound transmission loss of foam-filled honeycomb sandwich panels using statistical energy analysis and theoretical and measured dynamic properties , 2010 .

[12]  Deng Zhaoxiang,et al.  Sound transmission loss characteristics of unbounded orthotropic sandwich panels in bending vibration considering transverse shear deformation , 2010 .

[13]  Jay Kim,et al.  Analysis of Sound Transmission Through Periodically Stiffened Panels by Space-Harmonic Expansion Method , 2002 .

[14]  L. Gagliardini,et al.  PREDICTING THE ACOUSTICAL RADIATION OF FINITE SIZE MULTI-LAYERED STRUCTURES BY APPLYING SPATIAL WINDOWING ON INFINITE STRUCTURES , 2001 .

[15]  Feng Jin,et al.  Sound Transmission Loss of Adhesively Bonded Sandwich Panels with Pyramidal Truss Core: Theory and Experiment , 2015 .

[16]  P. Lord,et al.  Sound transmission through sandwich constructions , 1967 .

[18]  Matthew Sneddon,et al.  Transmission loss of honeycomb sandwich structures with attached gas layers , 2011 .

[19]  Tian Jian Lu,et al.  Theoretical model for sound transmission through finite sandwich structures with corrugated core , 2012 .

[20]  Sungjoo Lee,et al.  Prediction of sound reduction index of double sandwich panel , 2015 .

[21]  Xu Guo,et al.  On compressive properties of composite sandwich structures with grid reinforced honeycomb core , 2016 .

[22]  Dongdong Li,et al.  Thermomechanical bending analysis of functionally graded sandwich plates using four-variable refined plate theory , 2016 .

[23]  M. Guerich,et al.  Optimization of Noise Transmission Through Sandwich Structures , 2013 .

[24]  Yong Xia,et al.  High-temperature deformation field measurement by combining transient aerodynamic heating simulation system and reliability-guided digital image correlation , 2010 .

[25]  R. H. Lyon,et al.  Sound transmission loss characteristics of sandwich panel constructions , 1991 .

[26]  Tian Jian Lu,et al.  Sound Transmission Through Simply Supported Finite Double-Panel Partitions With Enclosed Air Cavity , 2010 .

[27]  Sergio De Rosa,et al.  Numerical and experimental investigations on the acoustic power radiated by Aluminium Foam Sandwich panels , 2014 .

[28]  Yong‐Joe Kim,et al.  Identification of Acoustic Characteristics of Honeycomb Sandwich Composite Panels Using Hybrid Analytical/Finite Element Method , 2013 .

[29]  Ole Thybo Thomsen,et al.  Non-linear thermal response of sandwich panels with a flexible core and temperature dependent mechanical properties , 2008 .

[30]  Steven Nutt,et al.  Transmission loss assessments of sandwich structures by using a combination of finite element and boundary element methods , 2005 .

[31]  A. Beukers,et al.  Sound Transmission Loss Prediction of the Composite Fuselage with Different Methods , 2012, Applied Composite Materials.

[32]  Liu Liu,et al.  Dynamic response of acoustically excited plates resting on elastic foundations in thermal environments , 2016 .

[33]  Malcolm J. Crocker,et al.  Sound Transmission Characteristics of Asymmetric Sandwich Panels , 2010 .

[34]  Kaiping Yu,et al.  A piecewise shear deformation theory for free vibration of composite and sandwich panels , 2015 .

[35]  Yueming Li,et al.  Vibration and Acoustic Response of Rectangular Sandwich Plate under Thermal Environment , 2013 .

[36]  Malcolm J Crocker,et al.  Boundary element analyses for sound transmission loss of panels. , 2010, The Journal of the Acoustical Society of America.

[37]  Yu Liu,et al.  Sound transmission through triple-panel structures lined with poroelastic materials , 2015 .

[38]  C. Soares,et al.  A new higher order shear deformation theory for sandwich and composite laminated plates , 2012 .

[39]  Yu Liu,et al.  Effects of external and gap mean flows on sound transmission through a double-wall sandwich panel , 2015 .

[40]  James P. Carneal,et al.  An analytical and experimental investigation of active structural acoustic control of noise transmission through double panel systems , 2004 .

[41]  Bernard Budiansky,et al.  Influence of Aerodynamic Heating on the Effective Torsional Stiffness of Thin Wings , 1956 .

[42]  T. Lu,et al.  Analytical and experimental investigation on transmission loss of clamped double panels: implication of boundary effects. , 2009, The Journal of the Acoustical Society of America.

[43]  Jukka Tuhkuri,et al.  Active attenuation of sound transmission through a soft-core sandwich panel into an acoustic enclosure using volume velocity cancellation , 2015 .

[44]  M. Guerich,et al.  Numerical Prediction of Noise Transmission Loss through Viscoelastically Damped Sandwich Plates , 2008 .

[45]  Tongan Wang,et al.  Assessment of sandwich models for the prediction of sound transmission loss in unidirectional sandwich panels , 2005 .

[46]  Clive L. Dym,et al.  Transmission of sound through sandwich panels , 1974 .

[47]  Clive L. Dym,et al.  Transmission of sound through sandwich panels: A reconsideration , 1976 .

[48]  James Albert Moore Sound transmission‐loss characteristics of three‐layer composite wall constructions , 1978 .

[49]  T. Lu,et al.  Vibroacoustic behavior of clamp mounted double-panel partition with enclosure air cavity. , 2008, The Journal of the Acoustical Society of America.

[50]  K. Daryabeigi Thermal Analysis and Design Optimization of Multilayer Insulation for Reentry Aerodynamic Heating , 2002 .

[51]  T. Vo,et al.  An analytical method for the vibration and buckling of functionally graded beams under mechanical and thermal loads , 2016 .

[52]  Marek Krzaczek,et al.  Experiments and FE Analyses on Airborne Sound Properties of Composite Structural Insulated Panels , 2015 .

[53]  Y. Frostig Shear buckling of sandwich plates – Incompressible and compressible cores , 2016 .

[54]  H. Tung Nonlinear thermomechanical response of pressure-loaded doubly curved functionally graded material sandwich panels in thermal environments including tangential edge constraints: , 2018 .

[55]  Chenguang Huang,et al.  Thermal post-buckling behavior of simply supported sandwich panels with truss cores , 2016 .

[56]  S. Raja,et al.  Vibro-acoustic response and sound transmission loss analysis of functionally graded plates , 2014 .

[57]  Yeoshua Frostig Classical and high-order computational models in the analysis of modern sandwich panels , 2003 .

[58]  Kaiping Yu,et al.  Vibration and acoustic responses of composite and sandwich panels under thermal environment , 2015 .

[59]  R. D. Mindlin,et al.  Influence of rotary inertia and shear on flexural motions of isotropic, elastic plates , 1951 .

[60]  J. Mantari,et al.  Thermoelastic analysis of advanced sandwich plates based on a new quasi-3D hybrid type HSDT with 5 unknowns , 2015 .

[61]  E. M. Krokosky,et al.  Dilatational‐Mode Sound Transmission in Sandwich Panels , 1969 .

[62]  S. Akavci Mechanical behavior of functionally graded sandwich plates on elastic foundation , 2016 .

[63]  M. Mohammadimehr,et al.  High-order buckling and free vibration analysis of two types sandwich beam including AL or PVC-foam flexible core and CNTs reinforced nanocomposite face sheets using GDQM , 2017 .

[64]  Noureddine Atalla,et al.  Diffuse field transmission into infinite sandwich composite and laminate composite cylinders , 2006 .

[65]  N. Ganesan,et al.  Vibro-acoustic behavior of a multilayered viscoelastic sandwich plate under a thermal environment , 2011 .

[66]  Francesco Franco,et al.  A review of the vibroacoustics of sandwich panels: Models and experiments , 2013 .

[67]  David Hui,et al.  Mechanical behavior of composited structure filled with tandem honeycombs , 2017 .