Dynamic characterization of viscoelastic materials used in composite structures

Fotsing, Edith Roland; Sola, M; Ross, Annie; Ruiz, Édu

doi:10.1177/0021998313514254

Cited by 10 publications

(5 citation statements)

References 16 publications

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“…Although these methods are well established, they provide incomplete information, in the sense that they do not give the frequency dependence of the material properties. The second category concerns methods based on modal analysis [2,3]. They rely on the identification of natural frequencies and modal damping ratios to estimate the Young's modulus and loss factor of a material.…”

Section: Introductionmentioning

confidence: 99%

Experimental identification of homogenized traction and bending complex Young’s modules using a local dynamic inverse method on a sandwich curved beam

Bottois

Ablitzer

Audrain

et al. 2021

Journal of Sound and Vibration

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Section: Introductionmentioning

confidence: 99%

Experimental identification of homogenized traction and bending complex Young’s modules using a local dynamic inverse method on a sandwich curved beam

Bottois

Ablitzer

Audrain

et al. 2021

Journal of Sound and Vibration

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“…[31], and Fotsing et al. [32,33], who investigated the effect of entangled cross-linked fibers and interleaved viscoelastic layers (as inherently damped materials) in damping the vibration response of laminate and sandwich composites. Sargianis et al.…”

Section: Introductionmentioning

confidence: 99%

Static and dynamic characteristics of nano-reinforced 3D-fiber metal laminates using non-destructive techniques

Soltannia‬

Mertiny

Taheri‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬‬

2020

Jnl of Sandwich Structures & Materials

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Uncontrolled vibration in mechanical systems (e.g. aircraft, trains, and automobiles) may result in undesirable noise and eventually, cause mechanical failure. In this context, the main objective of the present research is to explore parameters that govern and affect the frequency response of three-dimensional fiber metal laminates. Three-dimensional fiber metal laminates are a class of novel lightweight hybrid material systems with great potential for use in aforementioned applications. Therefore, the vibration characteristics of the two most commonly used configurations of three-dimensional fiber metal laminates are experimentally investigated by nontraditional and conventional approaches. Material damping is also improved by the inclusion of two different types of nanocarbon particles within the core and/or interfaces of the hybrid system. The results are presented and compared. The inclusion of nanocarbon particle improved the fundamental frequency of the system slightly; however, material damping was enhanced significantly when only 1 wt% nanocarbon particle was used in the interfacial sections of the system.

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“…DMA þ quasi-static or DMA þ Hopkinson bar þ quasi-static) 4,5,15,16 and DMA are only valid for a limited set of strain rates and low strains levels. [16][17][18][19][20] This has historically been the methodology for modeling flexible materials but would not actually apply to a highly deformable and dynamically loaded matrix (see Figure 2). Thus, by extension, the existing methodology would not accurately capture the dynamic behavior of a FMC.…”

Section: Introductionmentioning

confidence: 99%

Dynamic response and validation of a flexible matrix composite

Whisler

Consarnau

Buenrostro

2019

Journal of Composite Materials

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Testing and predicting the dynamic response of flexible matrix composites in impact loading condition face two primary challenges: (i) experimentally, existing techniques using existing instruments do not always provide high fidelity material data under simultaneous high strain and high strain rate loading conditions; and (ii) finite element simulations of a highly flexible material require many material parameters and complex mathematical formulations. To address these limitations, this research investigation presents a technique originally developed in-house for modeling and validating hyper-viscoelastic materials and applies it toward the flexible matrix composite. Results from a simple low-velocity impact (2 m/s) test on a 75 × 75 mm2 flexible matrix composite indicate that the critical material properties for the low strength, highly deformable matrix in conjunction with an updated constitutive model can accurately predict the dynamic behavior within 10% with respect to the force time history response using MATLAB and ABAQUS/Explicit. Finite element interrogation also shows full field stress response within the composite specimen not easily measured via sensors and deformation matching the behavior observed via high-speed camera. Finally, on-going research in this arena indicates that the technique can be applied to higher rate loading mechanisms, such as a gas gun and Hopkinson bar apparatus, in order to obtain material parameters for even more devastating impact loading strain rates.

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Dynamic characterization of viscoelastic materials used in composite structures

Cited by 10 publications

References 16 publications

Experimental identification of homogenized traction and bending complex Young’s modules using a local dynamic inverse method on a sandwich curved beam

Experimental identification of homogenized traction and bending complex Young’s modules using a local dynamic inverse method on a sandwich curved beam

Static and dynamic characteristics of nano-reinforced 3D-fiber metal laminates using non-destructive techniques

Dynamic response and validation of a flexible matrix composite

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