Damping Mechanisms in Cable-Harnessed Structures for Space Applications: Experimental Validation

Agrawal, Pranav; Salehian, Armaghan

doi:10.1115/1.4048391

Cited by 5 publications

(1 citation statement)

References 12 publications

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“…The DTFM has also been extended to vibration analyses of thick piezoelectric beams and adaptive structures (Majeed et al, 2011, 2014, 2021). In addition to applications to multi-physics systems, the DTFM has also been applied to vibration analyses and control of damped aerospace structures (Agrawal and Salehian, 2021; Fang et al, 2002; Spak et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Investigation of boundary flexibility on the performance of piezoelectric vibration energy harvesting beam systems by DTFM

Amoozegar

Tan

2022

Journal of Intelligent Material Systems and Structures

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The purpose of this paper is to investigate the effect of boundary flexibility on the performance of piezoelectric vibration energy harvester (PVEH) beam systems, which has not been studied comprehensively in the literature despite its importance. The coupled electromechanical equations of motion of a piezoelectric cantilever beam with a tip mass are established, with the base boundary constrained by translational and rotational springs. An exact closed-form solution of the frequency response function (FRF) of the PVEH is obtained by the distributed transfer function method (DTFM). The DTFM is a systematic powerful tool for the dynamic analysis of distributed parameter continua with non-classical boundary conditions, intermediate constraints, coupled fields, and non-proportional damping without adding much complexity to the solution formulation. Moreover, the DTFM computes the derivatives of the response, that is, the strains, which are required in the electromechanical coupling formulation, simultaneously without any differentiation. Numerical results showing the effects of boundary flexibility on energy harvesting efficiency are presented. A first-order rational function relating the boundary stiffness parameters and the harvesting efficiency is determined by nonlinear curve fitting of the calculated data. Physical insights and applicability of this analytical function for end-of-line quality check of the boundary of PVEH are discussed.

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Section: Introductionmentioning

confidence: 99%

Investigation of boundary flexibility on the performance of piezoelectric vibration energy harvesting beam systems by DTFM

Amoozegar

Tan

2022

Journal of Intelligent Material Systems and Structures

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Dynamic Analysis and Experimental Validation of Periodically Wrapped Cable-Harnessed Plate Structures

Agrawal

Salehian

2022

Exp Mech

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Optimal Geometry for Cable Wrapping to Minimize Dynamic Impacts on Cable-Harnessed Beam Structures

Cao

Agrawal

et al. 2020

Journal of Vibration and Acoustics

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Power and cable carrier systems have been shown to significantly impact the dynamic behavior of lightweight space structures. The goal of this paper is to obtain an optimal cable placement geometry for cable-harnessed beam structures to minimize the impact of the added cables on the system dynamics. The cable is harnessed to the beam in a periodic pattern, which forms several repeating fundamental elements within the structure. An analytical model for the cable-harnessed beam using an energy-equivalence homogenization method is employed for the purpose of optimization. The natural frequencies of the cable harnessed beam is then matched with the bare beam when no cables attached through an optimization algorithm in order to find the optimal cable placement solution for the given system parameters. Subsequently, the effects of the system parameters on the optimal solutions are investigated and discussed. Experimental modal analysis is then performed to further validate the optimal solutions found using the model. The test results further validate the findings from the model. The frequency response functions from the bare beam and the optimally wrapped beam align really well.

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Damping Mechanisms in Cable-Harnessed Structures for Space Applications: Experimental Validation

Cited by 5 publications

References 12 publications

Investigation of boundary flexibility on the performance of piezoelectric vibration energy harvesting beam systems by DTFM

Investigation of boundary flexibility on the performance of piezoelectric vibration energy harvesting beam systems by DTFM

Dynamic Analysis and Experimental Validation of Periodically Wrapped Cable-Harnessed Plate Structures

Optimal Geometry for Cable Wrapping to Minimize Dynamic Impacts on Cable-Harnessed Beam Structures

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