Darleux, Robin; Lossouarn, Boris; Giorgio, Ivan; Dell’isola, Francesco; Deü, Jean-François Electrical analogs of curved beams and application to piezoelectric network damping. (English) Zbl 07601664 Math. Mech. Solids 27, No. 4, 578-601 (2022). Summary: In this paper, the method of electric analog synthesis is applied to design a piezo-electro-mechanical arch able to show the capacity of multimodal damping. An electric-analog circuit is designed by using a finite number of lumped elements representing the equivalent of a curved beam. Spatial and frequency coherence conditions are proven to be verified for the modes to be damped: in fact, lumped-element circuit can damp only a finite number of vibration modes. Analogous boundary conditions are ensured, so that natural frequencies and mode shapes of both the curved beam and the analog circuit are equal. The instance considered here is the vibration mitigation of a piezo-electro-mechanical arch. Having a view towards prototypical applications, all simulations consider values of physically feasible passive circuital elements. It is believed that the present results may represent a step towards the design of multi-physics metamaterials based on micro-structures exploiting the principle of multimodal damping. Cited in 5 Documents MSC: 74-XX Mechanics of deformable solids Keywords:electromechanical analogy; lumped-element model; piezoelectric coupling; vibration mitigation; multimodal damping PDFBibTeX XMLCite \textit{R. Darleux} et al., Math. Mech. Solids 27, No. 4, 578--601 (2022; Zbl 07601664) Full Text: DOI References: [1] Kron G. Numerical solution of ordinary and partial differential equations by means of equivalent circuits. J Appl Phys1945; 16(3): 172-186. · Zbl 0061.29605 [2] MacNeal RH. The solution of partial differential equations by means of electrical networks. PhD Thesis, California Institute of Technology, 1949. [3] MacNeal RH, McCann GD, Wilts CH. 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