Modeling and simulation of thin-walled piezoelectric energy harvesters immersed in flow using monolithic fluid–structure interaction

SHANG, Lan; Hoareau, Christophe; ZILIAN, Andreas

doi:10.1016/j.finel.2022.103761

Article (Périodiques scientifiques)

Modeling and simulation of thin-walled piezoelectric energy harvesters immersed in flow using monolithic fluid–structure interaction

SHANG, Lan; Hoareau, Christophe; ZILIAN, Andreas

2022 • In Finite Elements in Analysis and Design, 206, p. 103761

Peer reviewed

Permalien
https://hdl.handle.net/10993/54215

DOI
10.1016/j.finel.2022.103761

Documents (1)Envoyer vers Détails Statistiques Bibliographie Publications similaires

Documents

Texte intégral

1-s2.0-S0168874X22000361-main.pdf

Postprint Éditeur (3.64 MB)

Télécharger

Tous les documents dans ORBilu sont protégés par une licence d'utilisation.

Envoyer vers

RIS BibTex APA Chicago Permalink X Linkedin

Détails

Disciplines :

Ingénierie, informatique & technologie: Multidisciplinaire, généralités & autres

Auteur, co-auteur :

SHANG, Lan ; University of Luxembourg > Faculty of Science, Technology and Medicine (FSTM) > Department of Engineering (DoE)

Hoareau, Christophe

ZILIAN, Andreas ; University of Luxembourg > Faculty of Science, Technology and Medicine (FSTM) > Department of Engineering (DoE)

Co-auteurs externes :

yes

Langue du document :

Anglais

Titre :

Modeling and simulation of thin-walled piezoelectric energy harvesters immersed in flow using monolithic fluid–structure interaction

Date de publication/diffusion :

2022

Titre du périodique :

Finite Elements in Analysis and Design

Volume/Tome :

206

Pagination :

103761

Peer reviewed :

Peer reviewed

Focus Area :

Computational Sciences

Projet FnR :

FNR12252781 - Data-driven Computational Modelling And Applications, 2017 (01/09/2018-28/02/2025) - Andreas Zilian

Disponible sur ORBilu :

depuis le 27 janvier 2023

Statistiques

Nombre de vues

79 (dont 3 Unilu)

Nombre de téléchargements

55 (dont 1 Unilu)

Voir plus de statistiques

citations Scopus^®

citations Scopus^®
sans auto-citations

OpenCitations

citations OpenAlex

citations WoS^™

Bibliographie

Wang, J., Geng, L., Ding, L., Zhu, H., Yurchenko, D., The state-of-the-art review on energy harvesting from flow-induced vibrations. Appl. Energy, 267, 2020, 114902.
Amini, Y., Emdad, H., Farid, M., An accurate model for numerical prediction of piezoelectric energy harvesting from fluid structure interaction problems. Smart Mater. Struct., 23(9), 2014, 095034.
Ravi, S., Zilian, A., Simultaneous finite element analysis of circuit-integrated piezoelectric energy harvesting from fluid-structure interaction. Mech. Syst. Signal Process. 114 (2019), 259–274.
Erturk, A., Vieira, W., De Marqui Jr., C., Inman, D.J., On the energy harvesting potential of piezoaeroelastic systems. Appl. Phys. Lett., 96(18), 2010, 184103.
Dunnmon, J., Stanton, S., Mann, B., Dowell, E., Power extraction from aeroelastic limit cycle oscillations. J. Fluids Struct. 27:8 (2011), 1182–1198.
De Marqui Jr., C., Tan, D., Erturk, A., On the electrode segmentation for piezoelectric energy harvesting from nonlinear limit cycle oscillations in axial flow. J. Fluids Struct. 82 (2018), 492–504.
De Marqui, C., Vieira, W.G., Erturk, A., Inman, D.J., Modeling and analysis of piezoelectric energy harvesting from aeroelastic vibrations using the doublet-lattice method. J. Vib. Acoust., 133(1), 2011.
dos Santos, C.R., Pacheco, D.R., Taha, H.E., Zakaria, M.Y., Nonlinear modeling of electro-aeroelastic dynamics of composite beams with piezoelectric coupling. Compos. Struct., 255, 2021, 112968.
Li, D., Wu, Y., Da Ronch, A., Xiang, J., Energy harvesting by means of flow-induced vibrations on aerospace vehicles. Prog. Aerosp. Sci. 86 (2016), 28–62.
Akcabay, D.T., Young, Y.L., Hydroelastic response and energy harvesting potential of flexible piezoelectric beams in viscous flow. Phys. Fluids, 24(5), 2012, 054106.
Mehmood, A., Abdelkefi, A., Hajj, M., Nayfeh, A., Akhtar, I., Nuhait, A., Piezoelectric energy harvesting from vortex-induced vibrations of circular cylinder. J. Sound Vib. 332:19 (2013), 4656–4667.
Huang, G., Xia, Y., Dai, Y., Yang, C., Wu, Y., Fluid–structure interaction in piezoelectric energy harvesting of a membrane wing. Phys. Fluids, 33(6), 2021, 063610.
Chawdhury, S., Morgenthal, G., A partitioned solver to simulate large-displacement fluid–structure interaction of thin plate systems for vibration energy harvesting. Comput. Struct., 224, 2019, 106110.
Donea, J., Giuliani, S., Halleux, J.-P., An arbitrary Lagrangian-Eulerian finite element method for transient dynamic fluid-structure interactions. Comput. Methods Appl. Mech. Engrg. 33:1–3 (1982), 689–723.
Kamensky, D., Hsu, M.-C., Schillinger, D., Evans, J.A., Aggarwal, A., Bazilevs, Y., Sacks, M.S., Hughes, T.J., An immersogeometric variational framework for fluid–structure interaction: Application to bioprosthetic heart valves. Comput. Methods Appl. Mech. Engrg. 284 (2015), 1005–1053.
Peskin, C.S., The immersed boundary method. Acta Numer. 11 (2002), 479–517.
Baaijens, F.P., A fictitious domain/mortar element method for fluid–structure interaction. Internat. J. Numer. Methods Fluids 35:7 (2001), 743–761.
van Loon, R., Anderson, P.D., van de Vosse, F.N., Sherwin, S.J., Comparison of various fluid–structure interaction methods for deformable bodies. Comput. Struct. 85:11–14 (2007), 833–843.
Sheldon, J.P., Miller, S.T., Pitt, J.S., et al. Methodology for comparing coupling algorithms for fluid-structure interaction problems. World J. Mech., 4(02), 2014, 54.
Erturk, A., Inman, D.J., An experimentally validated bimorph cantilever model for piezoelectric energy harvesting from base excitations. Smart Mater. Struct., 18(2), 2009, 025009.
Dietl, J., Wickenheiser, A., Garcia, E., A timoshenko beam model for cantilevered piezoelectric energy harvesters. Smart Mater. Struct., 19(5), 2010, 055018.
Gatti, C.D., Febbo, M., Machado, S.P., Osinaga, S., A piezoelectric beam model with geometric, material and damping nonlinearities for energy harvesting. Smart Mater. Struct., 2020.
Zilian, A., Legay, A., The enriched space–time finite element method (EST) for simultaneous solution of fluid–structure interaction. Internat. J. Numer. Methods Engrg. 75:3 (2008), 305–334.
Landajuela, M., Vidrascu, M., Chapelle, D., Fernández, M.A., Coupling schemes for the FSI forward prediction challenge: comparative study and validation. Int. J. Numer. Methods Biomed. Eng., 33(4), 2017, e2813.
Howells, C.A., Piezoelectric energy harvesting. Energy Convers. Manage. 50:7 (2009), 1847–1850.
Richter, T., Wick, T., Finite elements for fluid–structure interaction in ALE and fully Eulerian coordinates. Comput. Methods Appl. Mech. Engrg. 199:41–44 (2010), 2633–2642.
Hron, J., Turek, S., A monolithic FEM/multigrid solver for an ALE formulation of fluid-structure interaction with applications in biomechanics. Fluid-Structure Interaction, 2006, Springer, 146–170.
Shamanskiy, A., Simeon, B., Mesh moving techniques in fluid-structure interaction: robustness, accumulated distortion and computational efficiency. Comput. Mech. 67:2 (2021), 583–600.
Wick, T., Fluid-structure interactions using different mesh motion techniques. Comput. Struct. 89:13–14 (2011), 1456–1467.
Hübner, B., Walhorn, E., Dinkler, D., A monolithic approach to fluid–structure interaction using space–time finite elements. Comput. Methods Appl. Mech. Engrg. 193:23–26 (2004), 2087–2104.
Reissner, E., On one-dimensional finite-strain beam theory: the plane problem. Z. Angew. Math. Phys. ZAMP 23:5 (1972), 795–804.
Irschik, H., Gerstmayr, J., A continuum-mechanics interpretation of Reissner's non-linear shear-deformable beam theory. Math. Comput. Model. Dyn. Syst. 17:1 (2011), 19–29.
Shang, L., Hoareau, C., Zilian, A., A geometrically nonlinear shear deformable beam model for piezoelectric energy harvesters. Acta Mech. 232:12 (2021), 4847–4866.
Basting, S., Quaini, A., Čanić, S., Glowinski, R., Extended ALE method for fluid–structure interaction problems with large structural displacements. J. Comput. Phys. 331 (2017), 312–336.
Bäumler, K., Bänsch, E., A subspace projection method for the implementation of interface conditions in a single-drop flow problem. J. Comput. Phys. 252 (2013), 438–457.
Chapter 8 - treatment of constraints: Contact and tied interfaces. Zienkiewicz, O., Taylor, R., Fox, D., (eds.) The Finite Element Method for Solid and Structural Mechanics (Seventh Edition), Seventh Edition, 2014, Butterworth-Heinemann, Oxford, 235–275.
Bergersen, A.W., Slyngstad, A., Gjertsen, S., Souche, A., Valen-Sendstad, K., turtleFSI: A robust and monolithic FEniCS-based fluid-structure interaction solver. J. Open Source Softw., 5(50), 2020, 2089.
Chung, J., Hulbert, G., A time integration algorithm for structural dynamics with improved numerical dissipation: the generalized-α method. J. Appl. Mech. 60:2 (1993), 371–375.
Jansen, K.E., Whiting, C.H., Hulbert, G.M., A generalized-α method for integrating the filtered Navier–Stokes equations with a stabilized finite element method. Comput. Methods Appl. Mech. Engrg. 190:3–4 (2000), 305–319.
Bazilevs, Y., Calo, V.M., Hughes, T.J., Zhang, Y., Isogeometric fluid-structure interaction: theory, algorithms, and computations. Comput. Mech. 43:1 (2008), 3–37.
Kadapa, C., Dettmer, W., Perić, D., A fictitious domain/distributed Lagrange multiplier based fluid–structure interaction scheme with hierarchical B-spline grids. Comput. Methods Appl. Mech. Engrg. 301 (2016), 1–27.
Joosten, M., Dettmer, W., Perić, D., On the temporal stability and accuracy of coupled problems with reference to fluid–structure interaction. Internat. J. Numer. Methods Fluids 64:10–12 (2010), 1363–1378.
Ypma, T.J., Historical development of the Newton–Raphson method. SIAM Rev. 37:4 (1995), 531–551.
Taylor, C., Hood, P., A numerical solution of the Navier-Stokes equations using the finite element technique. Comput. & Fluids 1:1 (1973), 73–100.
Reddy, J., On locking-free shear deformable beam finite elements. Comput. Methods Appl. Mech. Engrg. 149:1–4 (1997), 113–132.
Logg, A., Mardal, K.-A., Wells, G., Automated Solution of Differential Equations By the Finite Element Method: The FEniCS Book, Vol. 84. 2012, Springer Science & Business Media.
Balay, S., Abhyankar, S., Adams, M.F., Benson, S., Brown, J., Brune, P., Buschelman, K., Constantinescu, E., Dalcin, L., Dener, A., Eijkhout, V., Gropp, W.D., Hapla, V., Isaac, T., Jolivet, P., Karpeev, D., Kaushik, D., Knepley, M.G., Kong, F., Kruger, S., May, D.A., McInnes, L.C., Mills, R.T., Mitchell, L., Munson, T., Roman, J.E., Rupp, K., Sanan, P., Sarich, J., Smith, B.F., Zampini, S., Zhang, H., Zhang, H., Zhang, J., PETSC/TAO users manual., 2021, Argonne National Laboratory.
Amestoy, P.R., Duff, I.S., L'excellent, J.-Y., Multifrontal parallel distributed symmetric and unsymmetric solvers. Comput. Methods Appl. Mech. Engrg. 184:2–4 (2000), 501–520.
Failer, L., Richter, T., A parallel Newton multigrid framework for monolithic fluid-structure interactions. J. Sci. Comput. 82:2 (2020), 1–27.
Turek, S., Hron, J., Proposal for numerical benchmarking of fluid-structure interaction between an elastic object and laminar incompressible flow. Fluid-Structure Interaction, 2006, Springer, 371–385.
Erturk, A., Tarazaga, P.A., Farmer, J.R., Inman, D.J., Effect of strain nodes and electrode configuration on piezoelectric energy harvesting from cantilevered beams. J. Vib. Acoust., 131(1), 2009.
Tang, L., Païdoussis, M.P., Jiang, J., Cantilevered flexible plates in axial flow: energy transfer and the concept of flutter-mill. J. Sound Vib. 326:1–2 (2009), 263–276.