Top

Published in:

2020 | OriginalPaper | Chapter

10. Vibration Energy Harvesting in Fluctuating Fluid Flows

Authors : S. Krishna Kumar, Sunetra Sarkar, Sayan Gupta

Published in: Dynamics and Control of Energy Systems

Publisher: Springer Singapore

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

Ambient energy harvesting for power supply to low power hardware, like sensors in inaccessible environments, has garnered sustained interest over the last two decades. Common sources of ambient energy include vehicle vibrations and natural fluid flow. The latter is also proposed as a possible quiet alternative to conventional renewable energy systems like horizontal and vertical axis wind turbines. Various forms of flexible structures have been proposed and tested over years and found to be comparable to conventional systems on an energy density basis. These harvesters often rely on instability of the fluid-structure coupled system at increasing flow velocities. Thus, the design of these harvesters requires an understanding of the complex fluid-structure interaction inherent in them, which may include nonlinear effects. The inclusion of an electric circuit to scavenge the vibratory energy further transforms it into a three-way coupling problem. Despite laboratory scale verification of the potential of these systems, practical deployment has been deterred by the fluctuating nature of the natural fluid flows. Recent researches have sought to develop adaptive harvesters for such scenarios. Some progress has also been made in exploiting the spatio-temporal flow fluctuations beneficially for enhancing harvested power. This chapter summarizes the state-of-the-art in this regard and classifies the various approaches to tackling flow fluctuations.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

previous chapter Nonlinear Dynamics of Circular Cylinders Undergoing Vortex Induced Vibrations in Presence of Stochastic Noise

next chapter Syngas Combustion Dynamics in a Bluff-Body Turbulent Combustor

Abdelkefi A (2016) Aeroelastic energy harvesting: a review. Int J Eng Sci 100:112–135CrossRef

Abdelkefi A, Ghommem M (2013) Piezoelectric energy harvesting from morphing wing motions for micro air vehicles. Theor Appl Mech Lett 3(5):052004

Abdelkefi A, Hasanyan A, Montgomery J, Hall D, Hajj MR (2014) Incident flow effects on the performance of piezoelectric energy harvesters from galloping vibrations. Theor Appl Mech Lett 4(2):022002

Adhikari S, Friswell MI, Inman DJ (2009) Piezoelectric energy harvesting from broadband random vibrations. Smart Mater Struct 18(11):115005CrossRef

Akaydın HD, Elvin N, Andreopoulos Y (2010) Wake of a cylinder: a paradigm for energy harvesting with piezoelectric materials. Exp Fluids 49(1):291–304

Akaydın HD, Elvin N, Andreopoulos Y (2013) Flow-induced vibrations for piezoelectric energy harvesting. In: Advances in energy harvesting methods. Springer, Berlin, pp 241–267

Allen JJ, Smits AJ (2001) Energy harvesting eel. J Fluids Struct 15(3–4):629–640CrossRef

Andreopoulos Y, Danesh-Yazdi AH, Goushcha O, Elvin N (2015) The effects of turbulence length scale on the performance of piezoelectric harvesters. In: ASME (Oct. 2015), p V002T22A005

Anton SR, Inman DJ (2008) Vibration energy harvesting for unmanned aerial vehicles. In: The 15th international symposium on: smart structures and materials and nondestructive evaluation and health monitoring. International Society for Optics and Photonics, pp 692824–692824

Bibo A, Li G, Daqaq MF (2011) Electromechanical modeling and normal form analysis of an aeroelastic micro-power generator. J Intell Mater Syst Struct 22(6):577–592

Bonnin V, Bénard E, Moschetta J-M, Toomer CA (2015) Energy-harvesting mechanisms for uav flight by dynamic soaring. Int J Micro Air Veh 7(3):213–229

Bruni C, Cestino E, Frulla G, Marzocca P (2014) Development of an aeroelastic wing model with piezoelectric elements for gust load alleviation and energy harvesting. In: ASME 2014 international mechanical engineering congress and exposition. American Society of Mechanical Engineers, pp V001T01A057–V001T01A057

Bryant M, Garcia E (2011) Modeling and testing of a novel aeroelastic flutter energy harvester. J Vib Acoustics 133(1):011010

Bryant M, Mahtani RL, Garcia E (2012) Wake synergies enhance performance in aeroelastic vibration energy harvesting. J Intell Mater Syst Struct 23(10):1131–1141

Chen Y, Zhan J, Wu J, Wu J (2017) A fully-activated flapping foil in wind gust: energy harvesting performance investigation. Ocean Eng 138:112–122

Claudia B, James G, Giacomo F, Enrico C, Pier M (2017) Energy harvesting from aeroelastic vibrations induced by discrete gust loads. J Intell Mater Syst Struct 28(1):47–62CrossRef

Cutler M, McLain T, Beard R, Capozzi B (2010) Energy harvesting and mission effectiveness for small unmanned aircraft. In: AIAA guidance, navigation, and control conference, p 8037

Daqaq MF (2012) On intentional introduction of stiffness nonlinearities for energy harvesting under white gaussian excitations. Nonlinear Dyn 69(3):1063–1079

Erturk A, Inman DJ (2008) A distributed parameter electromechanical model for cantilevered piezoelectric energy harvesters. J Vib Acoustics 130(4):041002

Fei F, Mai JD, Li WJ (2012) A wind-flutter energy converter for powering wireless sensors. Sens Actuators A: Phys 173(1):163–171

Gavrilovic N, Benard E, Pastor P, Moschetta JM (2017) Performance improvement of small unmanned aerial vehicles through gust energy harvesting. J Aircraft 55(2):741–754

Gavrilovic N, Bronz M, Moschetta J-M, Benard E (2019) Bioinspired energy harvesting from atmospheric phenomena for small unmanned aerial vehicles. In: AIAA Scitech 2019 Forum, p 0570

Gavrilovic N, Mohamed A, Marino M, Watkins S, Moschetta J-M, Bénard E (2018) Avian-inspired energy-harvesting from atmospheric phenomena for small uavs. Bioinspiration Biomimetics 14(1):016006

Goushcha O, Akaydin HD, Elvin N, Andreopoulos Y (2015) Energy harvesting prospects in turbulent boundary layers by using piezoelectric transduction. J Fluids Struct 54:823–847CrossRef

He Q, Daqaq MF (2014) Influence of potential function asymmetries on the performance of nonlinear energy harvesters under white noise. In: ASME 2014 international design engineering technical conferences and computers and information in engineering conference. American Society of Mechanical Engineers, pp V006T10A060–V006T10A060

Hobeck JD, Inman DJ (2012) Artificial piezoelectric grass for energy harvesting from turbulence-induced vibration. Smart Mater Struct 21(10):105024CrossRef

Hoblit FM (1988) Gust loads on aircraft: concepts and applications. American Institute of Aeronautics and Astronautics

Jamshidi S, Dardel M, Pashaei MH, Alashti RA (2015) Energy harvesting from limit cycle oscillation of a cantilever plate in low subsonic flow by ionic polymer metal composite. Proc Inst Mech Eng Part G: J Aeros Eng 229(5):814–836

Jinwu X, Yining W, Daochun L (2015) Energy harvesting from the discrete gust response of a piezoaeroelastic wing: modeling and performance evaluation. J Sound Vib 343:176–193CrossRef

Jones KD, Davids ST, Platzer MF (1999) Oscillating-wing power generation. In: 3rd ASME/JSME joint fluids engineering conference. San Francisco, CA

Katzmayr R (1922) Effect of periodic changes of angle of attack on behavior of airfoils

Kim I-H, Jung H-J, Lee BM, Jang SJ (2011) Broadband energy-harvesting using a two degree-of-freedom vibrating body. Appl Phys Lett 98(21):214102

Kumar SK, Bose C, Ali SF, Sarkar S, Gupta S (2017) Investigations on a vortex induced vibration based energy harvester. Appl Phys Lett 111(24):243903

Kwuimy CAK, Litak G, Borowiec M, Nataraj C (2012) Performance of a piezoelectric energy harvester driven by air flow. Appl Phys Lett 100(2):024103

Langelaan JW (2009) Gust energy extraction for mini and micro uninhabited aerial vehicles. J Guid Control Dyn 32(2):464–473

Lau YL, So RMC, Leung RCK (2004) Flow-induced vibration of elastic slender structures in a cylinder wake. J Fluids Struct 19(8):1061–1083CrossRef

Lundström D, Krus P (2012) Testing of atmospheric turbulence effects on the performance of micro air vehicles. Int J Micro Air Veh 4(2):133–149

McCarthy JM, Watkins S, Deivasigamani A, John SJ, Coman F (2015) An investigation of fluttering piezoelectric energy harvesters in off-axis and turbulent flows. J Wind Eng Ind Aerodyn 136:101–113CrossRef

McKinney W, DeLaurier J (1981) Wingmill: an oscillating-wing windmill. J Energy 5(2):109–115

Mehmood A, Abdelkefi A, Hajj MR, Nayfeh AH, Akhtar I, Nuhait AO (2013) Piezoelectric energy harvesting from vortex-induced vibrations of circular cylinder. J Sound Vib 332(19):4656–4667CrossRef

Naudascher E, Rockwell D (2012) Flow-induced vibrations: an engineering guide. Courier Corporation

Onoue K, Song A, Strom BW, Breuer KS (2014) Cyber-physical energy harvesting through flow-induced oscillations of a rectangular plate. In: 32nd ASME wind energy symposium, p 0712

Park G, Rosing T, Todd MD, Farrar CR, Hodgkiss W (2008) Energy harvesting for structural health monitoring sensor networks. J Infrastruct Syst 14(1):64–79

Pellegrini SP, Tolou N, Schenk M, Herder JL (2013) Bistable vibration energy harvesters: a review. J Intell Mater Syst Struct 24(11):1303–1312

Peng Z, Zhu Q (2009) Energy harvesting through flow-induced oscillations of a foil. Phys Fluids 21(12):123602

Phillips WH (1975) Propulsive effects due to flight through turbulence. J Aircraft 12(7):624–626

Pobering S, Schwesinger N (2004) A novel hydropower harvesting device. In: 2004 international conference on MEMS, NANO and smart systems (ICMENS’04). IEEE, pp 480–485

Poirel DC, Price SJ (1997) Post-instability behavior of a structurally nonlinear airfoil in longitudinal turbulence. J Aircraft 34(5):619–626

Pozzi M, Guo S, Zhu M (2012) Harvesting energy from the dynamic deformation of an aircraft wing under gust loading. In: Health monitoring of structural and biological systems 2012, vol 8348. International Society for Optics and Photonics, p 834831

Rice SO (1944) Mathematical analysis of random noise. Bell Syst Tech J 23(3):282–332

Samir C, Dario M, Guido M (2018) Modeling of pulsating incoming flow using vortex particle methods to investigate the performance of flutter-based energy harvesters. Comput Struct 209:130–149CrossRef

Shi S, New TH, Liu Y (2013) Flapping dynamics of a low aspect-ratio energy-harvesting membrane immersed in a square cylinder wake. Exp Thermal Fluid Sci 46:151–161

St. Clair D, Bibo A, Sennakesavababu VR, Daqaq MF, Li G (2010) A scalable concept for micropower generation using flow-induced self-excited oscillations. Appl Phys Lett 96(14):144103

Stanton SC, McGehee CC, Mann BP (2009) Reversible hysteresis for broadband magnetopiezoelastic energy harvesting. Appl Phys Lett 95(17):174103

Stephen NG (2006) On energy harvesting from ambient vibration. J Sound Vib 293(1–2):409–425

Tang L, Païdoussis MP, Jiang J (2009) Cantilevered flexible plates in axial flow: energy transfer and the concept of flutter-mill. J Sound Vib 326(1):263–276

Tang L, Yang Y, Soh CK (2010) Toward broadband vibration-based energy harvesting. J Intell Mater Syst Struct 21(18):1867–1897

Taylor GW, Burns JR, Kammann SA, Powers WB, Welsh TR (2001) The energy harvesting eel: a small subsurface ocean/river power generator. IEEE J Oceanic Eng 26(4):539–547

Taylor J (1965) Manual on aircraft loads. Technical report, advisory group for aeronautical research and development Paris (France)

Wang Y, Inman DJ (2013a) Simultaneous energy harvesting and gust alleviation for a multifunctional composite wing spar using reduced energy control via piezoceramics. J Compos Mater 47(1):125–146

Wang Y, Inman DJ (2013b) Experimental validation for a multifunctional wing spar with sensing, harvesting, and gust alleviation capabilities. IEEE/ASME Trans Mechatron 18(4):1289–1299

Williams CB, Yates RB (1996) Analysis of a micro-electric generator for microsystems. Sens Actuators A: Phys 52(1–3):8–11

Xiao Q, Zhu Q (2014) A review on flow energy harvesters based on flapping foils. J Fluids Struct 46:174–191

Young J, Lai JCS, Platzer MF (2014) A review of progress and challenges in flapping foil power generation. Prog Aerosp Sci 67:2–28

Zhu Q (2012) Energy harvesting by a purely passive flapping foil from shear flows. J Fluids Struct 34:157–169

Zhu Q, Peng Z (2009) Mode coupling and flow energy harvesting by a flapping foil. Phys Fluids 21(3):033601

Title: Vibration Energy Harvesting in Fluctuating Fluid Flows
Authors: S. Krishna Kumar
Sunetra Sarkar
Sayan Gupta
Publisher: Springer Singapore
Book: Dynamics and Control of Energy Systems
Print ISBN: 978-981-15-0535-5

Electronic ISBN: 978-981-15-0536-2

Copyright Year: 2020
DOI: https://doi.org/10.1007/978-981-15-0536-2_10