Modeling and Experimental Characterization of an Electromagnetic Energy Harvester for Wearable and Biomedical Applications

Digregorio, Gabriel; Pierre, Hervé; Laurent, Philippe; Redouté, Jean-Michel

doi:10.1109/ACCESS.2020.3023195

Article (Scientific journals)

Modeling and Experimental Characterization of an Electromagnetic Energy Harvester for Wearable and Biomedical Applications

Digregorio, Gabriel; Pierre, Hervé; Laurent, Philippe et al.

2020 • In IEEE Access

Peer Reviewed verified by ORBi

Permalink
https://hdl.handle.net/2268/251167

DOI
10.1109/ACCESS.2020.3023195

Files (2)Send to Details Statistics Bibliography Similar publications

Files

Full Text

09194233.pdf

Publisher postprint (2.03 MB)

Download

Annexes

IEEE_Access_Digregorio2020_Video.rar

Publisher postprint (87.9 MB)

Request a copy

All documents in ORBi are protected by a user license.

Send to

RIS BibTex APA Chicago Permalink X Linkedin

Details

Keywords :

electromagnetic energy harvesters; energy harvesting characterization; finite element analysis; magnetic force; two degrees of freedom; eddy currents; Axisymmetrical geometry; Wearable; Biomedical

Abstract :

[en] This work presents the modeling and the experimental validation of a linear electromagnetic energy harvester (EMEH) actuated by random low-g external acceleration or by a very slow imposed movement. By combining these two different ways of energy scavenging, the system is particularly suited for powering wearable and biomedical electronic devices where the human-motion and movement can be considered as random and non predictable. The design is composed of a mobile stack of head-to-head ring-shaped permanent magnets in which a fixed wounded ferromagnetic core, composed of two coils, is located. A custom co-simulation is presented: a finite element analysis (FEA) and a one dimension (1D) two degrees of freedom (2DOF) system model. The FEA is used to optimize the geometry of the EMEH and its form factor, allowing an significative down-scaling. The 1D 2DOF model describes the dynamics of the EMEH in its real environment by considering all the leading mechanical and electrical parameters. The geometry can drastically change the behavior of the system as well as its dynamics: the goal of this double structure is to reduce the magnetic force exerted between the fixed part and the moving part while keeping the magnetic flux gradient in each coil as large as possible. This force was characterized experimentally by using a custom designed test bench, to validate the FEA results. It was observed that the maximum produced energy is reached when the system sweeps across different equilibrium positions rather than oscillating around a given stable position. The second degree of freedom helps the system to settle in a large number of equilibrium positions when submitted to random external accelerations and therefore broadens the frequency response of the EH. Results show a theoretical electrical power output (RMS) of 2 mW for a 10 cm² cylindrical harvester submitted to a short external acceleration pulse of 27.5 m/s².

Disciplines :

Electrical & electronics engineering

Author, co-author :

Digregorio, Gabriel ; Université de Liège - ULiège > Dép. d'électric., électron. et informat. (Inst.Montefiore) > Systèmes microélectroniques intégrés

Pierre, Hervé ; Université de Liège - ULiège > Dép. d'électric., électron. et informat. (Inst.Montefiore) > Systèmes microélectroniques intégrés

Laurent, Philippe ; Université de Liège - ULiège > Dép. d'électric., électron. et informat. (Inst.Montefiore) > Systèmes microélectroniques intégrés

Redouté, Jean-Michel ; Université de Liège - ULiège > Dép. d'électric., électron. et informat. (Inst.Montefiore) > Systèmes microélectroniques intégrés

Language :

English

Title :

Modeling and Experimental Characterization of an Electromagnetic Energy Harvester for Wearable and Biomedical Applications

Alternative titles :

[en] Belgium

Publication date :

10 September 2020

Journal title :

IEEE Access

ISSN :

2169-3536

Publisher :

Institute of Electrical and Electronics Engineers, United States - New Jersey

Peer reviewed :

Peer Reviewed verified by ORBi

Additional URL :

https://ieeexplore.ieee.org/document/9194233

Commentary :

Open Access Paper.

Available on ORBi :

since 29 September 2020

Statistics

Number of views

158 (49 by ULiège)

Number of downloads

246 (25 by ULiège)

More statistics

Scopus citations^®

Scopus citations^®
without self-citations

OpenCitations

Bibliography

J. H. Kim, Y. J. Shin, Y. D. Chun, and J. H. Kim, ''Design of 100W regenerative vehicle suspension to harvest energy from road surfaces,'' Int. J. Precis. Eng. Manuf., vol. 19, no. 7, pp. 1089-1096, Jul. 2018.
H.-J. Jung, I.-H. Kim, and S.-J. Jang, ''An energy harvesting system using the wind-induced vibration of a stay cable for powering a wireless sensor node,'' Smart Mater. Struct., vol. 20, no. 7, Jul. 2011, Art. no. 075001.
W. Li, K. T. Chau, and J. Z. Jiang, ''Application of linear magnetic gears for Pseudo-Direct-Drive oceanic wave energy harvesting,'' IEEE Trans. Magn., vol. 47, no. 10, pp. 2624-2627, Oct. 2011.
P. D. Mitcheson, E. M. Yeatman, G. K. Rao, A. S. Holmes, and T. C. Green, ''Energy harvesting from human and machine motion for wireless electronic devices,'' Proc. IEEE, vol. 96, no. 9, pp. 1457-1486, Sep. 2008.
G. Colson, P. Laurent, P. Bellier, S. Stoukatch, F. Dupont, and M. Kraft, ''Smart-shoe self-powered by walking,'' in Proc. IEEE 14th Int. Conf. Wearable Implant. Body Sensor Netw. (BSN), May 2017, pp. 35-38.
H. C. Baelhadj, S. S. Adhikari, H. Davoodi, V. Badilita, and M. I. Beyaz, ''A sub-cm3 energy harvester for in-vivo biosensors,'' Microelectron. Eng., vol. 226, Apr. 2020, Art. no. 111288.
M. Geisler, S. Boisseau, M. Perez, P. Gasnier, J. Willemin, I. Ait-Ali, and S. Perraud, ''Human-motion energy harvester for autonomous body area sensors,'' Smart Mater. Struct., vol. 26, no. 3, Feb. 2017, Art. no. 035028.
N. G. Elvin and A. A. Elvin, ''Vibrational energy harvesting from human gait,'' IEEE/ASME Trans. Mechatronics, vol. 18, no. 2, pp. 637-644, Apr. 2013.
A. Zurbuchen, A. Haeberlin, A. Pfenniger, L. Bereuter, J. Schaerer, F. Jutzi, C. Huber, J. Fuhrer, and R. Vogel, ''Towards batteryless cardiac implantable electronic devices-The swiss way,'' IEEE Trans. Biomed. Circuits Syst., vol. 11, no. 1, pp. 78-86, Feb. 2017.
A. Nasiri, S. A. Zabalawi, and D. C. Jeutter, ''A linear permanent magnet generator for powering implanted electronic devices,'' IEEE Trans. Power Electron., vol. 26, no. 1, pp. 192-199, Jan. 2011.
X. Tang, X. Wang, R. Cattley, F. Gu, and A. Ball, ''Energy harvesting technologies for achieving self-powered wireless sensor networks in machine condition monitoring: A review,'' Sensors, vol. 18, no. 12, p. 4113, Nov. 2018.
X. Huang, L. Wang, H. Wang, B. Zhang, X. Wang, R. Y. Stening, X. Sheng, and L. Yin, ''Materials strategies and device architectures of emerging power supply devices for implantable bioelectronics,'' Small, vol. 16, no. 15, Apr. 2020, Art. no. 1902827.
S. Kumari, S. S. Sahu, B. Gupta, and S. K. Mishra, ''Energy harvesting via human body activities,'' in Smart Biosensors in Medical Care. Amsterdam, The Netherlands: Elsevier, 2020, pp. 87-106.
Q. Guo, M. Sun, H. Liu, X. Ma, Z. Chen, T. Chen, and L. Sun, ''Design and experiment of an electromagnetic ocean wave energy harvesting device,'' in Proc. IEEE/ASME Int. Conf. Adv. Intell. Mechatronics (AIM), Jul. 2018, pp. 381-384.
J.-M. Kim, M.-M. Koo, J.-H. Jeong, K. Hong, I.-H. Cho, and J.-Y. Choi, ''Design and analysis of tubular permanent magnet linear generator for small-scale wave energy converter,'' AIP Adv., vol. 7, no. 5, May 2017, Art. no. 056630.
I. Stamenkovic, N. Milivojevic, C. Zheng, and A. Khaligh, ''Three phase linear permanent magnet energy scavenger based on foot horizontal motion,'' in Proc. 25th Annu. IEEE Appl. Power Electron. Conf. Expo. (APEC), Feb. 2010, pp. 2245-2250.
S.-D. Kwon, J. Park, and K. Law, ''Electromagnetic energy harvester with repulsively stacked multilayer magnets for low frequency vibrations,'' Smart Mater. Struct., vol. 22, no. 5, May 2013, Art. no. 055007.
C. Wei and X. Jing, ''A comprehensive review on vibration energy harvesting: Modelling and realization,'' Renew. Sustain. Energy Rev., vol. 74, pp. 1-18, Jul. 2017.
Y. Zhang, T. Wang, A. Luo, Y. Hu, X. Li, and F. Wang, ''Micro electrostatic energy harvester with both broad bandwidth and high normalized power density,'' Appl. Energy, vol. 212, pp. 362-371, Feb. 2018.
C. Cepnik, O. Radler, S. Rosenbaum, T. Ströhla, and U. Wallrabe, ''Effective optimization of electromagnetic energy harvesters through direct computation of the electromagnetic coupling,'' Sens. Actuators A, Phys., vol. 167, no. 2, pp. 416-421, Jun. 2011.
L. Zuo, B. Scully, J. Shestani, and Y. Zhou, ''Design and characterization of an electromagnetic energy harvester for vehicle suspensions,'' Smart Mater. Struct., vol. 19, no. 4, Apr. 2010, Art. no. 045003.
C. Blache and G. Lamarquand, ''New structures for linear displacement sensor with high magnetic field gradient,'' IEEE Trans. Magn., vol. 28, no. 5, pp. 2196-2198, Sep. 1992.
M. Duffy and D. Carroll, ''Electromagnetic generators for power harvesting,'' in Proc. 35th Annu. IEEE Power Electron. Spec. Conf., Jun. 2004, pp. 2075-2081.
M. Gao, Y. Wang, Y. Wang, and P. Wang, ''Experimental investigation of non-linear multi-stable electromagnetic-induction energy harvesting mechanism by magnetic levitation oscillation,'' Appl. Energy, vol. 220, pp. 856-875, Jun. 2018.
H. Nguyen and H. Bardaweel, ''Multi-stable magnetic spring-based energy harvester subjected to harmonic excitation: Comparative study and experimental evaluation,'' in Proc. Int. Mech. Eng. Congr. Expo. IMECE, Nov. 2018, Paper IMECE2018-86157, V04BT06A038. [Online]. Available: https://proceedings.asmedigitalcollection.asme.org
Z. Wu, R. L. Harne, and K. W. Wang, ''Energy harvester synthesis via coupled linear-bistable system with multistable dynamics,'' J. Appl. Mech., vol. 81, no. 6, Jun. 2014, Art. no. 061005.
A. Cammarano, S. G. Burrow, and D. A. W. Barton, ''Modelling and experimental characterization of an energy harvester with bi-stable compliance characteristics,'' Proc. Inst. Mech. Eng., I, J. Syst. Control Eng., vol. 225, no. 4, pp. 475-484, Jun. 2011.
W. S. N. Trimmer, ''Microrobots and micromechanical systems,'' Sensors Actuators, vol. 19, pp. 267-287, 1989, doi: 10.1109/97804705 45263.sect1.
A. Zurbuchen, A. Haeberlin, L. Bereuter, A. Pfenniger, S. Bosshard, M. Kernen, P. P. Heinisch, J. Fuhrer, and R. Vogel, ''Endocardial energy harvesting by electromagnetic induction,'' IEEE Trans. Biomed. Eng., vol. 65, no. 2, pp. 424-430, Feb. 2018.
Z. Wang, C. Huber, J. Hu, J. He, D. Suess, and S. X. Wang, ''An electrodynamic energy harvester with a 3D printed magnet and optimized topology,'' Appl. Phys. Lett., vol. 114, no. 1, Jan. 2019, Art. no. 013902.
K. Fan, Y. Zhang, H. Liu, M. Cai, and Q. Tan, ''A nonlinear two-degree-of-freedom electromagnetic energy harvester for ultra-low frequency vibrations and human body motions,'' Renew. Energy, vol. 138, pp. 292-302, Aug. 2019.
G. Aldawood, H. T. Nguyen, and H. Bardaweel, ''High power density spring-assisted nonlinear electromagnetic vibration energy harvester for low base-accelerations,'' Appl. Energy, vol. 253, Nov. 2019, Art. no. 113546.
C. Li, S. Wu, P. C. K. Luk, M. Gu, and Z. Jiao, ''Enhanced bandwidth nonlinear resonance electromagnetic human motion energy harvester using magnetic springs and ferrofluid,'' IEEE/ASME Trans. Mechatronics, vol. 24, no. 2, pp. 710-717, Apr. 2019.
Y. M. Choi, M. G. Lee, and Y. Jeon, ''Wearable biomechanical energy harvesting technologies,'' Energies, vol. 10, no. 10, p. 1483, Oct. 2017.
K. Ylli, D. Hoffmann, A. Willmann, P. Becker, B. Folkmer, and Y. Manoli, ''Energy harvesting from human motion: Exploiting swing and shock excitations,'' Smart Mater. Struct., vol. 24, no. 2, Feb. 2015, Art. no. 025029.
S. P. Beeby, M. J. Tudor, and N. M. White, ''Energy harvesting vibration sources for microsystems applications,'' Meas. Sci. Technol., vol. 17, no. 12, pp. R175-R195, Dec. 2006.
A. A. Kolyshkin. (2013). Solution of Direct Eddy Current Problems with Cylindrical Symmetry. [Online]. Available: http://www.ndt.net/?id=16121
G. Sinha and S. S. Prabhu, ''Analytical model for estimation of eddy current and power loss in conducting plate and its application,'' Phys. Rev. Special Topics Accel. Beams, vol. 14, no. 6, Jun. 2011, Art. no. 062401.
K. Weise, M. Carlstedt, M. Ziolkowski, H. Brauer, and H. Toepfer, ''Lorentz force on permanent magnet rings by moving electrical conductors,'' IEEE Trans. Magn., vol. 51, no. 12, pp. 1-11, Dec. 2015.
D. F. Berdy, D. J. Valentino, and D. Peroulis, ''Kinetic energy harvesting from human walking and running using a magnetic levitation energy harvester,'' Sens. Actuators A, Phys., vol. 222, pp. 262-271, Feb. 2015.
J. Kravčák, ''Optimization of magnetic flux in electromagnetic vibrating generators,'' Trans Motauto World, vol. 2, no. 1, pp. 3-4, 2017.
P. Dular and C. Geuzaine. GetDP Reference Manual: The Documentation for GetDP, a General Environment for the Treatment of Discrete Problems. Accessed: Mar. 2019. [Online]. Available: http://getdp.info
D. Leith, ''Drag on nonspherical objects,'' Aerosol Sci. Technol., vol. 6, no. 2, pp. 153-161, Jan. 1987.
B. Ebrahimi, M. B. Khamesee, and F. Golnaraghi, ''Eddy current damper feasibility in automobile suspension: Modeling, simulation and testing,'' Smart Mater. Struct., vol. 18, no. 1, Jan. 2009, Art. no. 015017.