Implement a wireless electric energy transmission system through the magnetic resonant coupling of the near field for low-power consumption devices

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Jaime Rodrigo Vinueza Coba
Monica Alexandra Mayorga Arias
Monica Andrea Zabala Haro
Fabricio Javier Santacruz Sulca
Jefferson Alexander Ribadeneira Ramirez

Abstract

This paper proposes an alternative wireless power supply method for low-power consumption devices. For the design of the antennas responsible for the transmission of energy, microstrip lines were used on an FR4 substrate (Flame Retardant 4) based on mathematical methods tested from other research contributions. Therefore, integrated circuits with MMIC (Monolithic Microwave Integrated Circuits) technology are included for generating radio-frequency as an energy source from 16 MHz to 23 MHz. In the reception phase, a three-stage doubling voltage circuit is required to rectify and amplify the transmitted signal. The results of the implementation of the system indicate an efficiency between 20% and 30% for transmission distances up to 90 millimeters without obstacles. The performance decreases between 0% and 6.67% when crossing materials such as agglomerate, plastic, glass, expanded polystyrene, fabric, and wood. However, it loses performance with metal.

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How to Cite
Implement a wireless electric energy transmission system through the magnetic resonant coupling of the near field for low-power consumption devices. (2018). MASKAY, 8(1), 35-45. https://doi.org/10.24133/maskay.v8i1.598
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TECHNICAL PAPERS

How to Cite

Implement a wireless electric energy transmission system through the magnetic resonant coupling of the near field for low-power consumption devices. (2018). MASKAY, 8(1), 35-45. https://doi.org/10.24133/maskay.v8i1.598

References

[1] Naoki Shinohara. (2014). Wireless Power Transfer via Radiowaves. Wiley

[2] Agbinya, J.I. (2012). Wireless Power Transfer. River Publishers

[3] A. Munir, and B. T. Ranum, (2015), “Wireless Power Charging System for Mobile Device Based on Magnetic Resonance Coupling”, in Proc. of the 5th International Conference on Electrical Engineering and Informatics, Aug. 10-11, Bali, Indonesia, pp. 221-224.

[4] J. Zhang and Z. Jia, (Dec. 2010), “Design of Voltage Doubling Rectifier Circuit in Wireless Sensor Networks,” in Proceeding of International Conference on PIC, Sanghai, China, pp. 456 – 459.

[5] A. K. André Kurs, R. Moffat, J. D. Joannopoulos, P. Fisher, M. Soljiac (2007) “Wireless Power Transfer via Strongly Coupled Magnetic Resonances”, Science AAAs. 83 – 85.

[6] F. Pelliteri, V. Boscaino, R. L. Rosa, and G. Capponi, (2012), “Improving the Efficiency of a Standard Compliant Wireless Battery Charger,” in Universities Power Engineering Conference (UPEC), 2012 47th International, pp. 1 – 6.

[7] M. Kline, I. Izyumin, B. Boser, and S. Sanders, (2011), “Capacitive Power Transfer for Contactless Charging,” in Applied Power Electronics Conference and Exposition (APEC), 2011 Twenty – Sixth Annual IEEE, pp. 1398 – 1404.

[8] X. Lu, P. Wang, D. Niyato, D. I. Kim and Z. Han, (2016), "Wireless Charging Technologies: Fundamentals, Standards, and Network Applications," in IEEE Communications Surveys & Tutorials, vol. 18, no. 2, pp. 1413-1452.

[9] R. M. Dickinson, (1976), “Performance of a high-power, 2.388-GHz receiving array in wireless power transmission over 1.54 km”, in Proceeding of IEEE-MTT-S International Microwave Symposium (IMS), Chery Hill, USA, Jun, pp. 139 – 141.

[10] M. H. M. Salleh, N. Seman, and D. N. A. Zaidel, (2014), “Design of a Compact Planar Witricity Device with Good Efficiency for Wireless Applications”, Proceedings of Asia – Pacific Microwave Conference, pp. 1369 – 1371.

[11] H. M. G. E. D. M. El-Anzeery, M. A. E. A. S. El-Bagouri, and R. Guindi, (2012), “Novel Radio Frequency Energy Harvesting Model,” in Power Engineering and Optimization Conference (PEDCO), Melaka, Malaysia, 2012 IEEE International, pp. 209 – 213.

[12] M. H. M. Salleh, N. Seman, and R. Dewan, “Reduced – Size Witricity Charger Design and its Parametric Study,” IEEE International RF and Microwave Conference (RFM2013), Dec. 09 – 11, Penang, Malaysia, pp. 387 – 390.

[13] S. L. Ho, J. Wang, W. N. Fu, M. Sun, “A Comparative Study Between Witricity and Traditional Inductive Magnetic Coupling in Wireless Charging,” IEEE Transactions onMagnetics, vol. 47, no. 5, pp. 1522 – 1525, May. 2011.

[14] X. Zhang, S. LHo., W.N. Fu, (2011), “Quantitative Analysis of a Wireless Power Transfer Cell with Planar Spiral Structures,” IEEE Transactions on Magnetics, vol. 47, no. 10, pp. 3200-3203.

[15] B. T. Ranum, N. W. D. E. Rahayu, and A. Munir, “Characterization of Wireless Power Charging Receiver for Mobile Device,” International Journal of Electrical Engineering and Informatics , vol. 7, no. 1, pp. 130 – 139, Mar. 2015.

[16] D.G.Nottiani, F.Leccese, (2012), “A Simple Method for Calculating Lumped Parameters of Planar Spiral Coil for Wireless Energy Transfer,”11th International Conference on Environment and Electrical Engineering (EEEIC), vol., no., pp. 869 – 872.

[17] J. Wang, S.L. HO, W.N. Fu, M. Sun, (2010), “Finite Element Analysis and Corresponding Experiment of Resonant Energy Transmission for Wireless Transmission Device using Witricity,” 14th Biennial IEEE Conference onElectromagnetic Field Computation (CEFC), on, vol., no., pp. 1,1.

[18] J. Wang, S.L.Ho, W.N. Fu, M. Sun, (October 2011), “ Analytical Design Study of a Novel Witricity Charger with Lateral and Angular Misalignments for Efficient Wireless Energy Transmission,” IEEE Transactions onMagnetics, vol.47, no.10, pp. 2616-2619.

[19] W. Peng, G. Zhao, (2012), “Experimental Analysis on Wireless Power Transmission Based on Magnetic Resonant Coupling,” 2nd International Conference onRemote Sensing, Environment and Transportation Engineering (RSETE), vol., no., pp. 1,4.

[20] N.W.D.E.Rahayu, A. Munir, (August 2014), “Radiator for Wireless Charging Application Based on Electromagnetic Coupling Resonant ,”Proceeding of International Conference on Electrical Engineering, Computer Science and Informatics (EECSI 2014), Yogyakarta, Indonesia, pp. 496 – 499, 20-21.

[21] H.Zhou, S.Yang, (2012), “Resonant Frequency Calculation of Witricity Using equivalent Circuit Model Combined with Finite Element Method,” International Conference on Electromagnetic Field Problems and Applications (ICEF), 2012 Sixth, vol., no., pp.1,4.

[22] F. Zhang, S.A. Hackwoth, X. Liu, C. Li, M. Sun, (2010), “Wireless Power Delivery for Wearable Sensors and Implants in Body Sensor Networks,” Annual International Conference of the IEEE onEngineering in Medicine and Biology Society (EMBC), vol., no., pp. 692,695.

[23] X. Sun, M. Cao, J. Hao, Y. Guo, (2012), “A Rectangular Slot Antenna with Improved Bandwidth,” AEU – International Journal of Electronics and Communications, vol. 66, pp.465-466,6.

[24] Xiu Zhang, S. L. Ho and W. N. Fu, (2010), "Modeling and design of a wireless power transfer cell with planar spiral structures," Digests of the 2010 14th Biennial IEEE Conference on Electromagnetic Field Computation, Chicago, IL, pp. 1-1.

[25] Martin Dadić, Karlo Petrović, Roman Malarić, (2017), “FEM Analysis of a PCB Integrated Resonant Wireless Power Transfer,” 40th International Convention on Information and Communication Technology, Electronics and Microelectronics (MIPRO), Opatija, pp. 166-170.

[26] Johnson I. (2011). Agbinya. Principles of Inductive Near Field Communications for Internet of Things. River Publishers

[27] Iulian Rosu (2014), Microstrip, Stripline, and CPW Design

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