Electron cyclotron converters of microwaves in wireless power transmission systems

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Abstract

A proposal to use special electron cyclotron devices as effective converters of electromagnetic waves into direct current in modern microwave systems for wireless transmission of electrical energy to the Earth via a microwave channel from solar space power plants located on board geostationary satellites is considered. Such converters are a product of domestic development, they can have a conversion efficiency of more than 80%, they are insensitive to overloads and are several orders of magnitude more economical than the well-known semiconductor rectennas (rectifying antennas). Semiconductor rectennas, assembled from a multitude of individual semiconductor diodes with a Schottky barrier, in the process of nonlinear conversion of microwaves, generate parasitic radiation that forms a powerful electromagnetic background, which seriously interferes with the stable operation of information systems of special and general civil communications. In addition, the cost of semiconductor rectennas is several orders of magnitude higher than that of electron-cyclotron converters with the same input microwave power. Due to the high compactness of the electronic converters, they can also be installed on an intermediate satellite platform in the stratosphere, receiving the energy of the Sun through a laser beam from a geostationary orbit and transmitting it to the Earth with practically no loss through the microwave channel. The possibilities of using electron cyclotron converters in ground-based systems for wireless energy transmission are also promising. Already the first electron cyclotron converters, created at the “Torii” enterprise according to the project of the Lomonosov Moscow State University, had an efficiency of over 60% at an input microwave power of 10 kW.

About the authors

Yury A. Pirogov

Lomonosov Moscow State University

Author for correspondence.
Email: yupi937@gmail.com

Professor of the Photonics and Microwave Physics Department of the Faculty of Physics of the MSU, Dr.Sci.(Phys. & Math.)

1 Leninskiye Gory, Moscow, 119991, Russian Federation

Gohar M. Kazaryan

Lomonosov Moscow State University

Email: yupi937@gmail.com

Associate Professor of the Photonics and Microwave Physics Department of the Faculty of Physics of the MSU, PhD (Phys. & Math.)

1 Leninskiye Gory, Moscow, 119991, Russian Federation

Vladimir L. Savvin

Lomonosov Moscow State University

Email: yupi937@gmail.com

Associate Professor of the Photonics and Microwave Physics Department of the Faculty of Physics of the MSU, PhD (Phys. & Math.)

1 Leninskiye Gory, Moscow, 119991, Russian Federation

References

  1. Mankins J. Special report: Space-based solar power. Inexhaustible energy from orbit. Ad Astra. 2008; 20(1):20–36.
  2. Didenko AN. SVCH-energetika: teoriya i praktika [Microwave energetics: theory and practice]. Moscow: Nauka Publ.; 2003. (In Russ.)
  3. Glaser PE. Power from the Sun: its future. Science. 1968;162(3856):857–861.
  4. Vanke VA, Lopukhin VM, Savvin VL. Sverhmaloshumyashchie usiliteli ciklotronnyh voln [Super-low noise amplifiers of cyclotron waves]. Physics-Uspekhi (Advances in Physical Sciences). 1969;99(4):545–572. (In Russ.)
  5. Vanke VA, Lopukhin VM, Savvin VL. Problems of the Sun Space Electrical Plants. Physics-Uspekhi (Advances in Physical Sciences). 1977;123(4):633–655. (In Russ.)
  6. Vanke VA. Transverse electron-beam waves for microwave electronics. Physics-Uspekhi (Advances in Physical Sciences). 2005;48(9):917–937.
  7. Grikhiles VA, Orlov PP, Popov LB. Solnechnaya kosmicheskaya energetika [Sun space energetics]. Moscow: Nauka Publ.; 1984. (In Russ.)
  8. Brown W. History of power transmission by radio waves. IEEE Transactions on Microwave Theory and Technique. 1984;MTT-32(9):1230–1242.
  9. McSpadden J, Fan L, Chang K. A high conversion efficiency 5.8 GHz rectenna. IEEE MTT-S International Microwave Symposium Digest. 1997;2:547–550.
  10. Nagatomo M, Sasaki S, Naruo Y, Vanke VA. Solar power systems (SPS) – investigations at the Institute of Space and Astronautical Science of Japan. Physics-Uspekhi (Advances in Physical Sciences). 1994;164(6):631–641.
  11. Vanke V, Savvin V. Cyclotron-wave converter for SPS energy transmisson system. Proc. SPS-91. Paris; 1991. p. 515–520.
  12. Vanke VA, Matsumoto H, Shinohara N. High power converter of microwaves into DC. Journal of Radioelectronics. 1999;9. Available from: http://jre.cplire.ru/jre/ sep99/1/text.html (accessed: 11.09.2020).
  13. Vanke VA. Cyclotron and synchronous oscillations and waves of the electron beam. General relations. Journal of Radio Electronics. 2002;1. Available from: http://jre.cplire.ru/jre/jan02/2/text_e.html (accessed: 11.09.2020).
  14. Bykovskiy SV, et al. Tsiklotronnyi preobrazovatel' SVCh-energii [Cyclotron converter of microwave energy]. Russian Patent No. 119691. 1999, October 27. (In Russ.)
  15. Matsumoto H, Vanke VA, Shinohara N. Microwave/D.C. cyclotron wave converter having decreased magnetic field. US Patent No. 6,507,152 B2. 2003, January 14.

Copyright (c) 2020 Pirogov Y.A., Kazaryan G.M., Savvin V.L.

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