Stable ionistor battery for communication systems

STUDY OF TECHNOLOGICAL POSSIBILITIES OF CREATING IONISTOR BATTERIES TO ENSURE THE TRANSCEIVER SYSTEMS OPERATION STABILITY

Denis R. Ivanov, Ilya M. Lerner, Sergey V. Spiridonov,
Department of Nanotechnology in Electronics,
Kazan National Research Technical University named after A.N. Tupolev-KAI, KNRTU-KAI, Kazan, Russian Federation;
German-Russian Institute of Advanced Technologies (GRIAT), aviap@mail.ru

DOI: 10.36724/2664-066X-2020-6-4-11-17

SYNCHROINFO JOURNAL. Volume 6, Number 4 (2020). P. 11-17.

Abstract

The article describes a stable ionistor battery for infocommunication systems creating procedure. Based on a comparative analysis, the most balanced in terms of electrical characteristics, processability and availability components were selected. Using vacuum thermal resistive spraying, electrodes with a nanostructured carbon coating were manufacturedd. For this method, a structure with a high specific surface area obtaining technology has been formulated. Using two assembly methods, a cell of a stable ionistor battery has been built. It is possible to fully evaluate the physical and operational characteristics of the obtained ionistor batteries during long-term tests.

Keywords: ionistor, structured carbon coating, supercapacitor, thermal vacuum resistive spraying.

References

[1] Wang S., Wei T., Qi Z. (2008) Supercapacitor energy storage technology and its application in renewable energy power generation system. Proceedings of ISES World Congress 2007,
Vol. I, pp. 2805-2809.

[2] Raza, W., et al.. (2018). Recent advancements in supercapacitor technology. Nano Energy, 52, pp.441–473.

[3] Moftah A., Al Shetiti A. (2015) Review of Supercapacitor Technology. Int. J. Comput. Sci. Electron. Eng. V. 3(3). pp. 226-231.

[4] Kötz, R. and Carlen, M. (2000). Principles and applications of electrochemical capacitors. Electrochimica Acta, 45(15–16), pp.2483–2498.

[5] Gautham Prasad, G., Shetty, N., Thakur, S., Rakshitha and Bommegowda, K.B. (2019). Supercapacitor technology and its applications: a review. IOP Conference Series: Materials Science and Engineering, 561, p. 012105.

[6]  Lewandowski, A. and Galinski, M. (2007). Practical and theoretical limits for electrochemical double-layer capacitors. Journal of Power Sources, 173(2), pp. 822-828.

[7] Tabarov, F.S. (2019). Obtaining and properties of fibrous carbon materials for supercapacitor electrodes. Ph.D. thesis in Engineering Science. 115 p.

[8] Vangari, M., Pryor, T. and Jiang, L. (2013). Supercapacitors: Review of Materials and Fabrication Methods. Journal of Energy Engineering, 139(2), pp. 72-79.

[9] Jónsson, E. (2019). Ionic liquids as electrolytes for energy storage applications – A modelling perspective. Energy Storage Materials, 25. pp. 827-835.

[10] Svarovskaya, N.A., Kolesnikov, I.M. and Vinokurov, V.A. (2017). Electrochemistry of electrolyte solutions [“Elektrohimiya rastvorov elektrolitov”]. Moscow: Publishing Center of the Russian State University of Oil and Gas (NRU) named after I.M. Gubkin,
66 p.

[11] Chaika, M.Y. (2012). The main types of separation materials in supercapacitors with non-aqueous electrolyte [“Osnovnye tipy separacionnyh materialov v superkondensatorah s nevodnym elektrolitom”]. Vestnik VGTU, 6, pp. 57-60.

[12] Popel, O.S., Tarasenko, A.B. and Kolomiets, Y.G. (2012). Electric energy storage devices for use in renewable energy power plants.[“ Nakopiteli elektricheskoj energii dlya ih ispol’zovaniya v energoustanovkah na vozobnovlyaemyh istochnikah energii”] Moscow: M.V. Lomonosov Moscow State University, p. 49.