volume | PIER Journals

Abstract

The paper presents a study of dynamic thermal processes in ultra-high-speed microgenerators power of 55 W with the rotational speed of 800,000 rpm for UAV. A large-scale study of current works devoted to this topic were done where the main shortcomings were identified. A mathematical description of heat exchange processes in microelectromechanical energy converters with a flight time of no more than 10 minutes was developed in a non-stationary formulation. A study of the thermal state of the microgenerator operating in a short-term mode without a special cooling system is conducted. An experimental study of the heating dynamics of its active parts is carried out using the method of physical analogies. On the basis of experimental studies, the FEMM model is verified. Afterwards, combined electromagnetic and thermal calculations of microgenerator are conducted.

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15. Ismagilov, F., V. Vavilov, I. Hairullin, and D. Gusakov, "High efficiency ultra-high speed microgenerator," Proceedings of IECON 2016 — 42nd Annual Conference of the IEEE Industrial Electronics Society, 1670-1674, 2016.

16. Ismagilov, F., V. Vavilov, V. Aiguzina, and V. Bekuzin, "Minimization of energy losses in ultrahigh- speed electrical rotating machines," ElektrotehnisKi Vestnik, Vol. 84, No. 1-2, 56-60, 2017.

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Dr. Flur Rashitovich Ismagilov

Dr. Viacheslav Vavilov

Mr. Denis Gusakov