G.B. Steganov1, Yu.A. Chudnovsky2, N.I. Alimov3, A.A. Skoptsov4

1-4 Mozhaysky Military Space Academy (Saint Petersburg, Russia)

In this paper, we consider the problem of maintaining the energy balance of the power supply system of the Earth remote sensing spacecraft in critical operating conditions with the most intense cyclogram of the spacecraft operation, the maximum state of degradation of energy sources and storage devices, as well as with the minimum time to replenish useful energy.The problem of maintaining balance is formulated as a problem of nonlinear mathematical programming with functional constraints.

Goal of the work is improving the efficiency and survivability of the remote sensing spacecraft and maintaining the energy balance of the power system in critical operating conditions by transferring the storage devices of the accumulating subsystem of the spacecraft to a given level of charge in the minimum charge time.

An algorithm for controlling the accelerated charge of the rechargeable battery with the analysis of the Nickel-hydrogen battery temperature and its time derivative is developed.in some cases, the rechargeable battery replenishment time was reduced by 12−20%. The proposed algorithm for maintaining the energy balance can be used to select the stages of the accumulating subsystem charge current and transition from the current stage to the next one in a minimum time, providing flexibility in managing the modes of electricity storage with the adaptation of the charging current profiles to changing critical operating conditions.

Steganov G.B., Chudnovsky Yu.A., Alimov N.I., Skoptsov A.A. Algorithm for maintaining the energy balance of the power supply system of the earth remote sensing spacecraft under critical operating conditions. Information-measuring and Control Systems. 2021. V. 26. № 3. P. 14−21. DOI: https://doi.org/10.18127/j20700814-202103-02 (in Russian)

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