Analysis and improvement of characteristics of power supply systems for the small space vehicle of the AIST-2 type
- 作者: Mordanov M.R.1, Safronov S.L.1
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隶属关系:
- Samara National Research University
- 期: 卷 23, 编号 1 (2024)
- 页面: 55-66
- 栏目: AIRCRAFT AND SPACE ROCKET ENGINEERING
- URL: https://journal-vniispk.ru/2542-0453/article/view/311446
- DOI: https://doi.org/10.18287/2541-7533-2024-23-1-55-66
- ID: 311446
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全文:
详细
The power supply system being created is intended to provide electricity to spacecraft systems. It ensures that the design characteristics of the solar battery of the prototype are preserved and makes it possible to install means to support the thermal conditions of the photovoltaic battery while maintaining the cost of production of the prototype solar battery. Various types of solar energy concentrators are considered: concentrators in the form of individual convex linear Fresnel lenses, Flexible Array Concentrator Technology concentrators, Stretched Lens Array concentrators. A method for improving the characteristics of the spacecraft solar system is presented. The methodology includes the calculation of various types of concentrators, types of photovoltaic converters and types of solar battery frames. As an example of the implementation of the methodology, the design of solar battery panels was developed. A comparative table of the solar battery before and after modernization is provided.
作者简介
M. Mordanov
Samara National Research University
编辑信件的主要联系方式.
Email: mordanovmarsel@gmail.com
Engineer
俄罗斯联邦S. Safronov
Samara National Research University
Email: safronov@ssau.ru
ORCID iD: 0000-0002-7530-0636
Candidate of Science (Engineering), Associate Professor of the Department of Space Engineering
俄罗斯联邦参考
- Galinovsky A.L., Denisov A.V., Gavrilova E.A., Denisova M.A., Chertov V.G., Eremin S.A. Designing frames of integrated cfrp solar panels for spacecraft. Proceedings of Higher Educational Institutions. Маchine Building. 2019. No. 12 (717). P. 49-60. (In Russ.). doi: 10.18698/0536-1044-2019-12-49-60
- Green M.A. Third generation photovoltaics: Advanced solar energy conversion. Springer, 2003. 65 p. doi: 10.1007/b137807
- Bayborodov A.A., Vasil'eva T.S., Volkov M.V., Kuznetsov A.D., Dvirnyy V.V. Solnechnye batarei s kontsentratorami svetovogo potoka. Sbornik trudov Mezhdunarodnoy molodezhnoy nauchnoy konferentsii «XIV Korolevskie Chteniya» (October, 3-5, 2017, Samara). V. 1. Samara: Samara University Publ., 2017. P. 8-13. (In Russ.)
- Kazantsev Yu.M., Kremzukov Yu.A. Automated control system of energy-transducing equipment of spacecraft power-supply system. Bulletin of the Tomsk Polytechnic University. 2009. V. 314, no. 4. P. 138-141. (In Russ.)
- Taran A.A., Voronin S.M. Photoelectric transformer efficiency in solar emission. Don Agrarian Science Bulletin. 2011. No. 3 (15). P. 35-40. (In Russ.)
- Belan N.V. Bortovye energosistemy kosmicheskikh apparatov na osnove solnechnykh i khimicheskikh batarey [Onboard power systems of spacecraft based on solar and chemical batteries]. Kharkov: Kharkov Aviation Institute Publ., 1992. 191 p.
- Dyblya A.Yu., Kuzina T.A., Samoylov V.V. Calculation of solar batteries for spacecraft of a satellite communication system in low circular orbit. Innovative Science. 2020. No. 4. P. 28-31. (In Russ.)
- Slyshchenko E.V., Naumova A.A., Lebedev A.A., Genali M.A., Vagapova N.T., Zhalnin B.V. The review of modern solar cells for space application based on AIIIBV materials. Siberian Journal of Science and Technology. 2018. V. 19, no. 2. P. 308-324. (In Russ.). doi: 10.31772/2587-6066-2018-19-2-308-324
- Ryabtseva M.V., Lebedev A.A., Naumova A.A., Bolotin A.M., Vagapova N.T., Cherenkov P.G. Analysis of promising spacecraft solar cell designs. Engineering Journal: Science and Innovation. 2022. No. 3 (123). (In Russ.). doi: 10.18698/2308-6033-2022-3-2162
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