Methodology of designing a small spacecraft for technological purposes

Andrey V. Sedelnikov; Седельников Андрей Валерьевич; Anastasiya S. Taneeva; Танеева Анастасия Сергеевна

doi:10.25206/2588-0373-2024-8-4-73-79

Methodology of designing a small spacecraft for technological purposes

Autores: Sedelnikov A.V.¹, Taneeva A.S.¹
Afiliações:
1. Samara National Research University
Edição: Volume 8, Nº 4 (2024)
Páginas: 73-79
Seção: Articles
URL: https://journals.rcsi.science/2588-0373/article/view/279358
DOI: https://doi.org/10.25206/2588-0373-2024-8-4-73-79
EDN: https://elibrary.ru/TTAAOV
ID: 279358

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Resumo
Sobre autores
Bibliografia
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Resumo

The paper presents a methodology for designing a small spacecraft to perform the tasks of technological processes in near-Earth space. When designing such a small spacecraft, it is assumed that it will be equipped with a microgravity platform to meet the requirements for micro-accelerations. The methodology is based on the principles of individuality, attainability and controllability. They guarantee the maximum possible consideration of the features of the gravity-sensitive process being implemented, including compliance with the requirements for limiting the micro-acceleration module in the working area of technological equipment and effective control of this implementation. The developed technique can be used in the design of a small spacecraft for technological purposes.

Palavras-chave

design methodology, micro-acceleration, gravity-sensitive processes, microgravity platform, small spacecraft, technological purpose, vibration protection device

Sobre autores

Andrey Sedelnikov

Samara National Research University

Autor responsável pela correspondência
Email: onv@omgtu.ru
ORCID ID: 0000-0003-2698-1348
Código SPIN: 3987-6997

Doctor of Technical Sciences, Professor, Professor of Space Engineering Department

Rússia, Samara, Moskovskoye sh., 34, 443086

Anastasiya Taneeva

Samara National Research University

Email: onv@omgtu.ru
ORCID ID: 0000-0002-8531-760X
Código SPIN: 8816-1930

Graduate Student of Space Engineering Department, Engineer of NII-219 (Research Institute of Space Engineering), Engineer and Assistant of Space Engineering Department

Rússia, Samara, Moskovskoye sh., 34, 443086

Bibliografia

Raykunov G. G., Ezhov S. A., Gusev L. I. Sovremennyye tendentsii v razvitii kosmicheskogo priborostroyeniya i kosmicheskikh informatsionnykh sistem [Current trends in growth of space device engineering and space information systems] // Raketno-kosmicheskoye priborostroyeniye i informatsionnyye sistemy. Rocket-Space Device Engineering and Information Systems. 2014. Vol. 1, no. 1. P. 3–12. EDN: THSWPD. (In Russ.).
Sedelnikov A. V., Eskina E. V., Taneyeva A. S., Khnyreva E. S., Matveyeva E. S. Problema obespecheniya i kontrolya trebovaniy po mikrouskoreniyam na bortu malogo kosmicheskogo apparata tekhnologicheskogo naznacheniya [The problem of ensuring requirements for microaccelerations on board of small spacecraft] // Omskiy nauchnyy vestnik. Seriya aviatsionno-raketnoye i energeticheskoye mashinostroyeniye. Omsk Scientific Bulletin. Series Aviation-Rocket and Power Engineering. 2022. Vol. 6, no. 2. P. 90–98. doi: 10.25206/2588-0373-2022-6-2-90-98. EDN: YNTNVQ. (In Russ.).
Klimenko N. N. Smena paradigmy: sozdaniye i primeneniye psevdokosmicheskikh apparatov kak sostavnaya chast’ «novoy kosmicheskoy revolyutsii» i «novoy bespilotnoy revolyutsii» [Paradigm shift: development and deployment of high altitude pseudosatellites as a complementary part of «new space revolution» and «new drone revolution»] // Vestnik NPO im. S. A. Lavochkina. Vestnik NPO IM. S. A. Lavochkina. 2023. No. 3 (61). P. 3–18. doi: 10.26162/LS.2023.61.3.001. (In Russ.).
Aslanov V. S., Yudintsev V. V. Vybor parametrov sistemy uvoda kosmicheskogo musora s uprugimi elementami posredstvom trosovoy buksirovki [Parameters selection of space debris removal system with elastic elements by cable towing] // Vestnik Moskovskogo aviacionnogo instituta. Aerospace MAI Journal. 2018. Vol. 25, no. 1. P. 7–17. EDN: YSPCOF. (In Russ.).
Sedel’nikov A. V., Taneyeva A. S. Modelirovaniye polya mikrouskoreniy v zashchishchennoy zone vibrozashchitnykh ustroystv dlya realizatsii gravitatsionno-chuvstvitel’nykh protsessov na bortu malogo kosmicheskogo apparata tekhnologicheskogo naznacheniya [Modeling the micro-acceleration field in the protected zone of vibration-proof devices for implementation of gravity-sensitive processes on board a small technological spacecraft] // Omskiy nauchnyy vestnik. Seriya aviatsionno-raketnoye i energeticheskoye mashinostroyeniye. Omsk Scientific Bulletin. Series Aviation-Rocket and Power Engineering. 2023. Vol. 7, no. 2. P. 65–72. doi: 10.25206/2588-0373-2023-7-2-65-72. EDN: AJCGPU. (In Russ.).
Sedelnikov A. V., Molyavko D. P., Khnyreva E. S. O snizhenii upravlyayemosti kosmicheskogo apparata pri provedenii aktivnogo kontrolya mikrouskoreniy na stadii ekspluatatsii [About decrease in controllability of spacecraft when carrying out active control microaccelerations at the operation stage] // Aviakosmicheskoye priborostroyeniye. Aerospace Instrument-Making. 2017. No. 4. P. 25–34. EDN: YUONUD. (In Russ.).
Lobykin A. A. Metody uluchsheniya mikrogravitatsionnoy obstanovki na bortu avtomaticheskogo kosmicheskogo apparata, prednaznachennogo dlya mikrogravitatsionnykh issledovaniy [Enhancement of Microgravity Environment on a Board of Automatic Spacecraft for Microgravity Investigations] // Poverkhnost’. Rentgenovskiye, sinkhrotronnyye i neytronnyye issledovaniya. Journal of Surface Investigation. X-Ray, Synchrotron and Neutron Techniques. 2009. No. 2. P. 84–91. EDN: JVSLCD. (In Russ.).
Sedelnikov A. V. Kontrol’ mikrouskoreniy kak vazhneyshey kharakteristiki kosmicheskoy laboratorii spetsializirovannogo tekhnologicheskogo naznacheniya konstruktivnymi metodami [Control of microaccelerations as the major characteristics of space laboratory of specialized technological appointment as constructive methods] // Kontrol’. Diagnostika. Testing. Diagnostics. 2014. No. 7. P. 57–63. doi: 10.14489/td.2014.07.pp.057-063. EDN: SGPIKR. (In Russ.).
Elkin K. S., Ivanov A. I., Neznamova L. O., Prudkoglyad V. O. Perspektivy sozdaniya vakuumnykh i gravitatsionno-chuvstvitel’nykh tekhnologiy, ispol’zuyushchikh usloviya kosmicheskogo poleta na okolozemnykh orbitakh. Issledovaniye gravitatsionno-chuvstvitel’nykh yavleniy na bortu otechestvennykh kosmicheskikh apparatov [Prospects for creation of vacuum and gravity-sensitive technologies using space flight conditions in near-Earth orbits. Investigation of gravity-sensitive phenomena on board domestic spacecrafts] / By ed. K. S. Elkina. Moscow, 2013. 306 p. (In Russ.).
Wu Q., Liu B., Cui N. [et al.] Tracking Control of a Maglev Vibration Isolation System Based on a High-Precision Relative Position and Attitude Model // Sensors. 2019. Vol. 19. 3375. doi: 10.3390/s19153375. (In Engl.).
Liu J., Li Y., Zhang Y. [et al.] Dynamics and control of a parallel mechanism for active vibration isolation in space station // Nonlinear Dynamics. 2014. Vol. 76, no. 3. P. 1737–1751. doi: 10.1007/s11071-014-1242-3. (In Engl.).
Borisov A. E., Emel’yanov G. A., Nikitin S. A. Parametricheskaya optimizatsiya sistemy upravleniya avtomaticheskoy povorotnoy vibrozashchitnoy platformy dlya mikrogravitatsionnykh issledovaniy [Parametric system optimization of the management of an automatic rotary vibration-proof platform for the microgravity research] // Kosmonavtika i raketostroyeniye. Cosmonautics and Rocket Engineering. 2013. No. 3 (72). P. 147–155. EDN: RECYIT. (In Russ.).
Zhu T., Cazzolato B., Robertson W. S. P. [et al.] Vibration isolation using six degree-of-freedom quasi-zero stiffness magnetic levitation // Journal of Sound and Vibration. 2015. Vol. 358. P. 48–73. doi: 10.1016/j.jsv.2015.07.013. (In Engl.).
Grodsinsky C. M., Whorton M. S. A Survey of Active Vibration Isolation Systems for Microgravity Applications // Journal of Spacecraft and Rockets. 2000. Vol. 37, no. 5. P. 586–596. doi: 10.2514/2.3631. (In Engl.).
Liu C., Jing X., Daley S. Recent advances in micro-vibration isolation // Mechanical Systems and Signal Processing. 2015. Vol. 56–57. P. 55–80. doi: 10.1016/j.ymssp.2014.10.007. (In Engl.).
Wang S., Hou L., Meng Q. [et al.] Three-magnet-ring quasi-zero stiffness isolator for low-frequency vibration isolation // International Journal of Mechanical System Dynamics. 2024. Vol. 4, no. 2. P. 153–170. doi: 10.1002/msd2.12107. (In Engl.).
Xie D., Zheng Z., Zhu Y. Design of a two-degree-of-freedom magnetic levitation vibration energy harvester for bridge vibration response analysis // Heliyon. 2024. Vol. 10, no. 4. e26000. doi: 10.1016/j.heliyon.2024.e26000. (In Engl.).
Ming C., Xing J., Chen Z. [et al.] Design, analysis and experimental investigation on the whole-spacecraft vibration isolation platform with magnetorheological dampers // Smart Materials and Structures. 2019. Vol. 28, no. 7. 075016. doi: 10.1088/1361-665X/ab0ebe. (In Engl.).
Wang A., Wang S., Xia H. [et al.]. Dynamic Modeling and Control for a Double-State Microgravity Vibration Isolation System // Microgravity Science and Technology. 2023. Vol. 35, no. 1. 9. doi: 10.1007/s12217-022-10027-8. (In Engl.).
Edberg D., Boucher R., Nurre G. S. [et al.] Performance assessment of the STABLE Microgravity Vibration Isolation Flight Demonstration // 38th Conference Structures, Structural Dynamics, and Materials. 1997. doi: 10.2514/6.1997-1202. (In Engl.).
Jones D. I., Owens R. G., Owen A. R. A microgravity isolation mount // Acta Astronautica. 1987. Vol. 15, no. 6–7. P. 441–448. (In Engl.).
Whorton M. S. g-LIMIT — A microgravity vibration isolation system for the International Space Station // Conference and Exhibit on International Space Station Utilization. 2001. doi: 10.2514/6.2001-5090. (In Engl.).
Dong W., Duan W., Liu W. [et al.] Microgravity disturbance analysis on Chinese space laboratory // npj Microgravity. 2019. Vol. 5, no. 1. doi: 10.1038/s41526-019-0078-z. (In Engl.).
Qian Y., Xie Y., Jia J. [et al.] Development of Active Microvibration Isolation System for Precision Space Payload // Applied Science. 2022. Vol. 12. 4548. doi: 10.3390/app12094548. (In Engl.).
Kim Y., Kim S., Park K. Magnetic force driven six degree-of-freedom active vibration isolation system using a phase compensated velocity sensor // Review of Scientific Instruments. 2009. Vol. 80. 045108. doi: 10.1063/1.3117462. (In Engl.).
Zhongxiang Y., Zhengguang Zh., Lizhan Z. [et al.]. Microvibration isolation in sensitive payloads: methodology and design // Nonlinear Dynamics. 2023. Vol. 111, no. 21. P. 1–49. doi: 10.1007/s11071-023-08943-4. (In Engl.).
Sedelnikov A. V., Taneyeva A. S. Kontseptual’naya model’ malogo kosmicheskogo apparata tekhnologicheskogo naznacheniya [Conceptual model of a technological purpose small spacecraft] // Vestnik Moskovskogo aviatsionnogo instituta. Aerospace MAI Journal. 2024. Vol. 31, no. 2. P. 44–55. EDN: WVCFSZ. (In Russ.).
Sazonov V. V., Chebukov S. Yu., Abrashkin V. I. [et al.] Analiz nizkochastotnykh mikrouskoreniy na bortu ISZ FOTON-11 [Low-frequency microaccelerations onboard the foton-11 satellite] // Kosmicheskiye issledovaniya. Cosmic Research. 2001. Vol. 39, no. 4. P. 419–435. EDN: OUWKOJ. (In Russ.).
Abrashkin V. I., Bogoyavlenskiy N. L., Voronov K. E. [et al.] Neupravlyayemoye dvizheniye sputnika Foton M-2 i kvazistaticheskiye mikrouskoreniya na ego bortu [Uncontrolled motion of the Foton M-2 satellite and quasistatic microaccelerations on its board] // Kosmicheskiye issledovaniya. Cosmic Research. 2007. Vol. 45, no. 5. P. 450–471. EDN: IAQPJV. (In Russ.).
Abrashkin V. I., Voronov K. E., Piyakov I. V. [et al.] Vrashchatel’noye dvizheniye sputnika FOTON M-4 [Rotational motion of Foton M-4] // Kosmicheskiye issledovaniya. Cosmic Research. 2016. Vol. 54, no. 4. P. 315–322. doi: 10.7868/s0023420616040014. EDN: WDORML. (In Russ.).

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