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Analiza przydatności pojazdów powietrznych, wyposażonych w skrzydła, do wystrzeliwania satelitów na niską orbitę okołoziemską
Języki publikacji
Abstrakty
The use of near-Earth space for scientific and commercial purposes has skyrocketed in recent years. However, progress continues to be hampered by the cost and availability of vehicles relied upon for delivering payloads to the Earth’s orbit. The Riga Technical University (Latvia), with the assistance of the Technological University in Kielce (Poland), is developing a concept of a novel payload launch system. The implications of such a system for launching payloads into low Earth orbit (LEO) are presented in the article. The system, intended for launching small spacecraft, comprises the A319 MPA transport airplane used as a platform aircraft and a three-stage payload carrier, codenamed LatLaunch. The first and second stages of the three-stage launch vehicle are unmanned winged aircraft. The third stage is a classic rocket which, once dropped from the launch platform, takes the payload to a specific height, at a given rate of speed and at a predetermined trajectory angle. The article presents the results of a study focusing on designing this system.
Przedstawiono wyniki prac nad koncepcją systemu wynoszenia małych statków kosmicznych na niskie orbity okołoziemskie (LEO). Ten system startowy małych statków kosmicznych obejmuje samolot transportowy A319MPA jako samolot platformowy oraz trzystopniowy mały nośnik pojazdów latających o nazwie LatLaunch. Pierwszy i drugi stopień trzystopniowego nośnika małego statku kosmicznego to uskrzydlone statki powietrzne. Trzeci stopień to klasyczna rakieta, która po zrzuceniu przenosi ładunek na określoną wysokość z zadaną prędkością i kątem trajektorii. W artykule przedstawiono wyniki badań nad tworzeniem tego systemu. Zastosowano metody aerodynamiki naddźwiękowej i trójwymiarowego modelowania. W wyniku obliczeń i trójwymiarowego modelowania powstał schemat LatLaunch, który umożliwia zintegrowanie go z platformą powietrzną - trzeci stopień rakiety jest warunkowo przesunięty z wewnętrznego przedziału drugiego stopnia.
Rocznik
Strony
9--20
Opis fizyczny
Bibliogr. 20 poz., rys., wykr.
Twórcy
autor
- Kielce University of Technology, 7 Tysiąclecia Państwa Polskiego Av., 25-314 Kielce, Poland
autor
- Cryogenic and Vacuum Systems, 7/9 Andreja Str., Ventspils, LV-3601, Latvia
autor
- Cryogenic and Vacuum Systems, 7/9 Andreja Str., Ventspils, LV-3601, Latvia
autor
- Cryogenic and Vacuum Systems, 7/9 Andreja Str., Ventspils, LV-3601, Latvia
Bibliografia
- [1] Fateeva, V. F. (ed). 2010. Small spacecraft for information support. Radio engineering, Moscow. https://ka.b-ok.xyz/book/2762803/beaf6b.
- [2] Jones, H. W. 2018. The recent large reduction in space launch cost. In Proc. of 48th International Conference on Environmental Systems ICES-2018-81. 8-12 July 2018, Albuquerque, New Mexico. https://ttu-ir.tdl.org/bitstream/handle/2346/74082/ICES_2018_81.pdf.
- [3] da Cás, L. K. Pedro, Carlos A. G. Veras, Olexiy Shynkarenko, and Rodrigo Leonard. 2019. “A Brazilian space launch system for the small satellite market”. Aerospace 6 (11) : 123-1-19.
- [4] Werner, Debra. 2018. “Small Satellites Are at the Center of a Space Industry Transformation”. Spacenews, https://spacenews.com/small-satellites-are-at-the-center-of-a-space-industry-transformation/ (accessed on 27 June 2019).
- [5] Crisp, N. H., K. Smith, and P. Hollingsworth. 2015. “Launch and deployment of distributed small satellite systems”. Acta Astronaut. 114 : 65-78.
- [6] Drenthe, N. T., B. T. C. Zandbergen, R. Curran, and M.O. Van Pelt. 2019. “Cost estimating of commercial smallsat launch vehicles”. Acta Astronaut. 7 : 160-169.
- [7] Koelle, D. E. 2013. TRANSCOST 8.2. Handbook of cost engineering for space transportation systems with TranceCostSystem: statistical-analytical model for cost estimation and economical optimization of launch vehicles; rev.4. Germany: TransCostSystems, Ottobrunn.
- [8] Kravchenko, Sergey, Natalja Panova, Nikolay Kuļešovs, Ilmars Blumbergs, and Vladimirs Šestakovs. 2020. Analysis of the Technical Implementation Options for Launching a Carrier for Output of Micro Satellites to LEO from an Aircraft Platform (LatLaunch project). In Rīgas Tehniskās universitates 61. starptautiskā zinātniskā konference, Latvia, Rīga, 15-16 October, 2020. Latvia: Rīga RTU Press, 202: 16-17.
- [9] Kravchenko, Sergey, Nikolay Kuleshov, Vladimirs Shestakov, Natalja Panova, and Ilmars Blumbergs. 2021. Comparative Analysis of Possible Aircraft Payload Transportation Method, Suitable for the LatLaunch Reusable Launch Vehicle Operation. In Proc of 25th international scientific conference “Transport means 2021” Vol. II, pp. 818-825. Kaunas October 6-8, 2021.
- [10] Pegasus-User-Guide-1. Release 8.2. 2020. Northrop Grumman Corporation, pp. 113.
- [11] Kuļešovs, Nikolay, Sergey Kravchenko, Ilmars Blumbergs, Natalja Panova, and Vladimirs Šestakovs. Patent LVP2022000015. 2022. Atdalams divkorpusu sparnotais lidaparats ka derigas kravas/satelitu daudzpakapju neseja pirma pakape (in Latvian).
- [12] Kravchenko, Sergey, Nikolay Kuļešovs, Ilmars Blumbergs, Natalja Panova, and Vladimirs Šestakovs. Patent LVP2022000012. 2022. Sistema derigas kravas nogadei zemes orbita (in Latvian).
- [13] Kravchenko, Sergey, Nikolay Kuleshov, Vladimirs Shestakov, Natalja Panova, and Ilmars Blumbergs. 2021. Advantage of using aircraft-type stages for creating "Latlaunch" launch vehicle. In Proc. of 20th International Scientific Conference Engineering for Rural Development Proceedings, Vol. 20, pp. 891-899. Jelgava, May 26-28, 2021.
- [14] Kuleshov, Nikolay, Sergey Kravchenko, Vladimirs Shestakov, Ilmars Blumbergs, D. Titov, and Natalja Panova. 2021. Modeling the Overall, Mass, and Aerodynamic Characteristics of the First and Second Stages of the System for Launching Micro- and Nanosatellites into Low Earth Orbits. In Proc. of 25th international scientific conference “Transport means 2021” Vol. II, pp. 818-825, Kaunas October 6-8, 2021.
- [15] NASA. 2014. Waking a Giant: Bringing the Saturn F-1 Engine Back to Life, https://ntrs.nasa.gov/archive/nasa/casi.ntrs.nasa.gov/20140011656.pdf.
- [16] Urbahs, Aleksandrs, Sergey Kravchenko, Margarita Urbaha, Kristine Carjova, Natalja Panova, and Rafał Chatys. 2021. “LatLaunch air-launch system for low-cost launching of small satellites into low earth orbit”. Aviation 2021, 25(2): 73- 78.
- [17] Kulikov, A. A. 1978. Practical aircraft aerodynamics MiG-25RB in Silin A.N. Moscow: Military publishing house of the USSR Ministry of Defense, p. 320.
- [18] Mehta U., Huynh L., Hagseth P. 2015. “Water injection pre-compressor cooling assist space access”. The Aeronautical Journal 119, 145-171.
- [19] Corda, S., and J.D. Anderson. 2021. Viscous Optimized Hypersonic Waveriders Designed from Axisymmetric Flow Fields. https://www.researchgate.net/publication/269215543_Viscous_optimized_hypersonic_waveriders_designed_from_axisymmetric_flow_fields (accessed on 04.06.2021).
- [20] Ding, F., J. Liu, C-b Shen, W. Huang, Z. Liu, S-h Chen. 2021. An overview of waverider design concept in airframe/inlet integration methodology for air-breathing hypersonic vehicles. https://www.researchgate.net/publication/327428996_An_overview_of_waverider_design_concept_in_airframeinlet_integration_methodology_for_air-breathing_hypersonic_vehicles (accessed on 04.06.2021).
Uwagi
1. Opracowanie rekordu ze środków MNiSW, umowa nr SONP/SP/546092/2022 w ramach programu "Społeczna odpowiedzialność nauki" - moduł: Popularyzacja nauki i promocja sportu (2024).
2. This research was funded by the Aeronautics Institute of the Riga Technical University (Latvia), under the project “Design and Modelling of Aerospace for Launching Pico- and Nano Satellites to Low Earth Orbit” (LatLaunch, project No. Lzp-2018/2-0344) and was completed with the assistance of the Kielce University of Technology (Kielce, Poland).
Typ dokumentu
Bibliografia
Identyfikator YADDA
bwmeta1.element.baztech-186eb8d9-2a99-4835-804c-bd1e76c090ae