D. G. Pantenkov1, S. I. Shalgunov2, A. T. Egorov3, A. M. Vorobyev4, V. A. Koltsov5
1, 3, 4 JSC «Kronstadt» (Moscow, Russia)
2, 5 JSC «Scientific and production association Stekloplastic» (Solnechnogorsk, Russia)

Currently, large-scale complexes with unmanned aerial vehicles (CUAVs) of long flight duration, which can stay in the air for up to several days, have received great development and widespread use. At the same time, such UAVs of heavy and super-heavy classes can have a wide range of payloads on board – a radar station, a multispectral optoelectronic system on a gyro stabilized platform, a digital aerial photo system, a radio and radio monitoring system. Long flight duration automatically means significant distance between the UAV and the ground control station (GCS). In this case, satellite communication channels become the main and only means of command and information exchange between UAVs and GCS. One of the main parameters of any communication channel is the information transfer rate. With regard to satellite communication of the radio link UAVs – spacecraft (SC) – GCS and GCS – SC – UAVs have a significant energy deficit on the signal propagation path due to the need to relay information through SCs in high orbits (geostationary and highly elliptical). Taking into account the above, the relevance and importance of the tasks solved by modern complexes with UAVs for special and civil purposes, a number of essential requirements are imposed on the design of radio-transparent fairings (RTF) for UAVs: in terms of strength, resistance to external influencing factors, aerodynamics and, of course, radio transparency in relation to minimization energy losses of the signal when passing through its walls, which ultimately significantly affects the final transmission rate of target information. This article has a high relevance, strict practical orientation and is devoted to the consideration of the results of the design of the RTF for a large-sized heavy-class UAV, obtained both as a result of electrodynamic modeling, and during experimental workings and field experiments, analysis of the obtained characteristics of the RTF. Due to its large volume, the article is structurally divided into three interconnected parts. In the first part of the article, as a statement of the problem, the main system requirements for the developed RTF have been formulated, the analysis of the main materials used from which it is fundamentally possible to manufacture RTF, their physical-mechanical and dielectric properties, wall designs, manufacturing technologies of RTF has been carried out. It has been quantitatively shown that the choice of optimal materials and the design of the walls of the RTF should be based on a reasonable compromise between the radio engineering and elastic-strength characteristics of the projected radio-transparent product.

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