LANDING PLATFORM AND SYSTEM FOR POSITIONING AND ALIGNING AERIAL VEHICLE ON IT

Abstract

The invention is designed for the organization of landing of unmanned vertical take-off and landing aerial vehicles (UAV VTOL) on the landing platform of a ground station, (including) for the purposes of automatic servicing their payloads and/or energy sources after landing. Due to the invention, it is provided correct position and alignment relative to the landing platform of unmanned aerial vehicle with three main landing legs on a flat horizontal landing platform, by providing rotation in opposite directions of two flat centering discs mounted on the platform with a protruding counter-direction spiral guide on each disk.

Claims

1-18. (canceled)

19. A landing platform (1) with a flat horizontal surface for positioning of unmanned aerial vehicle (2), comprising elements located on the platform adapted for centering of a landing or landed unmanned aerial vehicle, the elements comprising: a pair of adjacent rotatable flat discs (3) and straight groove(s) (4, 4b) arranged on a plane of the platform (1) along a line of symmetry between the discs (3), the discs being coupled to a drive or drives adapted to spin the discs, wherein each disc (3) is made integral with a narrow spiral guide (5) converging towards the center of the disc and protruding above the surface of the disc, the guide being configured to enable a supporting element of the unmanned aerial vehicle to slide towards the center (21) of the disc (3) during disc rotation, the spiral on one disc being left-handed (5b), and the spiral on the other disc being right-handed (5a).

20. The landing platform according to claim 19, wherein the upper surface of each disc (3) is fitted on the same level with the upper surface of the platform (1), and the spiral guide (5) is made as a strip fixed by its edge onto the disk (3) and configured with an offset from the center (21) of the disc (3) and with maximum slip contact with side surface of supporting element of landing or landed unmanned aerial vehicle (2).

21. The landing platform according to claim 19, wherein the spiral guide (5) is a logarithmic spiral, comprising from one to one and a half turns.

22. The landing platform according to claim 19, wherein the groove (4) is made on one or both sides of a line connecting the centers (21) of rotation of the discs (3), and is optionally through.

23. The landing platform according to claim 19, wherein the drives driving the discs (3) into rotation in opposite directions 27, 28 are configured as either two separate or one joint drive, and can be mounted directly in the discs (3), and wherein the drives (13) can drive the discs directly or via a reducer.

24. The landing platform according to claim 19, further comprising position and/or rotation sensors (22) for the discs (3).

25. The landing platform according to claim 19, wherein the platform (1) outside the groove(s) and the discs comprises one or more through holes (14) configured to operate with payload and/or energy sources (30) of the unmanned aerial vehicle (2) landed and positioned on the platform (1).

26. A system for positioning and aligning of an unmanned aerial vehicle on the landing platform, comprising the landing platform according to claim 19, and the unmanned aerial vehicle, wherein the unmanned aerial vehicle (2) is configured for vertical take-off and landing and comprises supporting elements configured to interact with the spiral guides (5) on the discs (3) of the landing platform (1) and with the groove (4) on the platform, wherein the supporting elements are made in the form of three main landing legs (6, 7) of the same height, installed on the base of unmanned aerial vehicle at vertices of an imaginary or real isosceles triangle (9) inscribed at the base of unmanned aerial vehicle, wherein the landing leg (7) at the vertex opposite the base of the isosceles triangle (31) is equipped with retractable vertically downwards pin (15), and wherein two other landing legs (6) are made cylindrical.

27. The system according to claim 26, wherein the retractable pin (15) is configured to fall into the groove(s) (4, 4b) of the landing platform (1) under its own weight, or-being made with a pushing element inside, and wherein the outer diameter of the pin (15) corresponds to the width of the groove (4, 4b) of the platform.

28. The system according to claim 26, wherein the height of cylindrical leg (6) corresponds to the height of the spiral guide (5) of the disk (3) of the platform (1), and outer radius of the leg corresponds to the offset of the spiral guide (5) from the center (21) of the disk (3) of the landing platform (1), wherein the cylindrical landing legs (6) are able to slide along the inner side surface of the respective spiral guides (5a, 5b) and comprise cylindrical skirts rotating freely around an axis of the leg.

29. The system according to claim 26, wherein the diameter of each disc (3) of the landing platform (1) is selected to receive each cylindrical landing leg (6) on the respective disc (3) when the unmanned aerial vehicle (2) lands, wherein the diameter is selected to be equal to double deviation of cylindrical leg (6) from the center of disc (3) with the probability of successful positioning after landing is based on the positioning accuracy of unmanned aerial vehicle (2), and the distance between the discs (3) is selected so that axes of rotation of the discs (3) of the landing platform coincide with the axes of cylindrical landing legs (6) in final position of the unmanned aerial vehicle (2) on the landing platform (1).

30. The system according to claim 26, wherein the unmanned aerial vehicle (2) further comprises one or more additional landing legs (16) outside of the imaginary or real isosceles triangle (9).

31. The system according to claim 30, wherein the groove (4) of the landing platform is arranged on both sides of the line connecting the centers (21) of rotation of the discs (3), wherein the imaginary or real triangle (9) is formed by two adjacent sides (19) and a diagonal (20) of imaginary or real square (17) at the base of the unmanned aerial vehicle (2), and wherein the additional leg (16) is arranged on the fourth vertex of imaginary or real square (17).

32. The system according to claim 26, wherein one or all of the landing legs, other than two main cylindrical legs (6), are also made cylindrical.

33. The system according to claim 26, wherein some or all of the landing legs, other than main leg (7) with retractable pin (15), further comprise the retractable pin.

34. The system according to claim 33, wherein all the landing legs are made the same.

35. The system according to claim 26, wherein the upper surface of the discs (3) of the landing platform (1) and/or bottom surface of the landing legs (6, 7, 16) of the unmanned aerial vehicle (2) is partly or completely made of low-friction material, and/or bottom surface of the landing legs is made spherical.

36. The system according to claim 26, wherein the landing platform (1) is equipped with two or more groups of centering elements comprising the pairs of discs (3) and respective grooves (4, 4b).

Description

BRIEF DESCRIPTION OF DRAWINGS

[0047] The proposed technical solution is explained by drawings, which illustrate the essence, but do not limit the scope of protection of the invention.

[0048] FIG. 1 shows a landing platform 1 and UAV 2 landing on it. Aligning elements — two discs 3 with spiral guides 5a and 5b and groove 4 — are shown on the platform.

[0049] FIG. 2. View of the UAV 2 from the base side (from the bottom). Shown is imaginary/real triangle 9 and three main landing legs of UAV arranged at its vertices -two cylindrical 6 and one leg 7 with retractable pin 15. Payload or energy source 30, accessible for service from below, are also shown.

[0050] FIG. 3. View of the landing platform 1 with UAV 2 landed on it, which is in the correct position and correctly aligned - cylindrical legs 6 of UAV being coaxial with the discs, and retractable pin of the third leg 7 being in the groove.

[0051] FIG. 4 shows UAV 2 (variant with a square base) landing on the landing platform 1 with two discs 3 arranged at diagonally opposite vertices of the imaginary square with an edge 19, and two grooves 4 and 4b, with centers on the remaining two vertices of the imaginary square and located along its diagonal connecting said two vertices.

[0052] FIG. 5. View of the UAV 2 (variant with a square base) from the base side (from the bottom). Are shown imaginary square 17 at the base of the UAV and three main landing legs of UAV, located at its vertices - two cylindrical legs 6 and one leg 7 with retractable pin 15, as well as one additional landing leg 16. Payload or energy source 30, accessible for service from below, are also shown.

[0053] FIG. 6. View of the landing platform 1 with UAV 2 landed on it, which is in the correct position and correctly aligned - cylindrical legs 6 of UAV 2 are coaxial with discs 3, and retractable pin 15 of third main landing leg 7 is in groove 4b.

[0054] FIG. 7. Bottom view of landing platform 1, designed for receiving UAV with only three main landing legs. Shown are two separate drives 13 of discs 3, rotation or position sensors 22 of discs 3 and openings 14 for servicing the payload or energy source of UAV.

[0055] FIG. 8. Bottom view of landing platform 1, designed for receiving UAV with three main landing legs and one additional leg. Shown are two separate drives 13 of discs 3, rotation or position sensors 22 of discs 3 and opening 14 for servicing the payload or energy source of UAV.

[0056] FIG. 9. Side view of landing platform 1 shows a variant of the drive of discs with spiral guides 5 using two threaded shafts 23.

[0057] FIG. 10 shows a process of landing UAV 2 with a triangular base on landing platform 1.

[0058] FIG. 11 demonstrates a process of interaction of spiral guides with the landing legs of UAV, namely, applying of force in direction 25 of spiral guide 5b -to the leg 6, and in direction 26 (towards the groove) - on the leg 7.

[0059] FIG. 12 demonstrates additionally further guiding action of groove 4 on landing leg 7 with the retractable pin inserted into the groove(s).

[0060] FIG. 13 shows the UAV at the end of the aligning process. UAV is correctly positioned and aligned on platform 1.

[0061] FIG. 14 shows a landing platform 1 with two groups of centering means 32.

MODES OF EMBODIMENTS OF THE INVENTION

[0062] Modes of embodiments of the invention are examples illustrating this invention, however not limiting its scope of protection.

Description of the System and the Landing Platform

[0063] FIG. 1 shows schematically the landing platform 1 and landing unmanned aerial vehicle 2, which are the key elements of the aerial vehicle positioning and aligning system according to the present invention, and the elements of which are configured in special way with respect to each other to achieve maximum efficiency in their interaction when positioning and aligning unmanned aerial vehicle during (after) landing. Thus, the design of landing platform 1 and supporting elements of UAV 2 are bind by unified inventive concept into UAV positioning and alignment system.

[0064] Unmanned aerial vehicle (UAV) 2 is a vertical take-off and landing (VTOL) vehicle, which positioning accuracy is sufficient to land within the perimeter of landing platform 1. UAV is designed for automated manipulation with its payload and/or its energy sources 30.

[0065] In the principle variant, each UAV 2, serviced by the system, is equipped with three main landing legs 6 and 7 of the same height (FIG. 2), arranged at the vertices of the imaginary or real isosceles triangle at the base of the aerial vehicle 2 (FIGS. 1, 2, 3, 10, etc.). Landing leg 7 at the vertex opposite the base 31 of the isosceles triangle, is equipped with retractable vertically downwards pin 15. Optimally, pin 15 is made with pushing spring inside it, and the outer diameter of pin 15 corresponds to the width of groove 4 of the platform, not exceeding it. Two landing legs 6, arranged at the base of the isosceles triangle are cylindrical in shape and, optimally, are provided with a cylindrical skirt, rotating freely around the axis of the leg.

[0066] UAV may be equipped with additional landing legs 16 located outside the perimeter of the imaginary or real triangle at the base of UAV. The total number of legs and their design is chosen to ensure reliable (and even) retention of UAV on the horizontal plane of landing platform 1. Preferably, the bottom part of the legs is made of material or equipped with a mechanism (such as a ball wheel) that reduces friction against the landing platform.

[0067] Landing platform 1 (FIGS. 1, 4, 10, etc.) is a part of ground station 8 for servicing UAV 2, acting as a surface on which UAV 2 lands. Platform 1 is designed for the required positioning and aligning of UAV 2 during and after landing, and is equipped with centering means configured to match and interact with supporting elements at the base of UAV.

[0068] The means for centering and positioning UAV 2 on landing platform 1 according to the present invention comprise of three principal elements: two rotating discs 3 with spiral guides and groove(s) 4, 4b (FIGS. 1, 4, etc.).

[0069] Landing platform 1 is a flat horizontal surface, on which said two rotatable flat horizontal discs 3 are arranged with possibility of rotation so that: [0070] their upper surfaces would be on a same level with the upper surface of platform 1; [0071] their axes of rotation would coincide with the axes of the main cylindrical legs 6 of UAV, received on the platform in the required end position (FIGS. 3, 6, 13).

[0072] The diameter of each disc 3 is chosen so as to ensure the required probability of receiving the cylindrical legs 6 of UAV 2 on the respective discs during landing, taking into account the positioning accuracy of UAV.

[0073] Based on the analysis of accuracy of positioning and keeping the azimuth of UAV in flight, and taking into account the influence of external factors, such as wind gusts, on UAV during the flight, it is possible to determine the probability of deviation of cylindrical leg 6 from the center of disc 3 . For example, deviation will be less than 50 mm for 50% of landings, deviation will not exceed 100 mm for 90% of landings, and deviation will not exceed 150 mm for 98% of landings.

[0074] The diameter of the disc is chosen to be equal to double deviation with the required probability of successful positioning. For example, 200 mm (2 x 100 mm) for 90 % of successful landings. In other words, the diameter of the disk is a compromise between its size (price, weight) and the probability of successful positioning after landing.

[0075] On the upper side of each disc 3 there is a continuous narrow spiral 5a, 5b (FIGS. 1, 4, etc.) protruding above the surface of the disk, made in the form of a strip, the edge of which is fixed on the surface of disc 3, and which ensures the maximum possibility of sliding of UAV supporting elements (legs 6, 7, 16) along the inner side surface of such a spiral guide. Each spiral 5 begins with an offset from the center of disc 3 and ends at the outer side of the disc. Furthermore, the spiral is left-handed 5b on one disk and is right-handed 5a on the other. Optimally, the spiral is logarithmic and comprises one to one and a half turns.

[0076] The height of spiral 5 corresponds to the height of cylindrical legs 6, 7, 16 of UAV, and the offset of the spiral beginning from center 21 of the disc corresponds to the radius of the cylindrical leg of UAV.

[0077] Cylindrical landing legs 6 are to be able to slide along the inner side surface of the respective spiral guides 5. For this purpose, they can be provided with cylindrical skirts, rotating freely around the axis of the leg. Under tangential force 25 from the side of spiral guide 5 (FIGS. 11, 12), each such leg moves towards the center of the respective disc 3, carried away by the curvature of spiral guide 5.

[0078] The thickness of the spiral, as well as the thickness of the disc, is determined by the required strength characteristics of the structure.

[0079] Furthermore, the platform is equipped with a narrow straight groove 4 (FIG. 1) arranged in such way, that: [0080] the line of groove 11 (e.g., FIG. 13) would be perpendicular and would pass through the center of the line connecting the centers of discs 3; [0081] the center of main landing leg 7 with retractable pin 15 of UAV, received on platform 1 in the required end position (for example, FIGS. 3, 13) would be in the groove line, optimally, in the center of the groove.

[0082] The width of groove 4 corresponds to the diameter of retractable pin 15 and the depth of the groove corresponds to the length of pin 15. Furthermore, the groove may be through (FIGS. 7, 8).

[0083] The length of groove 4 is chosen so as to ensure that retractable pin 15 of main landing leg 7 of UAV would fall into groove 4 when positioning and aligning UAV 2 on platform 1 after landing.

[0084] If the method of servicing UAV on the landing platform is compatible with two end positions, then platform 1 may comprise a second groove 4b (FIGS. 4, 8) arranged mirrored to the first groove 4 relative to the vertical plane passing through the centers of discs 3.

[0085] Accordingly, the serviced UAV 2 (FIG. 5) can be equipped with an additional fourth cylindrical leg 16, arranged at the fourth vertex of the imaginary or real square, while the main landing legs 6 and 7 are arranged at the remaining three vertices of the imaginary or real square (FIG. 5). In this case the principal condition is fulfilled since the main legs 6 and 7 are located at the vertices of the imaginary or real isosceles triangle at the base of UAV, formed by two adjacent sides 19 of the square and its diagonal 20. There may be more than one additional leg at the base of UAV, however any of them must be outside the imaginary isosceles triangle.

[0086] Discs 3 can be driven either separately by two drives 13 (FIGS. 7-9), or together by one drive joint via a belt, drive line or any other drive. Besides, the drives can be installed directly into the discs (hub motor). Discs 3 rotate in opposite directions so that spirals 5, arranged on them, perform a gripping movement during rotation.

[0087] A disc drive is an electric, hydraulic or pneumatic motor with or without a reducer, or is a threaded shaft 23 (FIG. 9), driven into rotation under the weight of UAV landed on a platform. Optimally, discs 3 are made of a water-resistant material such as anodized aluminum.

[0088] Platform 1 can be additionally equipped with sensors 22 of position and rotation of disc (FIGS. 7, 8) in order to detect malfunctions in the operation of the platform.

[0089] To provide access for the systems of ground station 8, which includes landing platform 1 as part thereof, to the payload and/or energy sources 30 of UAV 2, the platform may comprise one or more technological openings 14 (FIGS. 1, 4) arranged between disks 3 and groove(s) 4.

Description of System Operation

[0090] If platform 1 is not stationary at the ground station 8, then the ground station ensures such position of landing platform 1, which enables UAV 2 to land on it in normal mode. UAV 2 approaches and lands on landing platform 1 (FIGS. 10, 11, 12, 13). During landing UAV 2 on the landing platform, it is sufficient to ensure that two main cylindrical legs are on the respective discs 3 of platform 1, and the third leg 7 is in close proximity of one of the grooves 4 of the platform (FIG. 11).

[0091] After UAV lands on the landing platform, discs 3 are started to rotate in opposite directions 27, 28 (if one rotates clockwise, then the other rotates counterclockwise) so that spirals 5 (5a and 5b) would grip the legs 6 of UAV located on the disks and push them towards the centers of disks 3 (FIG. 12). Each disc 3 is rotated in its own direction, however always in the same direction.

[0092] If discs 3 are driven by threaded shaft 23, then, when UAV 2 is landing on platform 1, it presses the platform with its own weight (FIG. 9). When affected by this force, platform 1 descends and rotates shaft 23, which then rotates the discs with spirals 5, thereby positioning and aligning UAV 2.

[0093] Since for complete positioning and aligning of UAV a finite number of full revolutions of the disk (and therefore of the shaft) is required, not exceeding the number of spiral turns plus one, the system can be completely mechanical and does not require any external energy.

[0094] After the finite number of full revolutions of discs 3, the legs 6 and 7 of UAV, located on discs 3, are pushed by spirals 5 into the centers of discs 3, while the retractable pin 15 of third leg 7 is moved into one of the grooves 4 of the platform (as in FIG. 13). Therefore, UAV 2 is not only accurately positioned on platform 1, bet also precisely oriented relative to it.

[0095] Optionally, rotation of discs 3 stops at the moment when the beginnings of spirals 5 are blocking the legs 6 and 7 of UAV in centers 21 of discs 3, preventing UAV from leaving the end position on the platform under the action of external lateral factors (e.g., wind).

[0096] At completing of the positioning and aligning procedure, ground station systems perform the necessary manipulations (actions) with UAV payload and/ or energy sources 30.

Examples of Embodiments of Positioning and Aligning

1. Example of Positioning and Aligning of UAV With Three Main Legs at the Vertices of the Equilateral Triangle at the Base of Uav With Three Correct Alignments on the Platform

[0097] All three main legs of UAV are made the same - with a cylindrical skirt of the same diameter and having a retractable pin at the bottom. The diameter of the discs is slightly smaller than half the length of the side of the triangle at the base of UAV (for example, as in FIG. 13). The distance between centers 21 of the discs is equal to the length of side 31 of the triangle. The center of the groove is at the vertex opposite to the side, connecting the centers of the disks, and its length is equal to the length of the side of the triangle. The groove runs along the bisector of the triangle.

[0098] After the UAV has landed on the platform, the discs are starting to rotate in opposite directions 27, 28.

[0099] Since the platform, with the exception of the groove, and the discs form a continuous horizontal surface, the retractable pins of the legs of UAV, located on the platform discs after landing, are not pushed out and do not prevent the legs from sliding along the side surfaces of the spiral guides of discs during their rotation.

[0100] The spiral guides grip two of the three legs, located on the respective discs, and guide them toward their centers. During this movement, the third leg is forced to cross the groove on the platform at least once (see FIGS. 11 and 12), and, during such crossing, the pin of that leg is pushed downward and remains in the groove until the end of the positioning process. After fixing the retractable pin in the groove, the spiral guides of the discs, rotating in opposite directions, inevitably push the legs, located on them, to their centers. As a result, all three legs get into the correct position on the platform.

[0101] Correct alignment is when the retractable pin of any of the legs is in the groove of the platform, and the remaining two cylindrical legs are in the centers of the respective discs. All three possible positions are symmetrical with respect to rotation by 0, 120, and 240 (-120) degrees around the vertical axis passing through the center of the triangle.

[0102] The arrangement of the legs at the vertices of the equilateral triangle ensures the arrangement of the center of gravity of UAV on the axis passing through the center of the triangle (the point of intersection of its bisectors) and, accordingly, the optimal distribution of UAV weight on the legs.

2. Example of Positioning and Aligning UAV With Three Main Legs and One Additional Leg at the Vertices of the Imaginary Square With Two Correct Orientations on the Platform

[0103] The two main cylindrical legs are arranged at diagonally opposite vertices of the square, one of the remaining main legs is equipped with a retractable pin, and the fourth leg is an additional one.

[0104] The diameter of the discs is slightly smaller than half the diagonal of the square, and the distance between the centers of the discs is equal to the diagonal length of the square. The platform is equipped with two grooves, arranged along the diagonal of the square, perpendicular to the diagonal with the centers of the discs on it. The centers of the grooves are at the vertices of this diagonal, and the length of each groove is equal to the length of the side of the square. After the UAV has landed on the platform, the discs are rotated in opposite directions.

[0105] Since the platform, with exception of the grooves, and the discs form a continuous horizontal surface, the retractable pins of the UAV legs, located on the platform discs after landing, are not pushed out and do not prevent the legs from sliding along the side surfaces of the spiral guides of discs during disc rotation.

[0106] The spiral guides grip two legs, located on the respective discs, and guide them toward their centers. During this movement, the third main leg is forced to cross one of the grooves on the platform at least once, and, during such crossing, the pin of that leg is pushed down and remains in the groove until the end of the positioning process. After fixing the retractable pin in the groove, the spiral guides of the discs, rotating in opposite directions, inevitably push the legs, located on them, into their centers. As a result, all three legs get into the correct position on the platform.

[0107] Correct alignment is when the retractable pin of a respective leg is in one of the two grooves of the platform, and the remaining two cylindrical legs are in the centers of the respective discs. All two positions are symmetrical with respect to rotation by 0 and 180 (-180) degrees around the vertical axis passing through the center of the square.

[0108] The arrangement of the legs at the vertices of the square ensures the arrangement of the UAV center of gravity on the axis passing through the center of the square (the point of intersection of its diagonals) and, accordingly, the optimal distribution of UAV’s weight on the legs.

[0109] As can be seen from the above, compared to the known technical level, the proposed solution has the following advantages over the prior art both in the simplicity and reliability of the design solution and the efficiency of centering and aligning of the aerial vehicle: [0110] a) The platform does not require a strict UAV perimeter, particularly a symmetrical or round one. The weight of the proposed platform is lower; [0111] b) The spirals do not clamp the object at the center, but instead move the object to the center. The solution does not create any stress loads on the aerial vehicle and there is no risk of gripping it into the wrong position or damaging it during an improper landing; [0112] c) Flat continuous discs are driven by a conventional motor and do not require any additional complex mechanical systems to rotate them; [0113] d) The discs are not allowing water or dirt to pass through, on the contrary, they drain them away from the disc drives , acting as protective umbrellas; [0114] e) The groove is straight and, optimally, can be through (not blind), and does not require any mechanics installed under the groove. Therefore, grooves are not a factor for reducing reliability; [0115] f) Since the two discs center the two legs of the aerial vehicle, UAV is not only moved to the correct position on the platform, but is also correctly and unambiguously oriented onto it. [0116] g) If one or two legs of the aerial vehicle land on the spiral during landing, the legs will eventually jump it off as it rotates and end up on its outer side. In this case the spiral will automatically grip the leg on the next revolution of the disc and UAV centering will still end successfully; [0117] h) If the leg (one or two) of the aerial vehicle ends up on the outer side of the spiral during landing, then the spiral will automatically grip the leg on the next revolution and UAV centering will still end successfully; [0118] i) The proposed system does not require reset or preparation before landing UAV on it - it is possible to start rotation of the discs (each in its own correct direction, which is always the same one) before or after landing the aerial vehicle; [0119] k) The solution does not necessarily require end point position sensors and will not suffer in any way from, for example, constant disk rotation; [0120] l) Even if only one UAV leg got onto the disc during landing, there is still a high probability of its successful centering.

Industrial Applicability

[0121] Autonomous UAV service systems require correct positioning and aligning of UAV on the landing platform to charge their energy sources or to replace them or the payload. The described system is intended for such service systems and can be applied in the following areas: [0122] in autonomous pesticide spraying systems used in agricultural fields (requires autonomous filling of the spraying module and fast and frequent replacement of batteries); [0123] in solar power plant mirror or panel washing and cooling systems; [0124] in parcel, shopping, and medication delivery systems; [0125] in military intelligence and tactical systems on the basis of UAV; [0126] in perimeter monitoring systems for civilian and military facilities, and others.

[0127] List of positions:

[0128] 1 landing platform; [0129] 2 unmanned aerial vehicle (UAV) with vertical take-off and landing; [0130] 3 flat disk (centering element); [0131] 4 groove on the landing platform (centering element); [0132] 4b additional groove arranged symmetrically to the main one; [0133] 5 spiral guide on the disk, general view (5a right-handed, 5b left-handed); [0134] 6 main cylindrical landing leg; [0135] 7 main landing leg with retractable pin; [0136] 8 ground station; [0137] 9 imaginary or real triangle at the base of UAV; [0138] 10 center of imaginary or real triangle; [0139] 11 line along which the groove(s) are arranged; [0140] 12 one of the bisectors of imaginary or real triangle; [0141] 13 disk drive(s); [0142] 14 opening on the landing platform (1) for access to the payload and/ or energy sources of UAV (2); [0143] 15 retractable pin; [0144] 16 additional landing leg; [0145] 17 imaginary or real square at the base of UAV; [0146] 18 center of imaginary or real square; [0147] 19 one of the sides of imaginary or real square; [0148] 20 one of the diagonals of imaginary or real square; [0149] 21 center of disk; [0150] 22 disk position and/or rotation sensor; [0151] 23 threaded shaft driving the drive 13 into rotation under the weight of UAV; [0152] 24 landing direction of UAV 2; [0153] 25 direction of force of the action of the inner surface of spiral guide 5b on the cylindrical leg of UAV 2; [0154] 26 direction of forced movement of the main landing leg with retractable pin 15; [0155] 27 and 28 opposite directions of rotation of the discs ensuring the gripping movement of the spiral guides on them; [0156] 29 forced movement direction of the main landing leg with a retractable pin, where the pin is inserted into groove 4; [0157] 30 payload and/ or energy source of UAV; [0158] 31 base of imaginary or real triangle; [0159] 32 group of centering means comprising a pair of discs 3 and groove 4.