PLATFORM FOR FACILITATING THE LANDING ON ANY DESIRED COORDINATES, DOCKING, AND RETAKE-OFF OF DEFINED MULTI-PROPELLER AIRCRAFTS / UNMANNED AERIAL VEHICLES

Abstract

A system used to facilitate the landing of unmanned aerial vehicles on any desired coordinates, and docking and retake-off of them includes a motor operating the platform, a LED lighting employed for an operation of the system under low light conditions, electromagnetic magnets used for fixing the unmanned aerial vehicle on the platform, a transformer box used to supply electrical energy needed by the electromagnetic magnets and the LED lighting, a control cards box hosting control cards employed to control operations of junction boxes, the motor and the electromagnetic magnets, and a cable box through which connection cables of the system pass.

Claims

1. A system used to facilitate a landing, docking and retake-off of an unmanned aerial vehicle on any desired coordinates, wherein the system is used by the following steps: after receiving a command via a mobile phone mobile application or from a main control centre, activating a platform standing in an inactive position to turn into an active position of 90 degrees permitting the landing of the unmanned aerial vehicle; activating electromagnetic magnets to dock and interlock the unmanned aerial vehicle to the platform, and the unmanned aerial vehicle remaining interlocked with the platform during a product delivery process; and after manually receiving a cargo, deactivating the electromagnetic magnets to release the unmanned aerial vehicle, wherein the unmanned aerial vehicle becomes ready for a flight and takes off from the platform.

2. The system according to claim 1, further comprising: a motor operating the platform, a LED lighting employed for an operation of the system under low light conditions, the electromagnetic magnets used for fixing the unmanned aerial vehicle on the platform, a transformer box used to supply electrical energy needed by the electromagnetic magnets and the LED lighting, a control cards box hosting control cards employed to control operations of junction boxes, the motor and the electromagnetic magnets, and a cable box, wherein connection cables of the system pass through the cable box.

3. The system according to claim 1, wherein a main body of the platform comprises a rear cover, a main carrier bar, a roller bearing carrier, a body left side part, a body right side part, a body bottom part, and a body top part.

4. The system according to claim 1, further comprising a retaining disk and a motor roller bearing carrier, wherein the motor roller bearing carrier ensures a use of the platform after being fixed to a desired place and combines a rear cover, a main carrier bar, a roller bearing carrier, a body left side part, a body right side part, a body bottom part, and a body top part.

5. The system according to claim 1, further comprising a motor roller bearing carrier and a motor.

6. The system according to claim 1, wherein the platform is insulated with waterproof features, is coated by a water- and dirt-repellant nanocomposite coating, and is operable at a temperature range of −20 degrees centigrade to +60 degrees centigrade, wherein a structure of the platform is made of an ultraviolet (UV) resistant material, and the platform further comprises aa insulation band.

7. The system according to claim 2, further comprising a motor roller bearing carrier.

8. The system according to claim 3, further comprising a motor roller bearing carrier and a motor.

9. The system according to claim 4, further comprising a motor.

10. The system according to claim 2, wherein the platform is insulated with waterproof features, is coated by a water- and dirt-repellant nanocomposite coating, and is operable at a temperature range of −20 degrees centigrade to +60 degrees centigrade, wherein a structure of the platform is made of an ultraviolet (UV) resistant material, and the platform further comprises an insulation band.

11. The system according to claim 3, wherein the platform is insulated with waterproof features, is coated by a water- and dirt-repellant nanocomposite coating, and is operable at a temperature range of −20 degrees centigrade to +60 degrees centigrade, wherein a structure of the platform is made of an ultraviolet (UV) resistant material, and the platform further comprises an insulation band.

12. The system according to claim 4, wherein the platform is insulated with waterproof features, is coated by a water- and dirt-repellant nanocomposite coating, and is operable at a temperature range of −20 degrees centigrade to +60 degrees centigrade, wherein a structure of the platform is made of an ultraviolet (UV) resistant material, and the platform further comprises an insulation band.

13. The system according to claim 5, wherein the platform is insulated with waterproof features, is coated by a water- and dirt-repellant nanocomposite coating, and is operable at a temperature range of −20 degrees centigrade to +60 degrees centigrade, wherein a structure of the platform is made of an ultraviolet (UV) resistant material, and the platform further comprises an insulation band.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0015] The invention will be described with reference to the figures attached hereto, thus making sure that the specifications of invention are better understood and acknowledged, but its purpose is by no means to limit the invention with these drawings. On the contrary, it is intended to cover all alternatives, modifications and equivalences that may be included in the field of the invention described by the claims attached hereto. It should also be understood and noted that the details given herein are shown only to describe the preferred arrangements of the present invention, and that they are presented in order to give the most practical and easily understandable definition of both shaping of the methods and rules and conceptual features of the invention. These drawings are as listed below:

[0016] FIG. 1 shows a general appearance of the platform in inactive and active positions.

[0017] FIG. 2 shows an assembled appearance of components of the system.

[0018] FIGS. 1-2 aim to help the comprehension of this invention are numbered as specified in the drawing attached hereto, and are named and listed below.

REFERENCE NUMBERS IN DRAWINGS

[0019] 1. Rear cover [0020] 2. Main carrier bar [0021] 3. Retaining disk [0022] 4. Roller bearing carrier [0023] 5. Motor roller bearing carrier [0024] 6. Motor [0025] 7. Body left side part [0026] 8. Body right side part [0027] 9. Body bottom part [0028] 10. Body top part [0029] 11. Rubber insulation band [0030] 12. LED lighting [0031] 13. Electromagnetic magnets [0032] 14. Transformer box [0033] 15. Junction boxes [0034] 16. Control cards box [0035] 17. Cable box [0036] 18. Main body

DETAILED DESCRIPTION OF THE EMBODIMENTS

[0037] This invention is related to a system used to facilitate the landing of unmanned aerial vehicles on any desired coordinates, and docking and retake-off of them.

[0038] This invention is characterized by a combination of rear cover (1), main carrier bar (2), retaining disk (3), roller bearing carrier (4), motor roller bearing carrier (5), motor (6), body left side part (7), body right side part (8), body bottom part (9) and body top part (10) as shown in FIG. 2, thereby building a platform assuring safe landing of unmanned aerial vehicles even under inappropriate weather and ground conditions, as detailed in FIG. 1.

[0039] Control cards box (16), thanks to Arduino, motor and electromagnetic magnet control cards contained therein, transmits to motor (6) the signals received from main control centre or via mobile phone mobile application, and first of all, activates (opens) the platform for landing of unmanned aerial vehicle. On the platform activated at the time of landing, in line with the signals received from control cards, electromagnetic magnets (13) under body top part (10) are activated, to make sure that unmanned aerial vehicle lands safely and stably. Then, unmanned aerial vehicle is interlocked with platform via electromagnetic magnets (13) under body top part (10), and remains fixed and still during manual receipt of the cargo carried.

[0040] This invention includes a platform used for safe landing and take-off of unmanned aerial vehicles. Parts constituting the main body (18) of said platform are rear cover (1), main carrier bar (2), roller bearing carrier (4), body left side part (7), body right side part (8), body bottom part (9) and body top part (10).

[0041] Furthermore, the invented system also includes a retaining disk (3) and AC motor and roller bearing carrier (5) employed for fixing and retaining the platform at any place desired.

[0042] Said platform contains a cooling unit, is insulated with waterproof features, is coated by water- and dirt-repellant nanocomposite coating, and is operable at a temperature range of −20 to +60 degrees centigrade thanks to its structure made of ultraviolet (UV) resistant material, and the insulation band (11) included therein.

[0043] In this invention, the platform is ensured to turn into the desired position thanks to motor (6) included in motor roller bearing carrier (5). Motor (6) activates the platform to turn into active (open) or inactive (closed) positions in line with signals received from main control centre or via mobile phone mobile application.

[0044] Furthermore, as the invented system contains a physical programming platform, it may also be controlled via internet.

[0045] In addition, the invented system ensures delivery of cargo at the correct point of destination without any deviation in landing point via its neural networks and visual mapping—image processing.

[0046] While the platform is inactive (closed), unmanned aerial vehicle visually reads the QR code marked on the platform and confirms that it is at the correct point of destination. Platform contains a LED lighting (12) for effective operation of visual activities under low light conditions.

[0047] After unmanned aerial vehicle is landed, when it is required to take off, electromagnetic magnets (13) under body top part (10) are deactivated in line with signals received from control cards to release the unmanned aerial vehicle, thus making the unmanned aerial vehicle ready to take off.

[0048] Furthermore, the invented system contains a 12V transformer in transformer box (14) in order to supply electrical energy needed by electromagnetic magnets (13) and LED lighting (12).