SK9608Y1 - Method of transforming a flying car and flying car - Google Patents

Abstract

The method of transforming a flying car is performed from airplane mode to car mode and reciprocally from car mode to airplane mode. The transformation from airplane mode to car mode taking place in phases. In the first phase: the upper fuselage cover (1) is opened above the centerplane together with propeller blade covers (2); the transformation of the flaps (3) and the wings (4) is started; the transformation of the outer parts (6) of the horizontal stabilizers on the tail surfaces (7) is started. In the second phase, the telescopic insertion of the entire set of tail surfaces (7) is initiated and the start of the insertion of the propeller blades (10) is initiated. In the third phase, the rotation of the wings (5) is started in the form of a rotation, during which the angle of the wing arrow (5) changes horizontally. In the fourth phase, the rotation of the wings (5) around the transverse axis of the centerplane is initiated, thus changing the vertical angle of the wing (5) and starting the rotation of the outer parts (8) of the wings (5) downwards around the transverse axis of the wing (5); the rear bumper transformation (9) is also started and completed. In the fifth phase, the wings (5) are connected in the plane of symmetry of the vehicle. In the sixth phase, the wings (5) are retracted and locked in the position intended for car mode and the upper fuselage cover (1) above the centerplane is also closed.

Description

SK 9608 Υ1

The field of technology

The technical solution concerns the method of transformation of the flying car and the construction of the innovative parts of the flying car itself. The technical solution belongs to the automotive and aviation industry.

Current state of the art

The current state of technology shows many means of transport, which contain the characteristics of cars and at the same time also of airplanes. It is e.g. vertical takeoff and landing VTOL aircraft with four jet engines that tilt vertically. The movement of this unusual means of transport on land is ensured by the same four jet engines, which are tilted to a horizontal position. For this reason, it is a very handicapped car.

Another representative of an unusual means of transport is the "Terrafugia Transition, described in the published patent application WO 2007/114877, which is basically a two-seater aircraft that is equipped with a four-wheel landing gear and folding wings, where each wing folds around two horizontal axes into an accordion shape and remains folded in a vertical position. The car takes on a bizarre shape.

Furthermore, there is a known hybrid means of transport described in patent EU 2 750 905 BI intended for movement on land and in the air, which has the shape of a sports car and at the same time a futuristic airplane. The wing transformation retains its original wing length, so after transforming from airplane mode to car mode, the car has the dimensions of an airplane in plan view, which is a handicap in road traffic.

Also known is a means of transport intended for movement on land and in the air, which is described in the published document WO 2018208237A1. The wing transformation retains its original wing length, so after transforming from airplane mode to car mode, the car has the dimensions of an airplane in plan view, which is a handicap in road traffic.

The mentioned facts led to the effort to create a concept of such a means of transport for movement on land and in the air, which would ensure a significant reduction in the length of the car after the transformation from airplane mode. The result of these efforts is this utility model application.

The essence of the technical solution

The mentioned shortcomings are eliminated by the method of transformation of the flying car and the flying car according to this technical solution. For protection purposes, the transformation from airplane mode to car mode is described in sequence. The transformation from car mode to airplane mode takes place analogously in the reverse order. The essence of the technical solution lies in the fact that the transformation of a flying car from airplane mode to car mode takes place in stages:

In the first phase, the upper fuselage cover above the centerplane is opened together with the propeller blade covers. In this same step, the transformation of the flaps and ailerons is initiated, by rotating around the axis of rotation located on the upper side of the wing skin. Simultaneously with the previous transformation processes, the transformations of the outer parts of the lower horizontal stabilizers located on the tail surfaces are started.

In the second phase of the transformation, the transformational movements from the first phase are completed. Next, the telescopic retraction of the entire assembly of tail surfaces is initiated and the retraction of the propeller blades is started.

In the third phase of the transformation, the wings are retracted in the form of rotation, during which the angle of the wing arrow changes. The transformation processes of flaps, ailerons, propeller blades and tail surfaces from the first and second phase of transformation are also completed.

In the fourth phase of the transformation, rotations of the wings around the transverse centerline axis are initiated, resulting in a change in the angle of the wing setting, during which the ends of the wings are raised above the fuselage and tail surfaces. After reaching the upper point of this wing rotation, the rotations of the outer parts of the wings are started. The transformation of the vehicle's rear bumper is also being launched and completed.

In the fifth phase of the transformation, the rotation of the wings from the third phase is completed, which brings about the connection of the wings in the plane of symmetry of the vehicle.

In the sixth phase of the transformation, the transformations of the wing around the transverse axis of the centerplane from the fourth phase are completed, during which the wings are inserted and secured in the position intended for the mod car and also the upper fuselage cover above the centerplane is closed.

SK 9608 Υ1

The solution of the flying car is based on the mentioned transformations according to the technical solution. The flying car is designed to drive on land and fly in the air. It consists of a fuselage, cabin, wings, tail, landing gear and propulsion units, two propellers located at the rear, a fuel tank and wheels with included reciprocal transformation mechanisms and other control, control, signaling, navigation and communication components. The essence of the solution is that the wings on the upper side have horizontal axes of transformation of flaps and ailerons to change the planar surfaces of the wings. Furthermore, at the place where the wings are stored in the center plane, the wings have vertical axes of transformation for turning the wings in the form of rotation with a horizontal change in the angle of the wing arrow. Also, the wings have transverse axes for rotation of the outer parts of the wings. The center plane has a transverse axis of rotation to change the vertical angle of the wings. Propellers have hinged propeller blade covers. The blades of the propeller are folded parallel to the axis of rotation of the propeller. The tail part can be translated into the body. The tail surfaces have the outer parts of the horizontal stabilizers located below. The tail surfaces have transverse transformation axes of the outer parts of the horizontal stabilizers. The rear bumper has a transformative folding mechanism. The upper fuselage cover above the center plane has a transverse tipping axis.

The advantages of the method of transforming the flying car and the flying car itself according to this technical solution lie in the fact that there is a full-scale transformation from one category of means of transport to another category of means of transport, resulting in a full-scale car or a full-scale aircraft.

A significant advantage of the technical solution is the reduction of the length of the transformed car by the length of the outer part of the wings. The folded wings are thus shorter, which is not achieved by any transformation of flying cars from the state of the art. According to the technical solution, the flying car gives the impression of a real van-type car, because the folded wings form one integrated unit of the roof. The folded blades of the propellers do not protrude from the side contours of the car, and the appropriately chosen folding tail surfaces create a complete surface of the rear part of the car.

Overview of images on drawings

The technical solution will be further explained in the drawings, where in fig. 1 is an oblique front view of a means of transport in the form of a car. In fig. 2 shows a vehicle in the form of a car in an oblique rear view. In fig. 3 shows a rear view of a means of transport in the form of a car. In fig. 4 is a front view of a means of transport in the form of a car. In fig. 5 is a side view of a means of transport in the form of a car. In fig. 6 shows a top view of a means of transport in the form of a car. In fig. 7 is an oblique front view of a means of transport in airplane mode. In fig. 8 is an oblique rear view of a means of transport in airplane mode. In fig. 9 shows a rear view of a means of transport in airplane mode. In fig. 10 is a front view of a means of transport in the form of a car. In fig. 11 is a side view of a means of transport in airplane mode. In fig. 12 is a top view of a means of transport in airplane mode. In fig. 13 is an oblique front view of a means of transport in airplane mode with the parts that are related to the transformations indicated. In fig. 14 is an oblique rear view of a vehicle in airplane mode with first stage transformations. In fig. 15 is an oblique rear view of an airplane-mode vehicle with second-stage transformations. In fig. 16 is an oblique rear view of a vehicle in airplane mode with third-phase transformations and completed second-phase transformations. In fig. 17 is an oblique rear view of a means of transport in airplane mode with completed third and second phase transformations. In fig. 18, 19, 20 is an oblique rear view of a vehicle in airplane mode with fourth phase transformations in three sequences. In fig. 21 is an oblique rear view of an aircraft mode vehicle with fifth stage transformations. In fig. 22 is an oblique rear view of an aircraft mode vehicle with stage five transformations completed.

Implementation examples

Individual realizations of the technical solution are presented for illustration and not as limitations of possible solutions. Those skilled in the art will find or be able to discover, using no more than routine experimentation, many equivalents to specific embodiments of the solution. Also like this

SK 9608 Υ1 equivalents will fall within the scope of the following protection claims. Optimal design of the system cannot be a problem for an expert familiar with the state of the art, therefore these features were not dealt with in detail.

In this example of a specific embodiment of the subject of the technical solution, a flying car in the car mode shown in fig. 1 to 6. In fig. 7 to 12, the flying car is shown in airplane mode. For the sake of clarity, fig. 1 to 12 without plotted positions of individual components of the flying car. The positions of the individual components of the flying car are shown in fig. 13. These are the positions of the individual components of the flying car that take part in the transformation actions of the flying car from airplane mode to car mode and also in reciprocal transformation actions. The components of the flying car that participate in the transformation actions of the flying car are the upper cover 1 of the fuselage, the wings 5, the wings 4, the lift flaps 3 and the outer parts of the wings 8. They are also the covers 2 of the blades 10 of the propeller and the blades of the propeller 10 themselves. Finally, there are the tail surfaces 7, the outer parts 6 of the horizontal stabilizers located on the lower part of the tail and the rear bumper 9. In addition to these components of the flying car, which directly participate in the transformation actions, the flying car also consists of a fuselage, a four-seater cabin, wings, tail, chassis and drive units, two propellers located at the rear, a fuel tank and wheels with included reciprocal transformation mechanisms and other control, control, signaling, navigation and communication components.

In this example of a specific embodiment of the subject of the technical solution, the method of transforming a flying car from airplane mode to car mode is described, which is shown in fig. 14 to 22 with the support of fig. 13, where the positions of the individual components of the flying car participating in the transformations are plotted. The transformation of a flying car from airplane mode to car mode takes place in stages:

In the first phase, fig. 14, the upper cover 1 of the fuselage above the centerplane is opened together with the covers of the 2 blades 10 of the propeller. In this same step, the transformation of flaps 3 and ailerons 4 is started, by rotating around the rotation axis located on the upper side of the wing cover 5. Simultaneously with the previous transformation processes, the transformations of the outer parts 6 of the lower horizontal stabilizers located on the tail surfaces 7 are started.

In the second phase, fig. 15, transformations are completed transformational movements from the first phase. Next, the telescopic retraction of the entire assembly of tail surfaces 7 and the start of retraction of the propeller blades 10 are initiated.

In the third phase, fig. 16, the transformation is triggered by the insertion of the wings 5 in the form of rotation, during which the angle of the arrow of the wing 5 changes. The transformation processes are also terminated, fig. 17, flaps 3, wings 4, propeller blades 10 and tail surfaces 7 from the first and second phase of transformation.

In the fourth phase, fig. 18, the transformations are initiated by the rotation of the wings 5 around the transverse axis of the centroplane, resulting in a change in the angle of adjustment of the wing 5, during which the ends of the wings 5 are raised above the fuselage and tail surfaces 7. After reaching the upper point of this rotation of the wing 5, the rotations of the outer parts are started 8 wings 5, fig. 18,19, 20. The transformation of the rear bumper 9 of the vehicle is also started and completed.

In the fifth phase of the transformation, the rotation of the wings 5 from the third phase is completed, resulting in the connection of the wings 5 in the plane of symmetry of the vehicle, fig. 21.

In the sixth phase of the transformation, the transformations of the wing 5 around the transverse axis of the centerplane from the fourth phase are completed, during which the wings 5 are inserted and secured in the position intended for the car mod and also the upper cover 1 of the fuselage above the centerplane is closed, fig. 22.

Industrial applicability

The method of transforming the flying car and the flying car according to the technical solution finds use in the aviation and automotive industries.

Claims (3)

SK 9608 Υ1 CLAIMS FOR PROTECTION 1. A method of transforming a flying car, characterized by the fact that the transformation is carried out from plane mode to car mode and also reciprocally from car mode to plane mode, while the transformation from plane mode to car mode takes place in phases: in the first phase the upper cover (1) of the fuselage above the center plane is opened together with the covers (2) of the blades (10) of the propeller; the transformation of flaps (3) and ailerons (4) is started by rotating around the axis of rotation located on the upper side of the wing (5) and the transformation of the outer parts (6) of the horizontal stabilizers on the tail surfaces (7) is started by rotating around the axis of rotation located on the upper side tail surfaces (7); in the second phase, the transformation movements from the first phase are completed and the telescopic retraction of the entire assembly of tail surfaces (7) is initiated, and the initiation of retraction of the blades (10) of the propeller is also initiated; in the third phase, the folding of the wings (5) is started in the form of rotation, during which there is a horizontal change in the angle of the arrow of the wing (5) and the transformation movements from the first and from the second phase are completed; in the fourth phase, the rotation of the wings (5) is initiated around the transverse axis of the centroplane, resulting in a change in the vertical angle of the wing (5), during which the ends of the wings (5) rise above the fuselage and tail surfaces (7) and after reaching the upper point this rotation of the wing (5) starts the rotation of the outer parts (8) of the wings (5) downwards around the transverse axis of the wing (5); the transformation of the rear bumper (9) is also started and completed; in the fifth phase, the rotation of the wings (5) from the third phase is completed, resulting in the connection of the wings (5) in the plane of symmetry of the vehicle; in the sixth phase, the transformation of the wings (5) around the transversal axis of the centerplane downwards from the fourth phase is completed, during which the wings (5) are inserted and secured in the position intended for the mod car and also the upper cover (1) of the fuselage above the centerplane is closed. 2. A method of transforming a flying car, characterized in that the transformation from car mode to airplane mode is carried out reciprocally with the course of actions from the sixth phase to the first phase. 3. A flying car adapted for driving on land and flying in the air consisting of a fuselage, cabin, wings, tail, landing gear and drive units for two propellers located at the rear and for driven wheels with included reciprocal transformation mechanisms, reciprocally transforming according to claims 1 and 2 , characterized in that the wings (5) on the upper side have horizontal axes of transformation of flaps (3) and ailerons (4) to change the planar surfaces of the wings (5); at the location of the wings (5) in the center plane, the wings (5) have vertical axes of transformation for bending the wings (5) in the form of rotation with a horizontal change in the wing arrow angle (5); the wings (5) have transverse axes for rotation of the outer parts (8) of the wings (5); the centroplane has a transverse axis of rotation for a vertical change in the wing adjustment angle (5); the propeller has hinged covers (2) of the propeller blades (10); blades (10) of the propeller are foldable parallel to the axis of rotation of the propeller; the tail part is translationally retractable into the body; the tail surfaces (7) have transverse transformation axes of the outer parts (6) of the lower horizontal stabilizers; the rear bumper (9) has a transformative folding mechanism; the upper cover (1) of the fuselage above the center plane has a transverse tipping axis. 11 drawings