MXPA03008574A - Lift-providing unit for levitating a platform. - Google Patents

Abstract

A lift-providing unit including two weight units disposed at opposite ends of a rotating armature, at least one of the weight units being capable of generating a recoil force. Lift is provided by the recoil force multiplied by the centripetal force of the rotating armature.

Description

UNIT TO PROVIDE SUSTAINABILITY TO LIFT A PLATFORM BACKGROUND OF THE INVENTION 1. Field of the invention. This invention relates to a unit for generating lift to lift and direct a platform, more specifically a unit for generating lift that uses recoil, impact and centripetal forces to lift and direct a platform on which the unit is held. 2. Previous Technique Flying is an activity that has been known for centuries. The birds use it as a means of migration, hunting and shelter. It has always fascinated humans to travel in air. However, it has only been to our recent past that humans have produced machines capable of sustained flight, for example, airplanes, helicopters, rockets and hovercrafts. These flying machines generate their lift using rotors, propellers, gas or compressed liquid. For example, the sustentation in. Sliding vehicles is supplied by means of compressed air from the bottom of the vehicle using a rotating rotor quickly and allowing the compressed air to generate the lift of the vehicle.

Said device has the inconvenience that it can not generate the lift in a vacuum, that is, in outer space. Machines that generate vacuum lift typically expel gases through a port located at the base of the vehicle. There is a need for other methods to generate vacuum lift. Additionally, there is always the need to find new ways to fly for the human being.

SUMMARY OF THE INVENTION This invention satisfies the aforementioned needs. A novel unit has now been discovered to generate vacuum lift. The support generating unit of the present invention uses a rotating frame with a movable piston mounted thereon. The lift is produced by coupling the forces generated by the rotation of the armature while simultaneously moving the plunger during rotation. In one embodiment, the recoil force generated by moving the plunger, using centripetal force, generated by the rotation of the armature, is used to provide lift. In another embodiment of the invention, the impact force generated by moving the plunger in conjunction with the centripetal force generated by the rotation of the armature is used to provide the lift. The difference between the recoil and impact forces is essentially the position of the plunger and the direction in which it moves during the rotation of the armature. In both embodiments, an armature that rotates about a horizontal axis is used to provide the centripetal force while a movable piston mounted on the armature is employed to provide the recoil / impact forces. The armature rotates in a vertical plane. A frame with a horizontally oriented axis provides the horizontal axis and the support, around which the armature rotates. In both modes, the horizontal directional movement is carried out by mechanically rotating the armature in its vertical plane using a pinion that would allow the armature to direct the force at any horizontal angle when needed. If these armor were rotating in a horizontal plan, they would require a rotary mass to prevent the entire unit from rotating. However, this can be adapted if desired. To provide recoil force, the plunger moves in one. Vertical direction down during rotation. To provide a recoil force during the upper half of the rotation, the plunger moves from a far position to a close to the axis. To provide the recoil force during the lower half of the rotation, the plunger moves from a position close to a distance away from the axis. Being the upper half of the rotation between 270 ° and 90 °, assuming a clockwise rotation with 360 ° / 0 ° at the top; and the lower half of rotation being between about 90 ° and 270 °, assuming rotation in the clockwise direction and 360 ° / 0 ° in the upper part. The recoil force can be generated either only during one. half or during both halves of the rotation. In any case, the plunger should always be placed away from the axis during the lower half of the rotation and near the axis during the upper half of the rotation. It will be understood that the current distance between the axis and the plunger will vary and that close to the axis does not mean close to the axis. To provide the impact force, the plunger moves in a vertical direction upward during rotation. To provide an impact force during the upper half rotation, the plunger moves from a position close to a distance from the axis. To provide an impact force during the lower half of the rotation, the plunger moves from a far position to a close to the axis. The upper and lower halves of the rotation are as defined above. The impact force can be generated either for only one half or both halves of the rotation. In any case, the plunger should always be placed near the axis during the lower half of the rotation and away from the axis during the upper half of the rotation. It is preferable that more than one plunger can be used in the present invention. Where a variety of emboli are used, they are equiangular around the e and are placed in a common vertical plane. Preferably, there is an even number of plungers and, more preferably, 2 or 4 plungers.

BRIEF DESCRIPTION OF THE DRAWINGS These and other features, aspects and advantages of the present invention can be understood with reference to the following drawings, wherein: Figure 1 is a sectional side view of a preferred embodiment of the invention; Figure 2 shows a view of the base of the preferred embodiment in Figure 1; Figure 3 shows a sectional view of another preferred embodiment of the invention; Figure 4 shows a top view of the preferred embodiment of Figure 3.

• Figure 5 shows a sectional view of another preferred embodiment of the invention; Figure 6 shows a top view of the preferred embodiment of Figure 5; Figure 7 shows a sectional view of another preferred embodiment of the present invention; Figure 8 shows a base view of the preferred embodiment of Figure 7; Figure 9 shows a sectional view of another preferred embodiment of the present invention; Figure 10 shows a sectional side view of another embodiment of the present invention; Figure 11 shows a top view of the preferred embodiment of Figure 10; Figure 12 shows a side view of another preferred embodiment of the present invention; Figure 13 shows a top view of the preferred embodiment of Figure 12.

DETAILED DESCRIPTION OF THE INVENTION The present invention is directed to a unit for generating lift that has a plunger for generating recoil / impact energy, which uses centripetal force to generate vertical and horizontal lift. This first embodiment of the present invention can be characterized as a horizontal oscillating and electromagnetic sphere motor. As shown in Figure 1, this modality uses an electromechanical arrangement for the recoil device. To accomplish this, the devices for generating the recoil are placed on opposite ends of a rotating armature. For levitation, each device is activated to generate recoil when it is in the upward position of the armature rotation to generate downward force, which causes an equal and opposite lift force. By continuously activating recoil devices, each time one of the recoil devices is in the up position, this way the lift can be maintained. Referring to Figure 1, there is shown an inventive unit that provides lift in which the recoil device comprises an electromechanical array. Each recoil device comprises an electromagnet (1) and a sphere (2) having magnetic permeability. Each electromagnet (1) is placed inside a tube (3) and each tube (3) is mounted on a rotating armature (4). The electromagnet (1) is placed near the center of the tube (3), in relation to the length of the tube, so that it looks out from the center of rotation and has limited movement inside the tube (3). The movement of the electromagnet (1) is restricted by means of the bracket (5) supporting the electromagnet which also provides electrical current when needed. The electromagnet (1) receives electrical energy from the electrical conductor (14) through the electrical contact (13) located in the toothed area (15). When the unit is inactive, the sphere (2) can rest on a rubber stop (6) mounted on the retaining plate (7) secured to the outer end of the tube (3). However, depending on the position of the rotating frame (4) when it is not moving, the sphere (2) can rest on a magnetic protection pad (8) located on the outermost surface of the electromagnet (1). In this way, the electromagnet (1) and the retaining plate (7) restrict the movement of the sphere (2). The motor (9) driving the armature applies energy to the rotating armature (4) in a vertical plane. The motor (10) to change direction the armature is connected to the arrow (11) located in the stationary part (16). The stationary part (16) is mounted on the base (17) and is able to move through the use of the wheels (18). The arrow (11) in turn is connected to the gears (12) to provide horizontal directional movement of the support (19) of the frame. The rotation of the armature (4) supplies the required centripetal force. Assuming that each sphere (2) weighs 200 pounds, the armature (4) can be rotated at a speed in which each of the spheres (2) exhibits an apparent weight of 4,500 pounds, due to the artificial gravity generated by the centripetal acceleration. Of course, these numbers are used as an example. Once the centripetal acceleration is established by the rotation of the armature (4) by the drive motor (9) of the armature, the electromagnet (1) and the sphere (2) reach their respective travel limits within the tube (3). ). At this point, the sphere (2) is placed at a distance far from the electromagnet (1) and rests against the retaining plate (7) due to the centripetal force. Now the unit is on hold, ready. An address can be selected for the movement of the complete unit by means of a control system (not shown). When the rotating armature (4) is in a position corresponding to the selected direction, an electronic detector or photoelectric cell (not shown) energizes the electromagnet (1) which in turn attracts the sphere (2) towards the axis of rotation , thus generating a recoil force. The complete unit is forced to move in the direction of the incoming sphere (2) by this recoil force. As the sphere (2) moves towards the axis of rotation, the artificial gravity generated by the centripetal force begins to slowly lower the sphere (2) to a stop. The sphere (2) will then reverse the direction, and will travel back to rest against the retainer plate (7) again. The previous process is repeated in each rotation and, due to the high proportion of revolutions of the reinforcement (4), the lift can be maintained. By controlling the amount of energy. directed to the electromagnet (1), the amount of lift can be controlled. An inadvertent impact of the sphere (2) against the electromagnet (1) will not prevent or counteract the recoil energy. The electromagnet (1) has limited movement inside the tube (3) that helps to absorb the impact of the sphere (2). A second preferred embodiment of the invention relates to a horizontal motor of oscillating screw weight. Said motor uses a mechanical arrangement for the recoil action to generate the directional movement. This is achieved by rapidly propelling a mass towards the center of rotation of a rotating armature causing the axis of rotation to move in the direction of the incoming mass due to the recoil reaction. The centripetal force created by the rotating armature against acts the mass before it hits the axis of rotation, which is necessary because the impact would prevent the recoil reaction. Figure 3 illustrates the horizontal oscillating screw weight motor configuration. The rotating armature (4) is composed of the screw arrow (21) and the parallel rods (22). The rods (22) are mounted in such a way that they allow the movement of the oscillating weight (20) to lo. along the axis of rotation of the reinforcement (4). The oscillating weight (20) is also perforated in the center from side to side through where the screw arrow (21) passes, which is driven by the driving motor (23) allowing controlled movement of the swing weight (20). The weight (20) incorporates the disengagement system (24) allowing the oscillating weight (20) to move along the parallel rods (22) disabled by the screw arrow (21). Once the armature driving motor (9) establishes the centripetal acceleration of the rotating armature (4), the oscillating weight (20) will reach its travel limit and will rest on the retaining plate (7). The disengagement system (24) is activated, holding the oscillating weight (20) in the screw shaft (21). Now the unit is in standby, ready. When the operator of the machine selects a travel direction, the driving motor (23) of the screw arrow is activated at a point during the rotation of the armature corresponding to the selected travel direction. In this way the motor (23) rotates the screw arrow (21) by propelling the oscillating weight (20) rapidly towards the axis of rotation. The entire unit moves in the direction of the incoming weight due to the recoil forces. Before the oscillating weight (20) impacts the axis of rotation, the disconnection system (24) is deactivated, releasing the oscillating weight (20) of the screw arrow '(21). Now the centripetal force prevents the movement of the oscillating weight (20), bringing it to a stop, reversing its direction and supporting it once more against the retaining plate (7). This method of operation is repeated again until the desired location of the trip is reached. A third preferred modality of the. present invention relates to a horizontal gear of oscillating weight of gear. Said motor mainly uses the -action of recoil to achieve the directional movement, however some impact action is also possible. This is carried out by a mass propelled rapidly towards the center of rotation of a rotating armature which causes the axis of rotation to move in the direction of the incoming mass due to the recoil reaction. The centripetal force created by the rotating armature against acts the mass before it hits the axis of rotation, which is necessary because the impact could impede the recoil reaction. Figure 5 illustrates the configuration of the horizontal oscillating gear weight motor. The rotating frame (4) is composed of the rack (25) and the guide rods (26). Four meshing weights (27) are mounted along the rack (25), two on each side of the rack (25), the teeth of each mesh weight (27) are capable of intersecting the gaps corresponding to length of the rack (25) to allow controlled movement of the engagement weight (27) 'along the rack (25). The meshing weight (27) is connected to the gear weight motor assembly (28), which in turn is mounted near the guide rods (26). The gear weight motor (28) allows controlled movement of the gear weight (27) along the rack (25). Once the armature driving motor (9) establishes the centripetal acceleration of the rotating armature (4), the meshing weight (27) and the meshing weight motor (28) will reach their travel limits and will support on the top (29a) of the gear weight travel. The disengagement system (24) is activated by holding the meshing weight motor (28) on the guide rods (26). Now the unit is on hold, ready. . When the operator of the machine selects a travel direction, the gear weight motor (28) is activated at a point during the rotation of the armatures corresponding to the selected travel direction. The gear weight motor (28) rotates the gear weight (27) thereby rapidly propelling the gear weight (27) and the gear weight motor (28) towards the axis of rotation. The entire unit moves in the direction of the incoming weight due to the recoil forces. Before the meshing weight (27) and the meshing weight motor (28) impact the axis of rotation the disengagement system (24) is deactivated, thereby releasing the meshing weight motor (28) of the guide rods (26) Now, the centripetal force impedes the movement of the meshing weight (27) and the motor (28), bringing the meshing weight (27) and the motor (28) to a stop, reversing their direction and once again supporting them against the stop (29a) of the gear weight travel. The travel weight stop (29b) is positioned to prevent the weight of the gear (27) and the gear weight motor (28) from being impacted with the axis of rotation, in the event that the centripetal forces do not they are strong enough to prevent and completely propel the weight of the gear (27) and the gear weight motor (28) against its support against the stop (29a) of the gear weight travel. This method is repeated once more until the desired location of the trip is reached. A fourth preferred embodiment of the present invention relates to a lateral oscillating lateral solenoid motor. Said motor uses the action of impact and recoil to carry out the directional movement. This is done by rapidly propelling a mass towards the center of rotation of a rotating armature, which causes the axis of rotation to move in the direction of the incoming mass due to the backlash reaction. The centripetal force created by the rotating armature against acts on the mass before it hits the axis of rotation, which is necessary because the impact would prevent the recoil reaction. Figure 7 illustrates the configuration of the lateral oscillating solenoid motor. The rotating armature (4) is composed of the parallel guide rails (30). The solenoid plunger (31) is mounted on, and is capable of freely moving around, the parallel guide rails (30) through the use of electrical contact rollers (32). The solenoid plunger (31) receives electrical energy from the electrical contact rollers (32) through the solenoid coil (33) and allows controlled movement of the solenoid plunger (31). The range of movement of the solenoid plunger (31) is limited by the housing (34) of the solenoid. Once the armature driving motor (9) establishes the centripetal acceleration of the rotating armature (4), the solenoid piston (31) will reach its travel limit and will rest on the rubber stop (35a). Now the unit is on hold, ready. When the operator of the machine selects a direction of travel, the electrical energy activates the plunger of the solenoid (31) at a point during the rotation of the armature corresponding to the selected travel direction. Thus, the solenoid plunger (31) is rapidly propelled towards the axis of rotation. The entire unit moves in the direction of the incoming weight due to the recoil forces. Before the solenoid plunger (31) impacts the axis of rotation, the source of electrical energy is deactivated. Now, the centripetal force prevents the movement of the solenoid plunger (31), bringing it to the stop, reversing its direction and once again leaning against the rubber stop (35a). The rubber stop (35b) is positioned to prevent the solenoid plunger (31) from hitting the axis of rotation, in the event that the centripetal forces are not strong enough to prevent and fully propel the solenoid plunger (31) to his support against the rubber stop (35a). The horizontal directional movement of the support (19) of the reinforcement is controlled by the piston and the crossbar (36), more than by the arrow (11) and the gears (12) as in the previous mode. This method of operation is repeated continuously until the destination of the trip is reached. A fifth preferred embodiment of the present invention relates to a horizontal oscillating impact motor. Said motor mainly uses the impact action to carry out the directional movement. This is achieved by turning an armature to hit a stationary mass with which directional movement is caused in the direction of impact. The centripetal force created by the rotating armature can be varied to control the impact action. Figure 9 illustrates the configuration of the horizontal oscillating impact motor. The rotating armature (4) is constituted by a folding geomantic frame (37) and a frame wheel (38), which are housed within a lining (39) for lubrication purposes. On the outer circumferential surface of the liner (39) lies a pinion lock (40). The pinion lock (40) acts to control the movement of the retractable ramp (41) once the impact action is carried out. When the operation is desired to begin, the hydraulic piston (42) releases tension in the spring (43) enabling the retractable ramp (41) to retract completely and place its elongated end outside the liner (39). The armature driving motor (9) then begins to establish the centripetal acceleration of the rotating armature (4), and the frame (37) will extend and allow the frame wheel (38) to make contact with the inner wall of the lining (39). Now the unit is ready, waiting. When the operator of the machine selects a travel direction, the position gear (44) rotates the gear (45) to assist the retractable ramp (41) in a direction corresponding to the selected travel direction. The hydraulic piston (42) and the spring (43) now increase the force against the narrowed end of the retractable ramp (41), allowing the elongated end of the retractable ramp (41) to enter into the inner wall of the liner (39). ). The rotating wheel of the frame (38) impacts the retractable weight (41) on the impact driving line (46). The impact driving line (46) is propelled at the point of impact (47) mounted on the liner (39). The entire unit moves in the direction of the retractable ramp (41) propelled due to the impact action. The weight (48) supplies an additional impact force, which is mounted on and travels along the frame (37). A sixth embodiment of the present invention relates to a horizontal oscillating external impact sphere motor. Said motor uses the recoil action to achieve the directional movement. The recoil action is achieved by rapidly propelling a mass towards the center of rotation of a rotating armature which causes the axis of rotation to move in the direction of the incoming mass due to the recoil reaction. The centripetal force created by the rotating armature against acts the mass before it hits the axis of rotation, which is necessary because the impact would prevent the recoil reaction. Figure 10 illustrates the configuration of the horizontal oscillating external impact sphere motor. The platform extension (49) supports the outer tube (50) in the rotating frame (4). The outer tube (50) accommodates the piston-like unit (51), which in turn houses the sphere (52), the configuration of which allows the sphere (52) to oscillate within the piston-like unit ( 51). Said unit (51) similarly is able to move inside the outer tube (50). In the outer tube (50) there is an opening located on the outside of the rotating frame (4). This opening allows the coil (53) of the solenoid and the plunger (54) to make contact with the sphere (52). On the inner side of the outer tube (50) There is an air vent (55) to allow air to escape during the oscillation of the piston-like unit (51). • This unit is also equipped with a reverse rotating platform (56) that rotates in the reverse direction of the rotating frame (4) to stabilize the unit. The rotating platform (56) is constituted by the extension (57) and by the fixed sphere (58). Similar to the centripetal acceleration established by the rotating armature (4), the rotating platform (56) establishes its own centripetal acceleration of the fixed sphere (58) by rotating in the opposite direction to the. rotating armature (4). In this way the force generated by the rotating armature (4) is counter-actuated and neutralized by that of the rotating platform (56) enabling the unit to remain in a stable state. The reverse rotation is achieved with the gearbox of the transmission unit (59). Once the driving motor (9) of the armature establishes the centripetal acceleration of the rotating armature (4), the piston-like unit (51) and the sphere (52) reach their travel limits within the outer tube (50) . Now the unit is waiting, ready. When the operator of the machine selects a direction of travel, the coil of the solenoid (53) is energized at a point during the rotation of the reinforcements corresponding to the selected travel direction. The solenoid coil (53) causes the plunger (54) to strike the sphere (52), thus rapidly propelling the sphere (52) inward toward the axis of rotation. The sphere (52) then strikes the piston-like unit (51), causing said unit (51) together with the solenoid coil (53) and the plunger (54) to also be driven inward. The entire unit moves in the direction of the incoming weight due to the recoil forces. At a point before the piston-like unit (51) impacts the axis of rotation and before the sphere (52) hits the impact protection bearing (60), the centripetal force will impede the movement of the unit similar to piston (51) and sphere (52), leading the piston-like unit (51) and sphere (52) to a stop, reversing its direction, supporting the piston-like unit (51) against the piston plate. retention (61) and sphere (52) against the plunger (54). The retainer plate (62) of the plunger restricts the movement of the plunger (54) in a similar manner. This method of operation is repeated one more time until the desired travel location is reached. A seventh preferred embodiment of the present invention relates to a fixed electromagnetic horizontal motor. Said motor uses the recoil and impact actions to achieve the directional movement. This is achieved by rapidly propelling a mass towards the center of rotation of a rotating armature causing the axis of rotation to move in the direction of the incoming mass due to the recoil action. L Figure 12 illustrates the configuration of the fixed electromagnetic horizontal motor. The rotating armature (4) is constituted by the electromagnetic support bracket (63), located on the internal circumferential surface of the rotating frame (4) and the external bracket (64), located on the outer circumferential surface of the rotating frame ( 4) . The electromagnet (1) is mounted on the electromagnetic support bracket (63). The plunger 54 and the stop (65) of the plunger are mounted on the external clamp (64). The drive motor (9) of the frame establishes the centripetal acceleration of the rotating frame (4), which causes the piston (54) to reach its travel limit and to rest against the stop (65) of the piston. Now, the unit is ready, waiting. When the operator selects the desired direction of travel, the electromagnet (1) is activated and attracts the plunger (54) towards the axis of rotation causing the corresponding directional movement due to the recoil action. The centripetal force created by the rotary armature (4) against acts on the movement of the piston (54) and causes it to reverse its travel direction before it hits the stop (65). The impact force is generated by creating the directional movement as the plunger (54) hits the stop (65) 'as the plunger (54) once again reaches its travel limit. The recoil force and the impact force must be coordinated to occur during the same degree of the rotating frame (4), assuming a 360 ° rotation, to maximize the directional movement. The secondary rotary counter plate (66) is mounted on the bracket (19) of the frame and rotated in a direction opposite to that of the rotating frame (4) to stabilize the system. It will be understood that the claims are intended to cover all changes and modifications of the preferred embodiments herein chosen of the invention for the purpose of illustration, which do not constitute a departure from the spirit and scope of the invention.

Claims (15)

1. CLAIMS; 1. A unit to provide lift that is constituted by two load units, at least one of which is capable of generating a force. of recoil, the two loading units are disposed at opposite ends of a rotating armature.
2. 2. The support unit of claim 1 comprising an assembly mounted in a suspended housing so that it can be rotated about a central axis and a drive unit to apply a rotating force to the assembly of the armature to generate a centripetal force, the assembly of the armature is constituted by an armature having a first device for generating recoil provided at a first end of the armature and a second device for generating retraction disposed at a second end of the armature; the first and second devices for generating recoil are constituted by: a sphere slidably mounted between a retaining plate and an electromagnet; the electromagnet is able to draw the sphere against itself and hold it in a position of attraction until the electromagnet is de-energized and a control device to selectively energize and de-energize each of the electromagnets.
3. 3. A vehicle consisting of a platform attached to the unit to provide support of claim 1.
4. 4. The support unit of claim 1 wherein the control device includes a timing circuit and a detecting device for recording each rotation of the armor.
5. The support unit of claim 1 comprising an assembly of the armature mounted in a suspension housing so as to be able to rotate about a central axis and a drive unit to apply a rotational force to the armature assembly to generate a centripetal force, - the armature assembly consists of an armature having a first assembly of an oscillating weight disposed at a first end of the armature and a second oscillating weight disposed at a second opposite end of the armature; the first and second oscillating weight assemblies, each consisting of: an oscillating weight slidably mounted between a retaining plate and a lower base plate on at least one screw arrow passing through a hole in the oscillating weight; a screwdrive driving motor capable of rotating the arrow to retract the oscillating weight against the lower base plate and hold it against said plate until the driving motor of the screw arrow is de-energized; and a control device for selectively energizing the drive motor of the screw shaft.
6. The support unit of claim 1 comprising an assembly of the armature mounted in a suspension housing to be able to rotate about a central axis and a drive unit to apply a rotational force to the armature assembly to generate a centripetal force; the armature assembly is constituted by a rack and guide rods, the armature assembly further comprises an armature having a first oscillating gear weight assembly disposed at a first end of the armature and a second oscillating gear weight assembly. disposed at a second opposite end of the armature; the first and second oscillating gear weight assemblies, each consisting of: an oscillating gear weight slidably mounted between an upper stop of the gear weight travel and a lower stop of the gear weight travel at least a rack and guide rods, a gear weight motor capable of rotating the oscillating gear weight to retract it against the lower stop and hold it against said stop until the motor is de-energized and a control device to selectively energize the weight motor of gear.
7. The support unit of claim 1 comprising an assembly of the armature mounted in a suspension housing so as to be able to rotate about a central axis and a drive unit to apply a rotational force to the armature assembly to generate a centripetal force; the armature assembly is constituted by an armature having a first device for generating recoil provided at a first end of the armature and a second device for generating retraction disposed at a second opposite end of the armature; the first and second devices for generating recoil, each comprising: a solenoid plunger slidably mounted between a top rubber stop and a bottom stop within a solenoid housing; an electrical contact roller attached to the solenoid plunger wherein said roller energizes and de-energizes the solenoid plunger; the electrical contact roller is able to attract the solenoid plunger against the lower rubber stop and hold it in an attracting position until the solenoid plunger is de-energized; and a control device for de-energizing and selectively energizing each of the electromagnets.
8. The support unit of claim 1 comprising an assembly of the armature mounted in a suspension housing to be able to rotate about a central axis and a drive unit to apply a rotational force to the armature assembly to generate a centripetal force; the armature assembly is constituted by an armature having a first device for generating recoil provided at a first end of the armature and a second device for generating retraction disposed at a second opposite end of the armature; the first and second devices for generating recoil, each comprising: a sphere mounted slidably within a piston-like unit between a piston and an impact protection bearing; The plunger consists of a solenoid coil; the piston-like unit is slidably mounted within an outer tube; The solenoid coil is capable of energizing the plunger to propel the sphere against the impact protection bearing, and a control device to selectively energize and de-energize each of the solenoid coils.
9. The support unit of claim 8 comprising a counter rotating platform that rotates in the opposite direction of the armature assembly; and the counter rotating platform comprises an extension and a fixed sphere.
10. 10. The unit for providing lift comprising two weight units, wherein at least one of which is capable of generating an impact force, the two weight units are disposed at opposite ends of a rotating frame.
11. 11. The support unit of claim 10 comprising an assembly of the armature and a liner, wherein the armature assembly is mounted in a suspension housing that can be rotated about a central axis and a unit. driving force to apply a rotational force to the armature assembly to generate a centripetal force, the armature assembly comprises an armature having a first device for generating impact disposed at a first end of the armature and a second device for generating ready impact at a second opposite end of the armature; the liner comprises a retractable ramp, which further comprises: an elongate end comprising an impact driving line, a tapered end comprising a hydraulic piston; the first and second devices for generating impact, each comprising: a geomantic folding frame, a frame wheel mounted on an upper surface of the geomantic folding frame; a weight slidably mounted on the geomantic folding frame; and the frame wheel is capable of hitting the impact driving line.
12. 12. A vehicle comprising a platform attached to the support unit of claim 10. The support unit of claim 10 wherein the armature assembly and the liner are concentrically mounted within a gear. The support unit of claim 10 wherein the platform comprises a positioning gear mounted on the platform where the positioning gear rotates the gear. The support unit of claim 1 comprising an armature assembly and a counter rotating counter plate mounted in a suspension housing that can rotate about a central axis and a drive unit to apply a rotational force to the assembly of the armature to generate a centripetal force, - the assembly of the armature comprises an armature having a first device for generating energy disposed at a first end of the armature and a second device for generating power arranged at a second opposite end of the armature; the first and second devices for generating energy, each comprising: a piston slidably mounted between a stop of the plunger and an electromagnet; the electromagnet is able to draw the plunger towards the electromagnet and keep it in an attracted position until the electromagnet is de-energized; and a control device for de-energizing and selectively energizing each of the electromagnets.