RU98113689A - UNIVERSAL ELECTROMAGNETIC MOVEMENT UNIT IN STATIONARY AND NON-STATIONARY CONDITIONS - Google Patents

Claims (4)

1. A device that converts rotational motion into translational, representing an electromechanical device containing a circular rotating rotor, the axis of which is connected to the driving link-motor (electric or other), the weights, which are identical in weight on the radially extendable rods, are located around the circumference of the rotor, which are under they are put forward by the action of centrifugal forces, the rotor together with the loads is placed in a cylindrical stator (housing) of diamagnetic material, the shape of which is curved in cross section (elliptical or similar), the axis of rotation of the rotor is set on the large axis of rotation of the elliptical figure, but not in the center, which creates the eccentricity of the rotation of the rotor and the resulting centrifugal forces on opposite sections of the major axis due to different and constantly changing lengths of radii and different speeds of loads that arise, forces on these sections of the motion path have different meanings and the resulting (difference) force is directed from the axis of rotation of the rotor to the center of the figure described by the rotor, for example, an ellipse acting on the stator walls (case) and moves the device due to rotation around the center of the device case in any (predetermined) direction in the plane of rotation of the rotor, while the rotor is suspended in the device body using an electromagnet system with opposite direction of magnetic fields, characterized in that, in order to improve technical characteristics of the device for converting rotational motion into translational motion to move it under stationary and non-stationary conditions, such as obtaining more power and, accordingly, dumb moving speed, reliability, versatility as such a device, we choose a synchronous electric machine (motor), arranged in such a way that the machine rotor is manufactured in the form of a sectioned ferromagnetic toroidal ring, we put (wrap) solenoid windings on each section, as on the core, the windings are connected to a semiconductor device (diode), the diode is installed (mounted) inside the case of the ferromagnetic core of the section, from the ferromagnetic sections with windings and the diode and make up the rotor, we take the number of sections equal to 4n, where n is 1,2,3, ..., while in each adjacent section the diodes have the opposite polarity of connection to the ends of the rotor windings, or we wrap in each adjacent section of the rotor windings in opposite sides and then the diodes are installed in one direction, the gap gaps (joints) between the sections are sealed with insulating material, structurally and technologically we ensure the rigidity of the rotor ring design, we place the rotor inside the stator, which we make in the form of cage-clips made of insulating material, into the slots of which we lay (wrap) the stator solenoid control windings, which are evenly distributed at equal distances between each other along the frame (cage) of the stator, the number of windings is selected from the condition 3 · 4p, where n is 1.2 , 3, ..., each winding is placed in ferromagnetic screens, the ends of the windings are brought out through the hole in the screens or through the grooves, which we connect according to the circuit to a switching device, which is connected to a source of alternating 3-phase current and a pulse generator the stator (frame, windings, screens), we technologically and structurally rigidly connect to the housing of the moving device, install in the device housing a second similar machine coaxially (one inside the other) or in parallel (one above the other), feed the stator windings of both machines (through commutator) voltage of 3-phase alternating current, we provide in the stator of each engine a rotating (running) electromagnetic field, with the help of which we separate the rotor from the walls of the stator cage, hold the rotor in magnetic the stator field and the rotation of the rotor using a rotating electromagnetic field due to the interaction of the magnetic field of the stator and the induced field of the rotor, the rotors are rotated in opposite directions, we apply direct current pulses (gearing) to certain stator windings of both motors according to a certain program, as a result of which we create dimetrically opposite or other points of the rotors of the inertia forces that create the force of translational movement, that is, we provide the transformation of rotational motion ia (rotors) in the translational movement of the device.  2. The device according to claim 1, characterized in that, in order to convert an electric machine (engine) into a propulsion device, in an enclosure with the machine we place an autonomous source of electricity together with a converter of thermal, nuclear or other energy.  3. The device, propulsion device according to claim 2, characterized in that, in order to create on its basis a universal movement device, both for all types of movements (underwater, surface, ground, air, space), and for each type separately, as well as a device that combines a combination of types of movements, structurally, the propulsion housing is manufactured in a disk-shaped form, we equip the housing with parts (elements) that give the device hydrodynamic, aerodynamic properties, as well as parts that allow you to move around the earth We’ll create places for the crew, equipment and cargo in the device’s case.  4. The moving device according to claim 3, characterized in that, in order to be able to move it in two mutually perpendicular planes on it, in a particular embodiment, we install two additional engines according to claim 1.