NL8701834A - Converting stationary magnetic energy into mechanical energy - using stationary field in one body to exert magnetic force in second body, causing their mutual movement along polar planes of each other - Google Patents

Abstract

Two bodies are provided which consist wholly or in part of permanent magnetic or magnetisable material, each body in magnetised condition having one or more polar planes. With at least one of the bodies a stationary magnetic field is created, under the influence of which, w.r.t. at least one other of the bodies in magnetised condition, locally a force of magnetic origin is exerted. The vectorial resultant of this force makes an angle unequal to zero degrees with the normal to the polar plane at the location of the other body. As a result of this, the bodies mutually mve in substance along each others polar planes. Pref. a superconducting electromagnet is used.

Description

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Magnet commutator turbine.

Device for converting magnetic energy into mechanical energy.

In my Dutch patent application no. 87.01587 "Magnet motor", filed on 06.07.1987, it was already demonstrated and described that magnetic energy can be converted into mechanical energy by making the magnetic force act at an angle to the normal on a magnetic pole . In the above-mentioned patent application, this is achieved by making the magnetization direction of the permanent magnet make an angle greater than 0 degrees with the normal on the pole face of the magnet.

10 The magnetic commutator turbine works on the same principle. The magnetic force action at an angle to the normal on a plane of a movable part of the device is achieved by magnetic commutation similar to the electric commutation with DC motors.

Figures IA and 1B show the cross section II-II, respectively.

I-If of a unidirectional magnet commutator turbine. Figures 2A and 2B show the cross-section li-II, respectively. I-I, of a bi-directional magnet commutator turbine.

Figures 1A and 1B show an embodiment of the device according to the invention and essentially consists of three parts, namely a permanent magnet as an energy source, a rotor commutator and a yoke with pole shoes.

The permanent magnet 11 is mounted on a shaft 12 which is adjustable within the rotor commutator. The rotor commutator consists of slats 13, preferably formed of ferrite iron or laminated soft iron, which are held in a round holder 14 consisting of non-magnetic material. The holder is connected to a shaft 15 which is rotatably mounted by means of ball bearing 16.

The slats are magnetically separated from each other by air or another material with a high magnetic resistance.

Both the shaft 12 of the permanent magnet 11, and the shaft 15 of the rotor commutator are mounted concentrically / as shown in Figures 1A and 1B, within the half pole-shoe ends of the yoke 17. This yoke 17 consists of soft iron, or other suitable material with a low magnetic resistance.

The magnetic flux flow flows, starting from the north pole of the permanent magnet 11, over the slats 13 opposite the north pole, via the yoke to the slats 13 opposite the south pole, back to the south pole of the permanent magnet 11. The slats opposite the north and south poles of the permanent magnet 11 are subjected to a tangential force in the direction of the half pole-shaped ends of the yoke 17. This creates a torque on the rotor commutator, which moves in the direction of the arrow 18 will run. By rotating the permanent magnet 11 through an angle of 90 degrees, the rotating rotor commutator can be stopped. The device described above can only rotate in one direction.

The principle of the embodiment of the device according to the invention, as shown in Figures 2A and 2B, is in principle the same as that described above, with the exception that a second permanent magnet 29 is now incorporated in the yoke 27, and that the ends of the yoke 27 are formed as whole pole shoes.

The magnetic flux path also proceeds as previously described. However, the second permanent magnet 29 in the yoke 27 also produces a repulsive tangential force on the slats 23 opposite the north-30 and south poles of the permanent magnet 21.

By adjusting the permanent magnet 21 to an angle of 180 degrees, the direction of rotation of the rotor commutator can be reversed, as indicated by arrow 30. Thus, by adjusting the permanent magnet 21, both the speed and the direction of rotation can be controlled .

8701834

Claims (3)

3 4 * Device for generating mechanical energy, characterized in that the thrust of said device is based on the repulsion force, or the attraction force, of one or more permanent magnets or magnetized bodies. 2) Device according to claim 1), characterized in that said thrust comes exclusively from one or more permanent magnets or magnetized bodies. 3. Device as claimed in claims 1-2), characterized in that the movement of one of the bodies is obtained by commutation of the magnetic force from one or more permanent magnets or magnetized bodies. 870 183A