DE3807691A1 - Homopolar ferromagnetic power machine - Google Patents

Abstract

The invention provides a machine which converts ferromagnetic energy into mechanical energy and is thereby capable of doing work. The energy conversion here relies only on the property of ferromagnets that they repel like magnetic poles in their vicinity and therefore exert mechanical force which is then, by application of the lever principle, converted into rotational movement of the rotor. Seven ferromagnets are arranged in a housing at right angles to the mid-point of the system, offset at right angles in the direction of rotation, so that their like magnetic poles follow one another in the direction of rotation. In addition, a ferromagnetic rotor is rotationally mounted at the mid-point of the system and its two rotor magnets are arranged in the soft-iron rotor magnet holder so that the like magnetic poles of the stator and rotor lie directly facing each other and, as a result, the mechanical force of the homopolar ferromagnetic force field produced between the stator and rotor, acting as a lever, continuously moves the rotor in one direction of rotation. The resulting torque of the rotor enables the machine to do work.

Description

The invention relates to an equipolar ferromagnetic motor. A machine for generating mechanical force using ferromagnetism. The conversion of ferromagnetic force into mechanical force this machine is based only on the property of ferromagnets repel from opposite magnetic poles, and thereby exert mechanical pressure, which then using the lever set is converted into a rotary movement.

There are several design proposals known at home and abroad that but they all have the same technical flaws, namely the attraction of unequal magnetic poles. Ferromagnetic engines that to work with increasing force fields are not allowed realize. Because ferromagnetic attraction forces are striving to shorten because they are pulling forces. A ferromagnetic rotor would be held in place by a ferromagnetic stator. A sub refraction of these tensile forces, and thus a possible torque of the rotor would be here only by means of switchable magnetism with the help of the elec tric current possible. Also effective shielding or insulation these tensile forces are not possible without losing energy over short distances. Because all currently known elements are through for these force fields casual, except for magnetic metals, which, however, are themselves attractions subject to force. For these reasons, all previous patents messages cannot be realized.

The invention seeks to remedy this. The invention as in the Is characterized, the task solves a ferromagnetic force to create a machine that is able to To do work.

In the following, the invention will be explained using only one embodiment illustrative drawings explained in more detail. It shows

Fig. 1 is a homopolar ferromagnet combustion engine according to the invention without a housing cover in view,

Fig. 2 is a longitudinal section through the center of a stator and the rotor magnets from the system center point located above offset from the time of the greatest force action,

Fig. 3 is a perspective view of a preferred embodiment of a ferromagnetic rotor according to the invention,

Fig. 4 shows a preferred embodiment of a rotor magnet according to the invention,

Fig. 5 in a perspective view and cross-section of the rotor magnet attitude and simultaneous shielding of soft iron,

Fig. 6 shows a cross section through a preferred embodiment of an inventive he homopolar ferromagnet combustion engine,

Fig. 7 + 10, the magnetic effect of the shield by soft iron pole at the same ferromagnetic force fields,

Fig. 9, 8 + 12 in order, the formation and effect of the torque on the rotor by the stator magnets and their ferromagnetic lines of force,

Fig. 11 shows the ferromagnetic lines of force of the rotor and stator and the torque generated by the rotor.

The figures show a preferred embodiment of an equipolar ferromagnetic motor machine according to the invention, the basic construction of which initially consists of a bearing block 1 with two bearing feet 2 , one of which can be removed, and the associated bearings 3 , as well as a device 4 for axially displacing the stator 5 for the purpose of speed regulation of the rotor. Furthermore, a ferromagnetic rotor 9 , which is rotatably mounted 3 in the bearing feet 2 .

The ferromagnetic rotor 9 itself consists in this preferred embodiment from the rotor magnet holder 12 and at the same time shielding from soft iron. From the rotor shaft 13 made of non-ferrous metal, and in the preferred embodiment here from two rotor magnets 11 , which have the shape according to the invention in FIGS . 3 and 4 and have a curved crystal-oriented magnetic preferred direction of anisotropic type.

According to the invention in this preferred embodiment of a ferro magnetic engine in the stator 6 seven ferromagnets 10 are offset from the system center point at right angles in the direction of rotation so that their magnetic poles of the same name follow one another in the direction of rotation. Also according to the invention, here the ferromagnetic rotor 9 is mounted in the system center of rotation 3 and the two rotor magnets 11 are mounted in the rotor magnet holder 12 in such a way that their magnetic poles of the same name lie directly opposite the magnetic poles of the same name of the stator 6 , so that the mechanical pressure of equipolar ferromagnetic force fields, which arises between the stator 6 and the rotor 9, is converted into a continuous mechanical rotation of the rotor 9 using the lever law and the torque thus generated enables the machine to perform work.

The creation of an effective torque on the rotor results in one hand by the arrangement of the stator magnets according to the invention, which as Acting lever move the rotor in one direction of rotation, and on the other by the shape and preferred magnetic direction of the invention Rotor magnets, and the effective shielding of the rotor magnet holder soft iron. There is a mechanical balance of the forces on the rotor therefore not available when this machine is ready for operation. Because the effective mechanical pressure is in the direction of rotation of the rotor forces acting on the rotor are greater than in the opposite direction. That is why the machine is also able to do work.

A mechanical balance is only given in this machine if the stator ( 6 ) in the bearing block ( 1 ) is axially displaced ( 4 ), so that the repulsive forces are reduced and the attractive forces become effective. This reduces the speed of the rotor until it comes to a standstill. However, this device is not necessary for the operation of this homopolar ferromagnetic motor, but is a preferred embodiment.

Because of this invention, it can be seen as a certainty, that

• 1. Ferromagnetic machines that only work with attractive forces should not work. For rotating the rotor after both Directions must be spent on energy.
• 2. Ferromagnetic machines that are attractive and repulsive Forces to do work, not work. To rotate the Only the friction energy has to be expended here in both directions be det.
• 3. Ferromagnetic machines that only have repulsive forces Work, work. To turn the rotor after one Direction does not have to use energy, it becomes one released while rotating the rotor in the opposite direction Energy has to be used exactly as much as in the direction of rotation of the rotor is released by itself.

Claims (5)

1. homopolar ferromagnetic motor, a machine for converting ferromagnetic force into mechanical force, characterized in that in a housing ( 5 ) a certain number of ferromagnets ( 10 ) from the system center point at right angles in the direction of rotation of the rotor ( 9 ) are so attached that their magnetic poles of the same name follow each other in the direction of rotation of the rotor ( 9 ), and a ferromagnetic rotor ( 9 ) is rotatably mounted in the system center ( 13 ) ( 3 ), in which a certain number of ferromagnets ( 11 ) are stuck, characterized in that the magnetic pole ends have a curved surface and a curved ferromagnetic, crystal-oriented preferred direction, and are thus secured in the rotor magnet holder and at the same time shielding from soft iron ( 12 ), so that the magnetic poles of the same name of the rotor ( 9 ) and stator ( 6 ) directly opposite, so that the resulting mechanical pressure equipotential Ferromagnetic force fields are converted into a continuous mechanical rotary motion of the ferromagnetic rotor ( 9 ) using the lever law and the torque thus generated enables the machine to do work. 2. Machine according to claim 1, in which in the stator and rotor only one ferromagnet with several magnetic poles is brought. 3. Machine according to claim 1 and 2, which a Vorrich tion for axial displacement of the stator for the purpose of rotation number regulation of the rotor. 4. Machine according to claims 1-3, in which the rotor and Stator has more than two rows of magnets and thus larger Achievements enabled. 5. Machine according to claim 1-4, in which the used Ferromagnetic materials can be isotropic as well as anisotropic.