DE3510349A1 - Permanent-magnet, annular-screen rotor for using the energy of permanent-magnet force - Google Patents

Abstract

In order to use the attraction force which is intrinsic in permanent magnets and which acts only when said permanent magnets are of different polarity, mechanically in terms of a rotor as an input energy transmitter, the invention proposes that two permanent magnet rotors which operate synchronously with one another on a shaft and also act as balanced flywheels transmit to a smoothly rotating output shaft with a flywheel such that they produce relatively more output energy at the rotor bearing surface and the opposite permanent magnet, which is mounted on the rotor block, is of different polarity and is in consequence directed and caused to attract, than the application of pressure which is necessary via the rotor magnet piston for the actual screening-tube positioning. In this case, the output shaft is at the same time the rotor shaft and the pressure-initiating device, which is located on the horizontal flywheel and in each case acts after half a revolution determines when an energy pulse can be picked off and passed on. This ensures that the energy pulses on the rotor output shaft are used in an optimum manner and support the synchronously operating rotors in the movement which is in each case already taking place.

Description

Permanent magnet ring shield rotor, for the use of energy from permanent magnetic force - The invention relates to a device to the, inherent in permanent magnets, only its mutually interpolated attractive force mechanically-rotor-wise to use.-Easy positioning of the Shielding tube over the rotor magnet he obtained output energy gain otherwise, either for positioning the shielding tube of rotors of the same type, or for driving to be used by machines.-It is designed as a double rotor, lying on an axis and thereby working sincronously, interacting with magnet arrangements of different poles 90 ° to each other shifted, all-sided strongly magnetized curved facades Magnetic plates provided.-The permanent magnets are bare. L-In rotor are nowhere Windings.! Except for the continuous rotor axis, iron shielding tube, the flywheel and on positioning devices installed thereon, are all components of the The rotor is made of antimagnetic material The rotor surface is divided into four in length and the magnets are opposite each other a quarter area each, with external poles directed towards the attraction of the rotor block magnetc-r Antimagnetic counterweights are attached between the magnets in such a way that this the sincron rotors themselves are considered to be balanced flywheels, with their Axis, located outside the rotor, also for positioning the iron shielding tube required larger flywheel.-the rotor block.the rotor outside and on the inside, has a quarter area opposite the rotor magnets, Likewise opposing magnets attached to the rotor magnets by attraction, with a quarter of the surface space between them.-The rotor block magnetic plates are twice as large Width of rotor magnet width and, with in each block, applied to attraction, different Polarity to rotor In one rotor plus to minus, in the other rotor minus to plus - the Rotor blocks stand at a measured distance from one another - the rotors sit in the outer one opening part of rotor blocks -between the rotor and the one opposite The rotor block magnet is a distance of approx. 9-10 mm.-In this gap lies loose, easy to move an iron pipe, with a wall diameter of 4-5 mm, the length of which extends from that of a rotor inside, up to the other rotor outside so that when one rotor is covered with iron pipes is, then the other rotor magnet surface is open and the, on the rotor block and Magnets located on the rotor attract each other. - Before the two opposing each other Cover the magnet completely, the iron shielding tube is positioned (pushed in between) and at the same time exposing the other rotor.-The attraction then goes there etc.-The iron shielding tube is not completely removed from the rotor magnet torn off, only pulled back to the edge and it remains on the rotor block located, homopolar and wider 'between the blocks, different in a line Polished magnets This is the core of my invention. By arranging them differently Magnet is achieved that the positioning of the iron shielding tube 9 to and fro Pushing it here, goes very easily and evenly.-The, over the column, open Attraction of superimposed magnets pulls it easily, even between them the relatively little effort required by the rotor for positioning still reduced ...

Further details and features of the invention emerge from the Subclaims.

An exemplary embodiment is described below with reference to the accompanying drawings the subject of the application illustrated in more detail.

In the drawings, FIG. 1 shows a schematic side view in FIG Cross-section on the core with the rotors, rotor block, iron shielding tube, with its movement device Fig. 2 is a schematic side view of the positioning device, with the flywheel Fig. 3 is a schematic plan view of the rotor block, lateral Shield stabilizer and positioner with the flywheel Fig. 4 a schematic cross section of the rotor blocks, rotors and magnet arrangements - The schematic representation of the permanent magnet according to the invention, sincron double rotor, shows a common shaft 15 (Fig.1,2'3,4, with attached to it at a measured distance Rotors 12 (Fig. 1) .- On its running surface, opposite one another, a quarter of Covering the running surface, magnetized magnets 13 (Fig.1L4) are attached on all sides.

To a rotor 12, with the positive pole to the outside 13 ¢, to the other rotor, with Minus, to the outside 13.- The rotor itself is antimagnetic and on its running surface, between the magnet blocks, antimagnetic weights are attached so that the rotors themselves'all balanced flywheels act 12.-with which one works, outside of the rotors, on the same axis 15 lying flywheel 22 (Fig.1,2,3) .- The rotor magnets, on two wheels, are shifted to each other 900 so that when that one wheel is working, is the other wheel free.-In addition, they have different external poles ..! - The rotor block, the Rotors outside comprising 2,2 '(Fig. 1,3,4), is also antimagnetic and has twice the width of the rotors 12 (Fig.1) .- On the inside facing the rotors, respectively a quarter in length, but covering the entire width (double the rotor width) 3.3 ' (Fig.1), arranged diametrically to each other and with, on the same plane, from block to block different external poles attached.-The rotor blocks with the rotors in them are located are at a certain distance from each other and the rotors are in outer openings.-The Block and rotor magnets are attracted to each other plus-minus and minus-plus opposite.-Between the rotor and on those opposite rotor block magnets a distance of approx. 9-10 mm. An iron shielding tube is easily movable in this column 1 (Fig, 1, 4), with a wall diameter of 4-5 mm, the length of which is from a rotor inside to to the other rotor outside is enough.-If one rotor is covered, then it is the other rotor bare 12 (Fig.1) .- The, on the rotor blocks, with different polarities Fixed magnets make the iron shielding tube easy to position.

They balance each other out with their effects on each other (Sig.1). That The shielding tube is not completely torn off the rotor magnet 'during positioning'. -Only until withdrawn to its edge and it remains, with the end, located on the rotor block, wider, between Magnets with different polarities float around the rotor blocks. - The rotor blocks are above, through a beam connection held together 14 (Fig, 1,3,4) .- The directional stabilization of the iron shielding tube is done by antimagnetic limiting ball bearings, the Installed between the rotor blocks .- (Fige1'3) 0-1o'14-In tube itself, are installed Light metal form stabilizers (rings) built into the shielding tube's lateral stability secure two homopolar magnets attached to one side arm. -25,26.-Am outside of the flywheel, on the side facing the rotor, is a plate with a side protruding, inclined plane 21 (Fig. 2,3) attached - in front of it, on the flywheel ball bearing housing, on the side, pivot pins are attached - a lever tilting rod 20 rotates on these pins (Fig. 2,) Above and below the pivot pin, transverse ball bearings are attached to the tilt rod 24 and they are overrun by the inclined plate every half a revolution of the flywheel 21,24 (Sig.2,3) and by the tilting rod arm, which is extended downwards, with him connected transmission arm 5 leading to the rear, also through a rear one Lever arm 7, the end of which is provided with ball bearings, rotatably mounted in a "U" bearing 8, the Shielding tube positioning 1 (Fig.1,2) accomplished - To put the rotor down there is a manually operated one on the flywheel bearing housing 16 (Fig. 213) Fork tilting device 18, 19.- With its help, the upper part of the positioning tilting rod located ball bearing 24, which is mounted there on the rod 20 so that it can move easily, according to be pushed up, out of reach of the swivel plate and the rotor brakes himself off.

Claims (1)

Claims 1. Device for generating energy by means of Permanent magnets, around its inherent energetic power mechanically-rotor-wise to use to direct their constructive-constellative work in such a way that besides self-propelled to generate output energy gain that can also be used elsewhere is, characterized in that a Sner, ieF pulse-transmitting connection between Singing energy and output energy take place on a common axis, with the, in the two double rotors working alongside and with one another, interrupting the magnetic effect required iron pipe positioning of the one located outside of the rotors Flywheel takes place. -2. Device according to claim 1, characterized in that the Flagnet rotor, essentially, consists of four main elements. The two, fixed stationary at a certain distance from each other, to A rotor block with a common axis and working sincronously with permanent magnets. The rotors provided with magnets and lying on a common axis. The easily movable one between the block and rotor magnets Iron shielding tube. The flywheel sitting on its axis outside of the rotors, with the shield tube positioning device. 3. Device according to claim 1 to 2 characterized in that the two rotor blocks, which are made of antimagnetic material, circular and in Axial direction are fixed stationary at a certain distance from each other.-The have the Double the width of the rotors - the inside is divided into four in the direction of the running surface and cover the attached magnets, diametrically opposite one another, in Lengthways, each only a quarter of the segment, but along the entire width of the engine block.-Die Nagnets are fully magnetized and one block shows its inside to the rotor minus, in the other block 'to rotor side plus.-To the rotor block the axle bearing housings are attached. 4. Apparatus according to claim 1 to 3, characterized in that the two, on the outskirts of the inside of the block, antimagnetic and on common Rotors attached to the axis, like balls on the running surface, divided into four lengthways are and cover the attached magnets, diametrically to each other, also in each case only a quarter of the rotor area - in between are counterweights, made of anti-magnetic Material set in such a way that it creates the rotors themselves as balanced flywheels Apply .-- The permanent magnets attached to the rotors are relative to each other in order to make a quarter segment shifted, in addition, placed with different external polarities to each other so that they always have an attraction on both rotors (plus on minus and ninus on plus) .- Between the rotor block magnet and the rotor magnet there is an approx. q-lo mm gap left out. -5. Device according to Claims 1 to 4, characterized in that that is in the gap cut out between the block and the rotor magnets an iron shielding tube with a wall diameter of 4-5 mm, which is easy to move in transverse direction, its Length depends on the magnetic charges. The iron shielding tube is between the two magnets set that when it is positioned, i.e. Slide back and forth, one rotor covered and the other rotor at the same time is exposed.-The open rotor magnets can then, with those opposite them Block magnets Develop their full force of attraction and in rotation go.-Before the magnets slide fully over each other, the iron pipe shielding must be changed take place (slide over it), otherwise braking effect.-The shielding tube is held by the rotor magnets not completely torn off, just pulled back to the edge and it stays with the end, located on the rotor block, wider, different between the rotor blocks polarized magnets lie.-This is the core of the invention ,, l-This is the pipe smoke Inside loaded and easily movable between two polarities.-The iron tube lateral stability secure two homopolar magnets attached to each other on its side The directional stabilization of the iron shielding tube is done by anti-magnetic Limiting ball bearings installed between the rotor blocks - in the tube itself. light metal form stabilizers are installed (rings). The positioning of the shielding tube is made easier by an easy pulling the iron when the magnets slide over each other .-- This will make the one of the Rotor, required for positioning, relatively little effort is still reduced 6. Apparatus according to claim 1 to 5, characterized in that, on the rotor axis Lying outside flywheel, on the side facing the rotor, a plate, with Laterally protruding, inclined plane is attached.-In front of it, on the sides of the ball bearing housing of the Schwungredes axis, pivot pins are attached.-On the pivot rotates, a Tilting rods that can be moved to and fro are on the tilting rod, above and below the pivot point Ball bearings attached.-The inclined plate presses against these ball bearings, each half Rotation of the flywheel and through the tilt rod extended downwards with leading the transmission arm connected to it to the rear, also through a rear lever arm, the end of which is provided with ball bearings, in a "U" Rotatable bearing, the positioning of the iron shielding is accomplished Practically three flywheels, two working and one positioned on the same axis. -7. Device according to Claim 1 to 6, characterized in that, in order to turn off the rotor There is a manually operated fork tilting device on the flywheel bearing housing.-i4it whose help can be the ball bearings located on the upper part of the positioning tilt rod is movably attached to the tilt rod, be pushed upwards out of reach of the swash plate and the rotor decelerates itself.