JP2018011509A - Izuogu machine (self-sustaining emagnetodynamics machine) - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a magnet motor called as a self-sustaining emagnetodynamics machine that utilizes inventor's first and second laws of emagnetodynamics as well as the inventor's horse orientation theory of magnetic fields.SOLUTION: A self-sustaining emagnetodynamics machine utilizes a theory that is different from an old theory of electric motors which has been built for over five hundred years since the days of the great inventor and scientist, Michael Faraday.SELECTED DRAWING: Figure 7

Description

  The present invention belongs to the physical technical field. More specifically, the present invention belongs to the technical field of energy.

 Prior art in such technical fields includes the theory of magnetism motors operating on electricity or batteries, the theory of magnetism and the force acting on conductors carrying current in a magnetic field.

  A force acts on the conductor that carries the current in a magnetic field. This theory is used to create an electric motor, a machine that converts electrical energy into mechanical energy. Emagnetodynamics motors operate on a different theory, namely the laws of emagnetodynamics.

  The prior art includes a conventional electric motor. However, they do not use distributors or kickstarters, nor do they use the laws of electromagnetic dynamics, as do multi-plane electromagnetic dynamics motors, which outperform hybrids of electric motors and internal combustion engines.

German Patent Publication No. 10 2004 043007

  The present invention is a magnetic motor called a self-supporting electromagnetic dynamics machine that utilizes the first and second laws of the inventors 'electromagnetic dynamics together with the inventors' horse orientation theory.

  The first law is described as follows. “When placed near the same pole array of magnets, the suspended composite pole rotates in one direction.”

  The second law is described as follows. “The direction of rotation is that of the same composite pole as the array.”

  An important feature of this machine is that it differs from previous inventions that are not self-supporting electromagnetic dynamics machines in that the self-supporting machine generates a feedback current that provides release from the backlash stator. Can operate without external energy source.

  Electric motors convert electrical energy into magnetic energy, and magnetic energy into mechanical energy, while self-supporting electromagnetic dynamics motors, like their non-self sustaining counterparts, Is directly converted into mechanical energy without passing through the current carrying conductor.

  The self-supporting machine of the present invention uses its own feedback current to operate, operates like an electric motor, but does not use the forces acting on the conductor carrying the current in the magnetic field. A self-supporting machine operated by the interaction of magnetic poles between and powered by magnets and electromagnets, the main part being a set of permanent magnets forming a stator of the machine arranged in a circular pattern; A composite magnet attached to the spindle forming the rotor, and a brush to release the rotor blades (on each side) of the rotor from backlash resulting from repulsion / traction of the composite pole of the rotor By having a distributor that applies pressure, the above-described problems are solved.

  The permanent magnet forming the stator may be fabricated such that half of the magnet is an N pole and the other half is an S pole.

  The electromagnet forms a release stator pole of the machine and is made to have a pole strength approximately equal to the respective pole strength of the stator permanent magnet, and if not magnetized, the first stator The time interval may be determined so as to be temporarily magnetized at an appropriate timing to be pulled back by repulsion / traction by the permanent magnet.

  The blades and spindle that hold the composite pole may all be made of a non-magnetic material such as brass or copper so as not to distort the magnetic field generated by the stator magnet.

  The first law of the inventors' magnetodynamics, which states that “the suspended composite magnetic pole moves in a certain direction when placed near the same pole array of magnets” is utilized by the above device. Also good.

  The second law of the inventors' magnetodynamics, which states that "the direction of rotation of the composite magnetic pole is the same direction of the composite pole as in the arrangement", may be used by the apparatus.

  Because the soft iron loses its magnetism very quickly, and to obtain it, the composite pole actually has the same crescent shape because it acts as a mirror image (alternative) of the stator permanent magnet. It may be possible to replace it with a bent soft iron disk.

  The brush and the rectifier may be made of copper or other non-magnetic but non-rusting metal.

  The rotor is mounted on the rotor made of either brass, copper or any other rigid non-magnetic material with the vane to which the composite pole is mounted resting on a horizontal plane. It may be configured as follows.

  The blades attached to the rotor, like the crankshaft of an internal combustion engine, are placed on different surfaces to increase the mechanical power output by the machine, but all are the same It may be possible to configure so that there are two or more vanes attached to the rotor.

  The stator magnet of the apparatus may be configured to be placed on a different surface of the machine to increase the mechanical power output by the machine.

  Similar to the ignition key of a motor vehicle, at the start of the machine, the first or last electromagnet of claim 1 and also the small DC motor attached to the rotor have an electrical output via a switch. May be transmitted.

  The DC motor of claim 12 mechanically coupled to the rotor may be used in a “kick start” process to rotate the rotor at the start of the magnetodynamic motor.

  The stator magnets of claim 11 mounted on different surfaces of the machine may be magnetically shielded from each other so as not to distort their magnetic fields from each other during operation.

  The arrangement of the stator and the rotor according to claim 1 can be reversed, and the laws of the magnetodynamics can still be applied to produce an action.

  The stator, which is a permanent magnet, may be able to be replaced with an electromagnet without degrading the operation of the system.

  The system of the present invention is a system that uses the theory of magnetodynamics, which is the simplest term, in other words, the movement of a magnet without the presence of a current or a conductor that carries the current, thereby solving the above-mentioned problems. The self-supporting magnetodynamic machine is the first machine known to man to cause a permanent magnet to release its atomic energy for mechanical work. The theory of emagnetodynamics is also the result of the inventors' research on magnets that has continued for 31 years.

It is a perspective view of a composite magnetic pole. This is a crescent N-pole and S-pole of two permanent magnets held together on a plate bent into brass or copper or any non-magnetic crescent shape. This is mounted on a spindle that is pivoted on a non-magnetic pivot axis. The arrangement of N poles of similar magnets is shown. (It can also be the S pole.) However, for the system to work, it is necessary to use the same pole. FIG. 3 shows the magnetic pole arrangement used to form the magnetic pole array referred to in FIG. The composite magnetic pole arrange | positioned in the vicinity of the arrangement | sequence of the same pole is shown. Although it is a composite magnetic pole, it is now made of soft iron slab. It is mounted on a spindle placed on a non-magnetic pivot axis. The angular arrangement of the rotor vane on each side is shown. A design model of a fully self-supporting electromagnetic dynamic motor with four faces attached is shown. Fig. 8 shows electrical connections for the machine shown in Fig. 7; 1 shows a rotor vane with a stem. 1 shows a permanent magnet that forms part of a composite pole of a rotor. This is a powerful ECLIPSE MAGNET of 60 × 15 × 5mm purchased from NAAFCO SCIENTIFIC in London. This causes a 15 degree deflection in a magnetic system about 300 mm apart. Release electromagnets 40 and 42 are shown. Shows unmagnetized iron rod (unmagnetized soft iron rod) Fig. 3 shows a stator and vanes (angular arrangement of stators) on one surface. The same bar (soft iron) in the solenoid is shown. 1 shows a clutch yoke for a machine. 1 shows a clutch fork for a clutch device. 1 shows a rotor for a machine (brass rotor, 870 mm, overall length). 1 shows a clutch device. Shows five horses pulling in different directions. 5 horses pulling in the same direction are shown (explanation of the inventor's magnetic horse-direction theory). A machine with an electromagnetic stator that gives mathematical and experimental proof of achieving efficiency beyond unity (a machine that mathematically demonstrates proof over unity).

  Referring now in detail to the invention of FIGS. 1-21, the machine and its components are shown. In particular, FIG. 7 shows a four-sided, self-supporting, magnetodynamic machine with all elements attached.

(Section 1)
Two brass rods 35 and 37 (diameter 25 mm, height 900 mm) threaded 15 mm long (both ends) are attached to a horizontal brass plate 10 at right angles. This brass rod carries an aluminum sleeve to stabilize the system. The rotor 26 is installed on the lower ball bearing 9.

  The stator 26 has a portion that holds the distributor 27 and the slip ring 29 at its lower part (length: 70 mm, diameter: 60 mm).

  Here, the Perspex 15 holding the carbon brushes 31, 33, 35, 37, 49, 41, 43, 45, 47 is installed and fixed with four copper bolts.

  Each of the circular Perspex plates 49, 51, 53, 55 carries three permanent magnets 18, 19, 20 and electromagnets 22, 32 mounted on their respective surfaces. Five stators on one face are placed around a 480 mm diameter circular hole cut in the center of the Perspex. The stator covers an angle of 180 degrees. This means that there is 45 degrees between one stator and its neighbor. The circumferential distance measured along the circumference of the circle between the center of one stator and the adjacent stator is the circumferential length of the distance between the north and south poles of the composite pole of the rotor ( circular length). Here, the circular Perspex plates 49, 51, 53, 55 are firmly held by sliding the aluminum sleeve downward and tightening. The aluminum vane 76 carrying the two permanent magnets constituting the composite poles on each side is now clamped in place and the top end of the stator is slid into the upper ball bearing of the copper support 28. The Here, nuts are tightened on the threaded ends of the brass supports 35, 37 in order to make the system strong and strong. Here, the DC battery 21 is connected to the release electromagnet via the ignition key, the motor 25 and nine brushes. The DC motor 25 is connected in parallel with the release electromagnet, and is protected from a heavy current surge by the high load resistance 23.

(Section 2)
The system is ready for operation. When the ignition key 12 is twisted, the current from the battery 21 turns on the DC motor 25 and rotates the rotor in the clockwise direction (this direction is the direction in which the second law of the Emagnetodynamics states that the rotor moves) Must match). The motor 25 can rotate the rotor 25 by an arrangement of wheels and pinions (the rotor 26 carries a wheel having a diameter of 144 mm with teeth of a cog gear, like a kick starter of an internal combustion engine, The motor carries a 10 mm diameter wheel with cog teeth. The battery 21 supplies energy to the distributor 27 and the motor 25 simultaneously. The distributor 27 is in electrical contact with the brushes 33, 35, 37, 39, 41, 43, 45 in the same manner as the distributor of a conventional internal combustion engine ignites the four plugs. Give energy to. The first release electromagnet 22 of surface 1 is timed to produce an N pole strength that should be the same as or close to the pole strength of the stator permanent magnet. This must occur at the moment when the magnetic axis of the leading composite pole of the rotor just tolerances the magnetic axis of the electromagnet 22. The rotor 26 moves further, and the distributor 27 is in contact with the second brush 35 at a point where the magnetic axis of the composite pole of the first rotor tries to diverge from the magnetic axis of the permanent magnet 19 of the last rotor. This gives energy to the last electromagnet 32, thereby freeing the composite pole pulled by the rotor that was supposed to be pulled by the south pole pulled by the north pole of the last stator permanent magnet 19. . This should have deteriorated the rotor rotation and stopped the machine. Because it is a four-sided machine, the torque applied to the rotor by other stators on the other side allows the stator to cover the resting distance, which again makes it possible for the first stator This is repeated under the influence of the electromagnet 22 (the iron core of the stator electromagnet 22 pulls the leading N pole of the composite rotor pole under the influence). The rotor can continue its rotation in this way.

  Note that all four vanes attached to the rotor but across different stators on different faces are not each positioned at 90 degrees.

  What we find from FIG. 6B is that the first vane V1 precedes the second vane V2 by an angle of 90 degrees. V2 precedes V3 by an angle of 135 degrees and V3 precedes V4 by an angle of 67.5 degrees. A simple angular arrangement of the rotor blades in a four-sided machine would have divided 360 degrees so that each blade preceded the subsequent blades by 90 degrees. We did not use this simple approach in this design. This is because the distributor means that energy is applied to two or more electromagnets at the same time. Since electromagnets draw a large amount of current from the feedback generator, the feedback generator cannot cope with the large draw for its scarce energy, and the system may stall. In order to avoid this fatal situation, the vanes are arranged as shown in FIG. The six-sided machine has a different blade arrangement, and so on. The overall idea in the design is to avoid situations where two or more release electromagnets are energized at the same moment.

  An internal combustion engine designer who designs a 4, 5 or 6 cylinder engine must determine the angular arrangement of the protrusions on the camshaft that will determine the firing sequence of the plug in the combustion chamber for each engine. As is the case, the angular arrangement for making a 5, 6 or 20 plane machine must be determined separately in each case.

We call this machine a magnetic motor, but from the above and from a design point of view, this machine actually has more commonality with internal combustion engines than common with conventional electric motors. Have.

(Section 3)
Referring to FIG. 7, in order for the rotor to rotate, it is necessary to ensure that the circumferential length of the vane is approximately the same as the circumferential distance between the magnetic axis of one stator and the next. There is.

  This is an important condition for the system to operate. It is equally important that all stator permanent magnets have equal strengths, otherwise the first and second laws of the embedding dynamics are not met and the machine will not function.

  The magnetodynamic machine is essentially a magnetic motor. Therefore, it is necessary to ensure that non-magnetic metals are used to create all parts of the machine, otherwise the critical magnetic field strength required at some point (s) is reduced. Or decrease. All bolts, nuts, etc. are made of copper or brass or aluminum to avoid magnetic interference and distortion that would mess up the assembly.

  In the same way that the plug of the internal combustion engine must be ignited at a specific timing, the release electromagnet is “ignited” at the appropriate time to ensure the rotor 26 releases at the backlash point and the motor continues to run. Be "/ must be energized. In order to ensure this precise timing, the position of the carbon brush is made adjustable, similar to the timing chain of an internal combustion engine. The brush is mounted on a base that moves on a circular groove formed in Perspex 15. Once the proper timing position is determined, the brush is screwed to the Perspex base with brass bolts and nuts.

(Section 4)
Referring to FIG. 7 of the present invention, the rotor 26 is made of copper, has a height of 870 mm, and has holes for taking vane stems formed along the stem at various heights of the stem. . These correspond to the height of the four faces.

  The rotor 26 has a large stem with a diameter of 60 mm and a height of 70 mm, while the rest of the body has a diameter of 30 mm. The slip rings 90 and 94 (10 mm width and 0.5 mm thickness) are made of copper which is a good electrical conductor and does not rust. These are desirable characteristics to ensure that good electrical contact between the slip ring rectifier and the brush is always maintained. The contact resistance of the brush should not exceed 0.2 ohms. Of course, the slip ring rectifier is effectively insulated from electrical contact with the rotor using paper insulation, as is done in conventional electric motor rectifiers.

  The permanent magnet stator, which is the main source of torque acting on the rotor 26, needs to be very strong or the machine will be weak. In fact, the permanent magnet stator used by the inventor to make a working model of a non-self-supporting magnetodynamic machine has a magnetic pole strength that causes a 25 degree angular deflection in a magnetometer 1 meter away. Each had. These magnets were Alcomax magnets, but of course, since these magnets were bought about 25 years ago, a stronger magnet in the form of a neodymium magnet has been invented.

  Emagnet dynamics machines with only one face are either internal combustion engines with only one cylinder versus traditional four cylinder, four stroke engines, or conventional electric motors that operate with only one coil. It ’s like that. In order to generate a sufficient torque for the rotor 26 to be a powerful machine, an actual electromagnetic dynamic motor must have many surfaces, at least four surfaces. As the number of surfaces increases, the resulting machine becomes more powerful and the magnetic shielding becomes much more effective to shield the magnetic field generated on one surface from affecting the flux on adjacent surfaces. Although important, it is desirable to make as many as 10-20 plane machines.

  Referring to FIG. 21 of the present invention, S1, S2, S3, and S4 are electromagnet stators of a single surface machine. S1, S2 and S3 are all connected in parallel and energized together, but S4 as a release electromagnet is energized separately in a separate circuit. It can be seen that in order to rotate this system, about 120V must be supplied to the three stators, and 72V needs to be supplied to the release stator S4. The current flowing through the first circuit measured by the ammeter A1 is 45A, and the reading of A2 is 6A.

The power generated by this machine rotating at 300 rpm is calculated as follows:
1. A 240V power supply is the main power input to the motor.
When K2 is closed from the motor position on the mmf axis of S2 to the mmf axis of S4, the control or auxiliary input to the motor provides relatively little power.
1. The motor power output is the product of rotor speed and rotor torque in radians / second.
Pout = T × ω = T × (300 × 2π) / 60 = 10πT watts Assuming a machine without loss, input power = output power,
Power from S1, S2, S3 = 45 × 240W = 10800W
Assuming θ radians in one rotation (S2 axis to S4 axis) or K2 by 120 degrees,
Power from S4 = 72 × θ / 2π × 6W≈68.750θW = 144.4W
(A) Percentage of power attributed to S1, S2, S3 = 10800 × 100 / (10800 + 68.75θ) = 98.7%
(B) Percentage of power attributed to S4 = 68.75θ × 100 / (10800 + 68.75θ) = 1.3%

  From this result, if a small feedback generator is linked to the rotor spindle, it will supply this 1.3% power needed to operate the release electromagnet and replace the electromagnets S1, S2, S3 with permanent magnets It is clear that we have a machine that is much more efficient than unity.

(Section 5)
Another version of self-supporting magnetodynamics can be created by adding a current booster to the feedback generator circuit. The output of the feedback generator is supplied to a pulse circuit as shown in FIG. A pulse circuit is simply a circuit in which electrical energy is stored in a capacitor and discharged at a very high rate. A large current flows for a very short time. The rotor release required at the backlash point results in a single point operation that lasts only a few milliseconds, and the current generated thereby is sufficient to release the rotor at the backlash point.

  Energy deceit (Deceit): It can be argued that self-supporting magnetodynamic machines use the principle of energy deception. This is explained as follows.

  In conventional electric motors, the motor needs to have full current flowing through the coil at any and every moment. This means that a large amount of energy must always be supplied to the electric motor. That's not the case with the Emergent Dynamics machine. We don't need a lot of energy at every moment. We need a large amount of energy only at the points necessary to ensure that the rotor blades are released from the backlash deceleration effect. For example, on a machine that rotates at a speed of 600 rpm, how much time do we need a lot of energy?

  A machine that rotates at 600 rpm rotates at 10 rps. The diameter of the slip ring rectifier is 60 mm and the width of the distributor is 20 mm. Therefore, this distributor contacts the carbon brush for 0.01 seconds. This is 1 / 100th of a second and of course short. This is the pulse duration. The permanent magnet stator supplies torque necessary for movement for the remaining time of one rotation. The energy stored in the permanent magnet is converted into mechanical energy.

  Television also uses the concept of eye deception. A small dot from the object hitting the retina remains for a few seconds. If this happens quickly enough, different points will appear continuously and the eyes will “see” the whole picture as one.

  It can be said that the Emergent Dynamics machine sees a pulse of energy appearing at the backlash point as one continuous chain thanks to the energy gap covered by the permanent magnet stator.

(Section 6)
The advantages of self-supporting magnetodynamic motors over conventional electric motors are clear. This means that this motor can replace any electric motor that is currently used. This includes but is not limited to electric cars, trains, trolley trains, electric fans and the like. If you can make a small-scale magnetodynamic motor, you can replace electric motors such as watches, grinders, and toys. It is also possible to introduce these important devices that do not require electricity or batteries to operate by introducing a small magnetodynamic machine to supply current to a television set or radio. Of course, the Emergent Dynamics machine has the ability to revolutionize our lifestyle. Energy savings for humanity will be enormous. Aside from the ability of energy to disturb the world's peace, machines that do not require external energy input to operate in a world where energy is depleted and very expensive are of great interest and have industrial value. .

  The successful design of the magnetodynamics motor, which took 31 years to achieve, and the theory of the magnetodynamics opened up a new field of learning in science and engineering. This is a field that needs to be explored more deeply by scientists and engineers around the world. Of course, the inventor considers this field to be a very interesting and exciting field.

  Further research work in this area finds, but is not limited to, the detailed characteristics of the EMG magnetodynamic machine and how they are compared to those of conventional electric motors and internal combustion engines. Will be included.

(Section 7)
In a broad embodiment, the invention is also a motor that operates on the basis of the interaction principle of permanent magnets or electromagnets using a law of emermodynamics different from the force acting on the conductor carrying the current in the magnetic field.

  The theory of emagnetodynamics is the product of the inventors' research on magnets that lasted 31 years.

  Other versions of the machine do not have vanes. A soft iron slab is affixed on the rotor as an angular dispersion. The rotor itself is made larger in diameter to accommodate this design change. This version is very similar to a conventional electric motor and has only two split ring rectifiers. The surface can be 30 or more, which leads to a more powerful and simple machine that operates above 2000 rpm.

9,11 Ball bearings at the bottom and top 10 Circular brass plates (diameter 500mm, thickness 10mm) that form the base of the machine
12 Ignition key to switch on the machine (typical car, eg Volkswagen, ignition key is suitable)
14 Group of feedback generators that also function as kickstarters 15 Rectangular Perspex plate (180 x 180 x 5 mm) holding a carbon brush
16 Slip ring rectifier
18, 19, 20 Surface 1 Permanent Magnet Stator 21 Motor Battery 12 Volt DC
22, 32 Release electromagnet for face 1 23 Resistance suitable for protection of feedback generator / kickstart motor 24, 36 Release electromagnet for face 4 25 Kick starter motor / feedback generator 12 volt Current rich 26 Rotor shaft (small rotation) Child stem), brass, 30mm diameter
27 Distributor, Copper 28 Copper Shackle Rectangular Plate 29 Slip Ring Copper Rectifier 30 Clutch Pedal 31 Carbon Brush 33, 35, 37, 39, 41, 43, 45, 47 Carbon Brush for Energizing the Release Electromagnet 38, 40 Rectangular permanent magnet forming a composite pole 42 Aluminum vane plate to hold the composite pole 50 Brass vane plate stem, length, diameter 10 mm
52 Wing plate stabilizer, length 25mm, diameter 5mm
54 Aluminum former for release electromagnet wound with insulated copper wire with a total resistance of 14 ohms and a diameter of 0.5 mm, length 150 mm, inner diameter 37.2 mm, outer diameter 39 mm
56 Soft iron core for electromagnet, length 160mm, diameter 37mm
66, 78 Release electromagnet 68, 70, 72 Permanent magnet stator 76 Inner hole of aluminum vane plate 82, diameter 84 Circular arm, diameter and width 86 Clutch shank, outer tube of outer diameter 88, outer diameter, mm length 90 Slip ring rectifier carrying distributor 92 idle copper separator
96 Return generator 97 Clutch fiber attached to flywheel (made of skin material) 98 Pulley connected with gear on generator 99 Clutch cable 100 Flywheel connected with gear attached to rotor shaft

Claims (16)

Uses its own feedback current to operate, operates like an electric motor, but does not use the force acting on the conductor carrying the current in the magnetic field, but operates by the magnetic pole interaction between the stator and rotor A self-supporting machine powered by a magnet and an electromagnet,
A set of permanent magnets forming a stator of the machine arranged in a circular pattern;
A composite magnet attached to a spindle forming a rotor;
A distributor for applying pressure to the brushes to release the rotor blades (on each face) from the backlash resulting from repulsion / traction of the rotor composite poles Machine.   The self-supporting machine according to claim 1, wherein the permanent magnets forming the stator are made such that half of the magnets are north poles and the other half are south poles.   The electromagnet forms a release stator pole of the machine and is made to have a pole strength approximately equal to the respective pole strength of the stator permanent magnet, and if not magnetized, the first stator The self-supporting machine according to claim 1, wherein the time interval is determined so as to be temporarily magnetized at an appropriate timing to be pulled back by repulsion / traction by a permanent magnet.   The blade and spindle holding the composite pole are all made of a non-magnetic material such as brass or copper so as not to distort the magnetic field generated by the stator magnet. Self-supporting machine.   The inventor's first law of electromagnetic dynamics states that suspended composite magnetic poles move in one direction when placed near the same pole array of magnets. Self-supporting machine.   2. The self-supporting machine according to claim 1, wherein the inventor's second law of the magnetodynamics states that the direction of rotation of the composite magnetic pole is the same direction of the composite pole as the array.   Soft iron loses its magnetism very quickly, and in order to obtain it, the soft pole acts as a mirror image (substitute) of the stator permanent magnet, so that the composite pole is bent into the same crescent shape. The self-supporting machine according to claim 1, wherein the self-supporting machine is replaced by a disk.   The self-supporting machine of claim 1, wherein the brush and the rectifier are made of copper or other non-magnetic but non-rusting metal.   The rotor is mounted on the rotor made of brass, copper or any other rigid non-magnetic material with the vane to which the composite pole is mounted resting on a horizontal plane. The self-supporting machine according to claim 1, configured as described above.   The blades attached to the rotor, like the crankshaft of an internal combustion engine, are placed on different surfaces in order to increase the mechanical power output by the machine, but all are the same The self-supporting machine of claim 1, wherein the self-supporting machine can be configured such that there are two or more vanes attached to the rotor.   The self-supporting of claim 1, wherein the stator magnet can be configured to be mounted on a different surface of the machine to increase the mechanical power output by the machine. Machine.   Similar to the ignition key of an automobile, at the start of the machine, the electrical output is also transmitted via a switch to the first or last electromagnet and also to a small DC motor mounted on the rotor. The self-supporting machine according to claim 1.   13. The self of claim 12, wherein the DC motor mechanically coupled to the rotor is used to rotate the rotor at the start of the magnetodynamic motor in a "kick start" process. Support machine.   The self-supporting machine of claim 11, wherein the stator magnets mounted on different sides of the machine are magnetically shielded from each other so as not to distort their magnetic fields from each other in operation.   The self-supporting machine according to claim 1, wherein the arrangement of the stator and the rotor can be reversed, and the laws of the magnetodynamics are still applied to produce operation.   The self-supporting machine according to claim 1, wherein the stator, which is a permanent magnet, is replaced with an electromagnet without deteriorating the operation of the system.

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