JP2007295778A - Elementary particle motor and elementary particle repulsion type high-speed torque fluctuation three-phase motor therewith - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an elementary particle motor rotated by using a ferromagnet body or a superconductive conductor, and using a repulsion effect of the elementary particle existing in the nature world and an ultra high-speed torque fluctuation three-phase motor amplified using the elementary particle motor. <P>SOLUTION: In this elementary particle motor formed of a pair of sleeve-type superconductive conductor coil stator and a sleeve-type superconductive conductor coil rotor, a repulsion force effect range angle is formed by disposing the stator and the rotor so that the N-poles of the stator and rotor may face each other and may be relatively displaced, the repulsion force effect range against the elementary particle existing in the nature world is formed, and the rotational force of the rotor is generated. Besides, the elementary particle motor constituted of the sleeve-type superconductive conductor coil stator and the sleeve-type superconductive conductor coil rotor is made to serve as the high-speed torque fluctuation three-phase motor which forms a rotational magnetic field by making a current flow to the coil of the rotor. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention is a novel elementary particle motor that is composed of a pair of a cylindrical superconducting coil stator and a cylindrical superconducting coil rotor, and generates a rotational force by utilizing the repulsive force of elementary particles existing in nature. The present invention relates to an elementary particle repulsion type high-speed torque fluctuation three-phase motor.

  Ordinary three-phase motors are composed of a combination of a stator made of permanent magnets and a rotor made of winding coils. Recently, superconducting materials have been developed, and three-phase motors and other electric motors using this have been developed. Various devices have been proposed.

  On the other hand, attempts have been made to improve the kinetic energy by utilizing the energy of elementary particles existing in nature, such as neutrons and pions, and combining them with low-temperature superconducting materials, but this has not been realized yet.

  That is, as a superconducting motor, a non-magnetic cylindrical casing, a permanent magnet cylindrical stator that is integrally provided radially on the inner wall surface, and a non-magnetic holding plate is integrally provided on both end faces, and a non-magnetic Body rotation shaft, non-magnetic cylindrical permanent magnet holding plate integrally provided on the outer periphery, a cylindrical rotor made of permanent magnet integrally provided on the outer wall surface of the holding plate, and integrally provided on both end faces thereof A non-magnetic holding disc, a cylindrical shape provided in the inner peripheral surface of the permanent magnet cylindrical stator with a predetermined gap, and concentrically and radially with respect to the permanent magnet cylindrical stator. A primary winding coil wound inward a required number of times within a gap between the rotating body, the permanent magnet cylindrical stator and the permanent magnet cylindrical rotor, and a secondary winding wound outside the primary winding coil a required number of times. Next wire coil And a non-magnetic rotating shaft are fitted in the recesses formed on the inner sides of the non-magnetic rotating shaft, and are integrated with both ends of the non-magnetic cylindrical rotating body. A superconducting motor comprising a nonmagnetic end cover provided and an auxiliary motor provided at one end of the nonmagnetic rotating shaft (see Patent Document 1), a rotating shaft fixed at the center, and a predetermined magnetic field capable of being magnetized A disk-shaped rotor portion having a thick superconductor or ferromagnetic body, the surface of the superconductor or ferromagnetic body being magnetized by N or S poles, and the back surface being magnetized by S or N poles And a stator (see Patent Document 2), magnet or superconducting device having a plurality of magnetic cores arranged in an annular shape facing the trajectory of rotation of the rotor portion and an exciting coil wound around the magnetic core Consists of a stator and a rotor excited by a coil In the driving force generator, the stator and rotor are both formed parallel to the drive shaft, and all the poles on the opposite side of the iron core provided at the shaft end have the same polarity. The magnetic poles of the rotor and the magnetic poles of the rotor are repelled to generate a driving force, and the number of stator magnetic poles facing the rotor magnetic poles is the same as or different from the number of rotor poles. There has been proposed so far that a driving force is always generated in the rotational direction regardless of the relative position (see Patent Document 3).

  On the other hand, inorganic materials and minerals are made into ultrafine particles, causing an anti-oxidation film phenomenon, free energy and elementary particle energy are linked together using silica ultrafine particles and pure water as a medium, and 6 of the top quarks in neutrons. There has also been proposed a motor (see Patent Document 4) that is driven by causing a harmonic resonance wave through six elementary particles around a neutron and a pion around one channel.

JP-A-5-56627 (Claims and others) JP-A-7-107720 (Claims and others) JP 2004-312885 A (Claims and others) JP-A-9-313933 (Claims and others)

  The present invention provides an elementary particle motor that uses a ferromagnetic material or a superconductor to rotate by utilizing the repulsive action of elementary particles existing in nature, and an ultrahigh-speed torque fluctuation three-phase motor that is amplified using the same. It was made for the purpose.

  The present inventor has conducted various studies on a method for amplifying torque fluctuations of a three-phase motor by utilizing the repulsive action of elementary particles and increasing the speed, and as a result, a rotor is disposed between two stators. In the torque fluctuation three-phase motor having the structure, the stator is formed of a power generation superconducting coil and a superconducting coil, the rotor is formed of a superconducting coil, and each coil is divided into 12 parts. It was found that the object can be achieved by maintaining the mutual positions so that the magnetic poles repel and always generate a driving force, and the present invention has been made based on this finding.

  That is, the present invention is a motor formed from a pair of a cylindrical superconducting coil stator and a cylindrical superconducting coil rotor, and the two are arranged so that their N poles face each other and are relatively displaced. In this case, a repulsive force acting area angle is provided to form a repulsive force acting area for the elementary particles existing in nature, and the rotational force of the rotor is generated. In an elementary particle motor composed of a stator and a cylindrical superconducting coil rotor, a rotating magnetic field is formed by passing a current through the coil of the rotor. Cylindrical inner stator 2 made of superconductor or ferromagnetic, cylindrical rotor 3 made of superconductor or ferromagnetic, and cylindrical outer stator 4 made of superconductor or ferromagnetic In the torque fluctuation three-phase motor having a structure in which concentric circles are sequentially arranged and the entirety is housed in a heat insulating cylindrical casing 5, the inner stator 2, the rotor 3 and the outer stator 4 are each made of an insulating partition wall 6. The rotor 3 and the outer stator 4 are magnetized so that the N pole and the S pole are in opposite directions for each adjacent section, and the rotor 3 The magnetic poles of the outer stator 4 and the magnetic poles of the outer stator 4 are kept at positions that repel each other and always generate a driving force, and the rotor 3 is integrally formed with the insulator layers 9 and 10 on both outer surfaces. The insulating layers 9 and 10 and the insulating partition walls 7 in the rotor 3 form a coolant or lubricating liquid supply line, and the rotor 3 is divided into two sections. It is connected to the three-phase conversion mechanism through three different electrodes And a superconducting coil formed by folding in quadruple, energizing two coils outside the two inner coils. Thus, a dielectric voltage resistance is generated in the two inner coils, and a superconducting coil that provides resistance in the current circuit is provided.

  According to the present invention, there is an effect that a superconducting coil is used to capture the kinetic energy of elementary particles existing in nature and efficiently convert them into a power source for use.

Next, the best mode for carrying out the present invention will be described with reference to the accompanying drawings.
FIG. 1 is an explanatory diagram showing the operation of the superconducting coil. The magnetic field lines indicated by solid arrows from the N pole to the S pole formed by the superconducting coil have a magnetic flux density of about 1000 Tesla. In the vicinity of the S pole of this superconducting coil, an attractive force action region is formed, and elementary particles from above are sucked in the direction of the upper chain line, and in the vicinity of the N pole, a repulsive force action region is formed. Is repelled in the direction of the lower chain arrow.

  FIG. 2 shows a motor formed of a pair of cylindrical superconducting coil stator and cylindrical superconducting coil rotor according to the present invention, in which both are relatively displaced along a line direction inclined with respect to the rotor axis. FIG. 5 is an explanatory diagram showing the behavior of the rotor when both N poles are arranged to face each other, and the solid line arrows indicate the direction of the magnetic force lines of the stator and the rotor. In the positional relationship between the stator and the rotor arranged in this way, a rotational force in the right arrow direction is generated as a vector sum of the repulsive force of the elementary particles from above and the repulsive force of the elementary particles from below. .

FIG. 3 shows the repulsive force of elementary particles when a plurality of pairs of a cylindrical superconducting coil stator and a cylindrical superconducting coil rotor are arranged with their N poles facing each other along a line inclined with respect to the axis of the rotor. In the upper and left sides of the stator, a repulsive force as shown by a chain line arrow is generated, and in the lower and right sides of the rotor, a repulsive force as shown by a chain line arrow is generated. A rotational force indicated by a solid arrow is generated as a sum, and the rotor is rotated.
The elementary particle motor of the present invention is operated by the rotational force generated in this way.

  Next, FIG. 4 shows that when a current that generates a rotating magnetic field is applied to the superconducting coil of the rotor so that the rotor rotates in the counterclockwise direction, that is, in the direction of the solid arrow, the rotor is clocked with reference to the NS of the stator. It is explanatory drawing which shows rotating in a direction, ie, the direction of a white arrow.

  Further, FIG. 5 also shows that when a current that generates a clockwise rotating magnetic field is also applied to the stator in the clockwise direction (solid arrow direction), also in the clockwise direction, that is, in the direction of the white arrow, also with reference to NS. Although it is explanatory drawing which shows rotating, in this case, the rotation speed becomes twice as compared with the case of FIG.

FIG. 6 is an upper sectional view of an example of the structure of the three-phase motor (three-phase, eight poles) of the present invention, and FIG. 7 is a side sectional view.
In the three-phase motor of the present invention, a fixed shaft 1 is fixed to the center of a cylindrical casing 5 made of a heat insulating material such as FRP, and a cylindrical inner stator 2 forming a superconducting power generation stator coil is fixed to the fixed shaft 1. Are integrally fixed. The cylindrical inner stator 2 is preferably made of a superconductor, but may be made of a ferromagnetic material such as magnetite in the case of low speed rotation.

  The inside of the cylindrical inner stator 2 is radially divided into 12 by an insulator, for example, reinforced ceramics 6. On the outside of the inner stator 2, a cylindrical rotor 3 is disposed concentrically and rotatably with the fixed shaft 1 and the inner stator 2. The cylindrical rotor 3 is preferably made of a superconductor, but may be made of a ferromagnetic material when rotating at a low speed. This has a function as an elementary particle repulsion superconducting rotating coil, and rotates at a speed of 600 to 30000 rpm.

  The inner surface and the outer surface of the rotor 3 are integrally covered with layers 9 and 10 made of an insulator, for example, reinforced ceramic. Further, the interior of the rotor 3 is vertically divided into 12 by partition walls 7 made of the same insulator as described above. These partition walls 7 are attached to the wall surface of the rotor 3 in an oblique direction.

  The insulator layers 9, 10 provided on the inner and outer periphery of the rotor 3 and the partition walls 7 form a supply line of a cooling liquid or a lubricating liquid, and the vicinity of the contact point between the partition walls 7, and the insulator layers 9, 10. Are provided with inlets 14... And outlets 15. Each divided section of the rotor 3 is magnetized so that the N pole and the S pole are in opposite directions for each adjacent section.

  Next, the outer stator 4 is fixedly disposed outside the rotor 3, which is also divided into 12 parts by the insulating partition walls 8... Each section is magnetized so that the N pole and the S pole are in opposite directions.

  The magnetic poles of the rotor 3 and the magnetic poles of the outer stator 4 must be kept repulsive to always generate a driving force by the arrow method.

  8 and 9 are drawings for explaining the parts of the mercury brushes 11, 12, and 13 shown in FIG. 7 in more detail. FIG. 8 is a side sectional view, and FIG. 9 is a plan sectional view. is there. This part consists of mercury brushes 11, 12, 13 and electrodes 16, 17, 18 connected thereto, and the mercury brushes are divided into three different fractions of the cylindrical rotor 3 via superconducting wires 19, 20, 21 respectively. Connected to the designated partition.

  On the other hand, when the electrodes 16, 17 and 18 are mounted on an automobile, for example, they are connected to a three-phase inverter interlocking with the accelerator, and the accelerator is shifted in three stages of low, second, and top to thereby respectively change the cylindrical rotor. 3 is input to the corresponding section, and torque fluctuation is performed. The superconducting wires 19, 20, 21 and the mercury brushes 11, 12, 13 are covered with an insulating material such as FRP 22, 23.

  FIG. 10 is a connection diagram of an example when the relay contact is changed in three stages in the above-described shift shift. (A) is a low voltage, (B) is a second voltage, and (C) is In the case of the top voltage, in the case of the low voltage, all four batteries are connected in parallel, and in the case of the second voltage, two sets of four batteries are connected in series to form two sets. The set is connected in parallel, and in the case of the top voltage, all four batteries are connected in series.

FIG. 11 shows the relationship between the electromagnetic relay circuit and the connection during the same three-step switching. (A) In FIG. 11, when the gear is set to low, the circuit [1] is formed and B and D are activated. . Then, in (b), the connection of b ³ , b ⁴ , d ^{2 and} the connection of d ¹ , b ¹ , b ² are established, and four batteries are connected in parallel.
When the gear is placed in the second position, the relay circuit [2] in FIG. Then, a closed connection is established with b ³ , b ⁴ , c ¹ , b ¹ , and b ² in (b), and two combinations of two batteries in parallel are connected in series. Next, when the gear enters the top (a), the relay circuits A and C in [3] in FIG. 6 are activated, and (a) a ² , c ¹ , a ¹ in FIG. Connected.
By connecting the electrodes of the three-phase motor to the three-phase inverter linked to the accelerator in this way, the torque can be varied at an ultra high speed.

  Next, in the elementary particle repulsive super high speed torque fluctuation three-phase motor of the present invention, C. By attaching the resonance current generating mechanism, the current from the power source can be increased up to about 100 times, and therefore the magnetic flux density in the stator can be increased to 1000 Tesla or more. In general, when a magnetic field having a magnetic flux density of 1000 Tesla or more is formed, elementary particles existing in the natural world are easily captured, so that the working efficiency of the elementary particle repulsive ultra-high speed torque fluctuation three-phase motor of the present invention is remarkably improved. Can be made.

  Next, FIG. 12 is a side sectional view for showing a coolant or lubricating fluid supply line in the three-phase motor of the present invention. When a superconductor is used as a coil, a coolant such as liquid nitrogen is used. When a magnetic material is used, a lubricating liquid such as lubricating oil is supplied along a route indicated by an arrow.

  That is, the coolant from the cooling radiator or the lubricant from the oil tank is provided in the insulator layer attached to the surface of the rotor 3 through the gap between the fixed shaft 1 and the inner stator 2. Circulates through the flow path and the flow path provided inside the insulating partition, and is finally discharged from the discharge port 24.

  Coolant or lubricating liquid injection reaching the outer wall surface of the outer stator 4 is provided in the flow path of the cooling liquid or lubricating oil supply line formed in the insulator layer 10 provided on the outer surface of the cylindrical rotor 3. An inlet 14 is provided, and a centrifugal force generated when the cylindrical rotor 3 rotates is used to apply pressure to the outer wall surface of the outer stator 4 with a cooling liquid or a lubricating liquid, and is generated when the rotor 3 rotates. To reduce surface friction. Thereby, damage to the rotor 3 and the outer stator due to the high-speed rotation of 600 to 30000 rpm can be prevented.

  Next, FIG. 13 is a side view of the elementary particle repulsive ultrahigh-speed torque fluctuation three-phase motor in a state where the heat insulating cylindrical casing is removed. As can be seen from this figure, in the three-phase motor of the present invention, the outer stator 4 is composed of twelve superconducting coils. This superconducting coil is formed by folding a plate-shaped superconducting material into four layers. Have a structure.

  By the way, in the plate-shaped superconducting material folded in this way, the two plates are exposed to the outside, and the two plates are confined inside. When a current is passed through the coil in such a state, an induced voltage resistance is generated in the two inner plates due to the current flowing in the two outer plates, and against the current flowing from the outer plate to the inner plate. It works against it. For this reason, although this coil has few turns, since resistance becomes large, it becomes possible to flow a big electric current.

  Next, FIG. 14 is a connection diagram showing the relationship between the stator 4 and the rotor 3 of the automatic torque adjusting type three-phase directly wound elementary particle repulsion motor. The three coils 28, 29, 30 in the rotor 3 are connected to the three coils 25, 26, 27 in the stator 4 via mercury brushes 11, 12, 13, and the stator coil 27 Is connected to the inverter 31 and inputs the current from the power source 32. The power source 32 and the inverter 31 are the same as the above-described L.P. C. A resonance current generating mechanism is configured, and the current supplied from the power supply 32 can be amplified 100 times.

  According to the present invention, since an efficient motor can be configured using elementary particles existing in nature, it can be used as various power sources.

Explanatory drawing which shows the effect | action of a superconducting coil. Explanatory drawing which shows the behavior of the rotor of the motor formed from a pair of cylindrical superconducting coil stator and cylindrical superconducting coil rotor of this invention. Explanatory drawing which shows the effect | action of the motor which consists of multiple pairs of a cylindrical superconducting coil stator and a cylindrical superconducting coil rotor. Explanatory drawing for demonstrating rotation of a rotor when an electric current is sent through the superconducting coil of a rotor. Explanatory drawing for demonstrating rotation of a rotor when the electric current which generate | occur | produces a rotating magnetic field is sent with respect to a stator. The upper sectional view of one example of the structure of the three-phase motor of the present invention. The plane sectional view of one example of the structure of the three-phase motor of the present invention. FIG. 8 is a side sectional view of the mercury brush shown in FIG. 7. FIG. 8 is a plan view of the mercury brush shown in FIG. 7. The connection diagram of an example when a relay contact is changed in three steps in a gear shift. The figure which shows the relationship between the electromagnetic relay circuit and connection in the case of the same 3 step switching. The side sectional view for showing the cooling fluid or lubricating fluid supply line in the three-phase motor of the present invention. The side view of the elementary particle repulsive super-high-speed torque fluctuation three-phase motor in the state which removed the heat insulation cylindrical casing. The connection diagram which shows the relationship between the stator and rotor of an automatic torque adjustment type | formula three-phase direct-wound particle | grain repulsion motor.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Fixed shaft 2 Cylindrical inner stator 3 Cylindrical rotor 4 Cylindrical outer stator 5 Insulating cylindrical casing 6, 7, 8 Insulating partition 9, 10, Insulator layer 11, 12, 13 Mercury brush 14 Inlet 15 Discharge port 16, 17, 18 Electrode 19, 20, 21 Superconducting wire 22, 23 Insulating material 24 Discharge port 25, 26, 27, 28, 29, 30 Coil 31 Inverter 32 Power supply

Claims (9)

  In a motor formed from a pair of a cylindrical superconducting coil stator and a cylindrical superconducting coil rotor, both are arranged so that their N poles are opposed to each other and are relatively displaced so that the repulsive force action range An elementary particle motor characterized in that, by providing an angle, a repulsive force action region for elementary particles existing in nature is formed, and the rotational force of the rotor is generated.   The elementary particle motor according to claim 1, wherein the motor is formed of a plurality of pairs of a cylindrical superconducting coil stator and a cylindrical superconducting coil rotor.   A high-speed torque fluctuation three-phase motor characterized in that a rotating magnetic field is formed by passing a current through a coil of the rotor in an elementary particle motor composed of a cylindrical superconducting coil stator and a cylindrical superconducting coil rotor.   4. The high-speed torque fluctuation three-phase motor according to claim 3, wherein a rotating magnetic field is formed by passing a current in a direction opposite to a current passed through the rotor through the stator.   A cylindrical inner stator made of superconductor or ferromagnetic, a cylindrical inner rotor made of superconductor or ferromagnetic, and a cylindrical outer stator made of superconductor or ferromagnetic are successively concentric around the fixed axis. In the torque fluctuation three-phase motor having a structure in which the whole is housed in a heat-insulating cylindrical casing, the inner stator, the rotor and the outer stator are each divided into 12 vertically by an insulating partition, The rotor and the outer stator are magnetized so that the N pole and the S pole are in opposite directions for each adjacent section, and the rotor magnetic pole and the outer stator magnetic pole are repelled and driven constantly. The rotor is maintained at a position where force is generated, and the rotor is integrally provided with an insulator layer on both outer surfaces. The insulator layer and the insulating partition in the rotor are used to cool or lubricate the rotor. Liquid supply line is formed And Oyobi three particle resilience ultrafast torque variation three-phase motor, characterized in that each is connected to the three-phase exchange mechanism through different electrodes compartments every respective two of the rotor.   The cylindrical inner stator, cylindrical rotor, and cylindrical outer stator are each made of a superconductor, and a coolant supply line is formed by the insulator layers on both outer surfaces of the rotor and the insulating partition walls in the rotor. The elementary particle repulsive ultrahigh-speed torque fluctuation three-phase motor according to claim 5.   The three-phase motor according to claim 5 or 6, wherein three different electrodes are coupled to a mercury brush.   L. C. The elementary particle repulsive ultrahigh-speed torque fluctuation three-phase motor according to claim 5, further comprising a resonance current generating mechanism.   It is a superconducting coil formed by folding four times, and when a current is supplied to two outer coils of the two inner coils, a dielectric voltage resistance is generated in the two inner coils, and a current circuit Superconducting coil that gives resistance inside.

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