WO2016006015A1

WO2016006015A1 - Power generator for counter-rotating magnetic field element and armature with each other with equal angular momentum

Info

Publication number: WO2016006015A1
Application number: PCT/JP2014/003627
Authority: WO
Inventors: 萩野　芳造
Original assignee: 萩野　芳造
Priority date: 2014-07-08
Filing date: 2014-07-08
Publication date: 2016-01-14

Abstract

Provided is an axial rotating power generator comprising a magnetic field element for producing a magnetic field and an armature for extracting a generated electrical current, in which a winding coil of the armature traverses the magnetic field formed by the magnetic field element to generate an electromotive force in the armature coil according to Fleming's right-hand rule. In the power generator, an external power is divided between a first external power unit and a second external power unit to counter-rotate the magnetic field element and the armature with each other with equal angular momentum such that the angular momentum of the armature and the angular momentum of the magnetic field element are equal, in which a first external power is transmitted to the armature to rotate the armature in a positive direction, a second external power is transmitted to the magnetic field element to rotate the magnetic field element in a direction opposite the rotating direction of the positive direction of the armature, the armature and the magnetic field element rotate in directions opposite of each other with equal rotational angular momentum, and the winding coil of the armature traverses the magnetic field formed by the magnetic field element to generate an electromotive force in the coil. As such, the reaction between the armature and the magnetic field element when rotating in forward and reverse directions to generate power is canceled, and leakage of the electromagnetic energy generated by the external power to the ground through the body of the power generator is prevented.

Description

A generator that reversely rotates a magnetic element and armature with equal angular momentum

The present invention relates to a generator that reversely rotates a magnetic element and an armature with equal angular momentum. In the present invention, a generator refers to a device that converts electromagnetic energy into electrical energy by applying electromagnetic induction by rotating a shaft, and includes a magnetic element that generates a magnetic field and an armature that extracts a generated current. By rotating the coil relatively, an electromotive force is generated in the armature coil according to Fleming's right-hand rule.

Conventional technology

In conventional generators, a heavy permanent magnet or an electromagnet with a coil wound around a pig iron core is fixed as a stator on the generator body installed on the ground, and the armature is rotatably supported inside the fence stator. When the coil of the child is rotated, if the magnetic flux generated from the stator is B, the voltage E = v · B is generated by Fleming's right-hand rule in the armature wire coil that crosses and moves across the magnetic flux B. It has a structure. In the equation, v is a crossing moving speed with respect to the magnetic flux B on the outer periphery of the armature rotor.

In conventional generators, external power rotates the armature, generating a voltage in the armature coil. In this case, the earth's falling hydropower, wind power, seawater flow, or artificially generated pressure power of steam is used as external power. The generator always has a load, and the current I flows from the output terminal connected to the load to the coil by the voltage (electromotive force) E generated in the coil of the armature rotated by the input power. The current I generates a force of F = I · B according to Fleming's left-hand rule with a magnetic flux B from a fixed magnetic element. The direction of the force is the force F acting in the direction opposite to the rotation direction by the input power of the generator, and the reaction force F.

In the conventional generator, the armature is rotated by the input power that always surpasses the force of F = I · B generated by Fleming's left-hand rule, and the electric energy of the product EI with the voltage E and the current I flowing to the output terminal is obtained. I have output. Conventional generators have a magnetic field as a stator attached to a ground-mounted main body, and use a voltage E generated between a light rotor armature and a magnetic flux B from the stator. Thus, the reaction between the armature and the magnetic field of the stator has acted as a reaction force from the stator to the ground via the generator body installed on the ground, and the accompanying energy has flowed out. This is the actual situation of conventional generators. See Non-Patent Document 1 for the action and reaction.

In the generator of the present invention, the energy of the reaction force acting on the magnetic element due to the reaction generated between the armature and the magnetic element due to the current flowing through the load in the conventional generator passes through the generator main body installed on the ground. The purpose is to prevent the phenomenon that flows out to the ground.

(1) The generator of the present invention includes a magnetic element that generates a magnetic field and an armature that extracts a generated current, and the winding coil of the armature traverses the magnetic field formed by the magnetic element. In the shaft rotation type generator that generates electromotive force in the armature coil according to the law,
The generator has a configuration in which a magnetic element and an armature are mutually rotated in reverse with equal angular momentum,
The external power is divided into a first external power unit and a second external power unit so that the angular momentum of the armature and the angular momentum of the magnetic field element are equal,
Transmitting the first external power to the armature and rotating the armature in the positive direction;
By transmitting the second external power to the magnetic element and rotating the magnetic element in a direction opposite to the normal direction of rotation of the armature,
The armature and the magnetic element are rotated with equal rotational angular momentum in opposite directions, and an electromotive force is generated in the armature coil by traversing the armature winding coil in the magnetic field formed by the magnetic element. And the generator.

(2) Furthermore, a first external power transmission device that transmits the first external power to the armature and rotates the armature in the forward direction; and a second external power that is transmitted to the magnetic element and transmits the magnetic element to the armature. The motor according to (1), further including a second external power transmission device that rotates in a direction opposite to the forward rotation direction.

(3) Furthermore, an external power split device that splits external power into a first external power unit and a second external power unit so that the angular momentum of the armature and the angular momentum of the magnetic field element are equal is provided. ) Generator.

(4) having a rotating shaft rotatably supported by the generator body, the magnetic element being fixed to the rotating shaft and rotating together with the rotating shaft, and the armature facing a cylindrical shape drawn by the magnetic element. The generator according to any one of (1) to (3).
(5) The generator according to any one of (1) to (4), wherein the magnetic field element is formed of a permanent magnet.

(6) The power generation method of the present invention includes a magnetic element that generates a magnetic field and an armature that extracts a generated current, and the winding coil of the armature crosses the magnetic field formed by the magnetic element so that the right hand of Fleming In a power generation method for generating an electromotive force in an armature coil according to the law,
The external power is divided into a first external power unit and a second external power unit so that the angular momentum of the armature and the angular momentum of the magnetic field element are equal,
Transmitting the first external power to the armature and rotating the armature in the positive direction;
By transmitting the second external power to the magnetic element and rotating the magnetic element in a direction opposite to the normal direction of rotation of the armature,
Rotate the armature and magnetic element with equal angular momentum in opposite directions,
A power generation method, wherein an electromotive force is generated in an armature coil according to Fleming's right-hand rule when an armature winding coil crosses a magnetic field formed by a magnetic element.

In the generator of the present invention, the external power is divided into the first external power unit and the second external power unit by the external power splitting means so that the angular momentum of the armature and the angular momentum of the magnetic element are equal. The first external power unit and the second external power unit are transmitted to the armature and the magnetic element, respectively, and the armature and the magnetic element are rotated in the opposite directions with the same rotational angular momentum. The reaction between the armature and the magnetic element cancels each other at the time of rotation, and electromagnetic energy by external power can be prevented from flowing out to the ground through the generator body. In the present invention, the reaction against the movement of the armature by the input power of the generator and the reaction against the electromagnetic action of power generation are substantially eliminated, and the input energy can be converted into electromagnetic energy purely without reaction.

It is a cross-sectional view of a magnetic element and an armature of a three-phase bipolar dielectric power generator according to an embodiment of the generator of the present invention. FIG. 3 is a cross-sectional view schematically showing a state in which a magnetic element and an armature are rotating in opposite directions with equal angular momentum in a three-phase bipolar dielectric power generation device according to an embodiment of the generator of the present invention. However, for simplicity of understanding, the magnetic field element is shown in a stationary state. The electromotive force obtained in the three-phase bipolar dielectric power generator according to one embodiment of the generator of the present invention is shown. It is the schematic of the cross section of the IV-IV line | wire of FIG. 1 of the three-phase bipolar dielectric power generator which concerns on one Example of the generator of this invention. It is the schematic of the three-phase synchronous electric power generating apparatus which concerns on another Example of the generator of this invention. DESCRIPTION OF SYMBOLS 1 ... Generator main body, 2 ... Circular vertical hole part, 3 ... Armature, 3a ... Frame, 3b ... Coil support body, 3c ... Coil, 4 ... Magnetic element , 6 ... rotating shaft, 7a ... bearing bearing, 8 ... gear, 9 ... gear, 10 ... external power split device, 11 ... rotating shaft, 11a ... bearing bearing, DESCRIPTION OF SYMBOLS 12 ... Slip ring, 21 ... Generator main body, 22 ... Circular vertical hole part, 23 ... Armature, 24 ... Magnetic field element, 26 ... Rotating shaft, aa ', b -B ', cc' ... electrical winding, C ... control device, E ... right cylindrical end plate, P ... external power, P1 ... first external power part , P2 ... second external power unit, M ... generator, M1 ... first external power transmission device, M2 ... second external power transmission device, v1 ... armature Rotational speed Degrees, v2 ... Rotational speed of magnetic field element

Below, the generator of this invention is demonstrated. The present invention refers to an apparatus or a machine that generates electricity by rotating a shaft, and includes a “magnetic element” that generates a magnetic field and an “armature” that extracts a generated current. When the magnetic field and the armature coil are rotated relatively, an electromotive force is generated in the armature coil according to Fleming's right-hand rule. In the generator of the present invention, for the sake of simplicity, the rotation direction of the magnetic element is assumed to be forward rotation, and the rotation direction of the armature is assumed to be reverse rotation. The generator of the present invention is the same as or similar to the conventional generator except for the configuration in which the magnetic element and the armature are reversely rotated with an equal angular momentum and the configuration related to the external power split.

First, how the present invention was completed will be described.
Newton's principal, which is the foundation of engineering from modern physics (see Non-Patent Document 1), Law 3 followed by System 1 to System 4 as vectors, based on analysis of force, speed, and momentum, The reaction is always accompanied. There is no self-motion that does not react to adjacent objects, and there has never been any mechanics or industry. It is the definition of the action of such a big concept.

Reference: Principa Philosopdice Naturalis. Principia Mathematica
Rule 1: All objects continue to be stationary or in a uniform motion state on a straight line unless their state is changed by the force applied to them.
Law 2: The change of motion is proportional to the applied power and is performed along the direction of the straight line where the force is applied.
Rule 3: For every action there is always an equal and opposite reaction. That is, the interaction between two objects that work with each other is always the same and goes in the opposite direction, so they cancel each other.

In addition to the non-reactionless motion that is not defined in the principal, the conventional algorithm is that the sum of the vectors in the opposite direction in the dynamics is zero. In one rotator, the sum of momentums of equal amounts in opposite directions on the same rotation axis becomes zero, so the rotator remains stationary, but the two coaxial cylindrical rotators around the central axis are Symmetric rotation of equal angular momentum is possible.

It is also possible to rotate a pair of rotating bodies attached via bearings around a common central axis. For the sake of convenience, rotations that are reversely rotated to each other are referred to as forward rotation and reverse rotation, respectively. In the present invention, a symmetric rotation with no reaction can exist between a pair of rotating bodies that rotate forward and backward with equiangular momentum, and a new symmetrical rotation can be achieved in the mechanism of two rotating bodies that are coaxial. A new structure based on the dynamics of a new field of momentum, and a symmetric rotating mechanism that does not exert a reaction, discovered the generator of a new field that depends on a set of rotors with the simplest forward and reverse rotation.

In the present application, a magnetic element refers to an element that generates a magnetic field, and an armature refers to an element that generates an electromotive force in the armature by electromagnetic induction and extracts a generated current from a coil. It may be noted C representing the coil inertia efficiency of the armature I _C, and I _B which are indicated by the B representing the magnetic flux on the moment of inertia of Jikaiko. Assuming that the armature and the magnetic element have the same amount of momentum, the rotational angular velocities of the forward and reverse rotations of the armature that is the forward rotation rotor and the reverse rotation magnetic field by the input power are + ω _C and −ω _B , respectively. , The angular momentum of the armature is I _C · ω _C , and the angular momentum of the magnetic element is −I _B · ω _{B. In} the generator, the voltage (electromotive force) E = v · B is applied to the coil of the armature based on both angular momentum. = R · (ω _C + ω _B ) · B is generated. In this equation, v is a relative peripheral speed of the rotating body rotating as the armature with respect to the magnetic element, r is a radius value from the center of the bearing-bearing bearing rotating shaft to the outer periphery of the rotating body rotating as the armature, and v = r · (ω _C + ω _B ).

A voltage (electromotive force) is generated in the coil of the armature based on the magnetic flux B of the magnetic element and the action of relative power acting between the rotating body as the armature and the rotating body as the magnetic element, and the load and armature A current flows through the coil and a current flows through the load to generate power consumption. As the current flows, a reaction acts as an electric motor on both rotating bodies, and the reactions always exist but cancel each other out, so that electric power is generated due to the consumption of the load with no reaction and only the input action.

Except for the mechanical loss generated in the rotating mechanism from the input power, almost no electric power with no reaction can be obtained. In the present invention, a cylindrical magnetic element is provided opposite to the armature around a cylindrical armature that is fixed to a rotary shaft that is rotatably supported by the generator body and rotates with the rotary shaft, and is rotated. The shaft is rotatably supported via a bearing. In other words, the conventional generator that rotates only the armature while fixing the magnetic element generates a voltage E = v · B generated between the rotor and the magnetic element fixed to the ground. Then, the reaction equivalent to the input power of the action is canceled out, and an output power double the power E can be obtained. In the generator according to the present invention, the rotational force between the current I flowing in the forward rotating armature and the reverse rotating magnetic element is used to generate power between the forward rotating armature and the reverse rotating magnetic element. It is possible to obtain a pure generator that works only as a machine and does not generate a reaction force F as an electric motor when a current flows.

The stator and armature that make up the conventional generator and motor are installed on the ground with a stator with a large inertia ratio, and an armature with a small inertia ratio is rotated, and a rotational angular velocity that is inversely proportional to the inertia ratio is used. I have generated power from the armature. However, according to Newton's law of action and reaction, the installed stator has an angular momentum interaction reaction due to the inertia ratio of the high-speed rotating armature, and in the case of a generator, the current I flowing from the generated voltage E to the load is fixed. The force generated between the magnetic flux B generated by the child and the reaction is applied to the stator, and the reaction has been transmitted to the ground with the accompanying energy through the main body to which the stator is attached.

This applies the driving force of the engine mounted on the vehicle to the wheels, and advances the vehicle with the power of the action that generates a reaction accompanied by energy transmission that pushes the road surface to the back of the vehicle, and the rocket called advanced technology moves forward. The efficiency of the case where there is no adjacent object that the combustion explosion of the mounted mass that obtained the speed of, applied the thrust of the forward component to the forward movement of the rocket in the action of the power in all 4π direction, and then left it released Has progressed with the worst reaction. In automobiles, the earth is rigid and has an infinite mass, but it uses a reaction due to the action of finite adjacent objects where water, sand and pebbles exist in the soil under the elastic asphalt. The energy sources of generators and motors, and the power sources of automobiles have contributed to the high temperature of the earth by the reaction of power and vibration caused by fuel explosions. This is basically a non-reaction, the power of the mechanism at normal temperature, the new generator is released from the energy sum of both equal amounts of relative angular momentum between the equal amount of rotors to release the kinetic energy of the angular velocity action. Describe the technology that makes it possible to say goodbye.

The present invention will be described with reference to FIGS. 1 to 4 based on a three-phase bipolar dielectric power generator. It is obvious that the power generation device is only one example of the power generation device and can be applied to other types of power generation devices. FIG. 1 is a schematic cross-sectional view of a magnetic element and armature of a three-phase bipolar dielectric power generator according to an embodiment of the generator of the present invention. FIG. 2 is a cross-sectional view schematically showing a state in which a magnetic element and an armature rotate in opposite directions with equal angular momentum in a three-phase bipolar dielectric power generator according to an embodiment of the generator of the present invention. FIG. However, to simplify understanding, the magnetic field element is shown in a stationary position. FIG. 3 shows an electromotive force obtained in a three-phase bipolar dielectric power generator according to an embodiment of the generator of the present invention. FIG. 4 is a schematic view of a cross section taken along line IV-IV of FIG. 1 of a three-phase bipolar dielectric power generator according to one embodiment of the generator of the present invention.

The main body 1 of the generator M is installed on the ground. A cylindrical vertical hole 2 is provided at the center of the generator main body 1, and a rotary shaft 6 is disposed at the center of the vertical hole 2. The armature 3 is disposed on the rotating shaft 6, and the magnetic field element 4 made of N-pole and S-pole permanent magnets is fixed to the rotating shaft 6. The outer tracks of the armature 3 and the magnetic element 4 are concentric with the rotating shaft 6 as the center. Arranged in a shape. The armature 3 includes a frame body 3a, a coil support body 3b made of a magnetic material arranged with a phase shift of 120 ° around the frame body, and a coil 3c wound around the coil support body. In the coil 3c, electromotive forces (voltages) of U phase, V phase, and V phase are generated by electromagnetic induction, respectively, and current flows through the external resistor Z.

FIG. 2 shows the mutual rotational positional relationship between the armature 3 and the magnetic element 4. Although the armature 3 and the magnetic element 4 are rotating in the opposite directions and with an equiangular momentum, the armature 3 is shown as a fixed position in FIG. 2 for easy understanding. The mutual rotation positions of the armature 3 and the magnetic element 4 indicate the states of (a) 120 degrees of rotating magnetic flux, (b) 150 degrees of rotating magnetic flux, (c) 180 degrees of rotating magnetic flux, and (d) 210 degrees of rotating magnetic flux. As the armature 3 and the magnetic element 4 mutually rotate, the magnetic flux flows through the coil support 3b made of a magnetic material arranged with a phase shift of 120 ° around the frame body and wound around the coil support 3b. The coil 3c crosses the magnetic flux, and the three-phase electromotive force shown in FIG. 3 is generated in the coil, and a three-phase alternating current is generated when connected to the external resistor Z.

4 is a schematic diagram of a cross section taken along line IV-IV of FIG. 1 of the three-phase bipolar dielectric power generation device according to one embodiment of the generator of the present invention. The magnetic element 4 is fixed to the rotating shaft 6. In the armature 3, the left columnar end plate E is rotatably held on the rotary shaft 6 via a bearing bearing 7 a. A concave portion is provided in the central portion of the right cylindrical end plate E, and the right end portion of the rotating shaft 6 is rotatably held. A rotation shaft 11 extending in the right direction coaxial with the rotation shaft 6 is attached to the central portion of the right cylindrical end plate E, and the rotation shaft 11 is inserted into a hole provided in the generator body 1 through a bearing bearing 11a. It is held rotatably.

The U-phase, V-phase, and W-phase wires of the armature are respectively connected to slip rings 12 fixed to the shaft 11 so that current can flow through the external resistor Z.

In FIG. 4, the external power P is divided into a first external power and a second external power by the external power split device 10 via the control device C, and the first external power is the first external power transmission device M1. Is transmitted to the rotating shaft 6 to which the magnetic field element 4 is fixed, and rotates the magnetic field element 4 in one direction. The second external power is transmitted to the armature 3 via the second external power transmission device M2 to rotate the armature 3 with the equiangular momentum in the direction opposite to the rotation direction of the magnetic element 4. In FIG. 4, 8 is a gear fixed to the end of the rotating shaft, and 9 is a gear fixed to the end surface of the cylindrical body of the armature 3.

The external power split device 10 splits the external power P into the first external power unit P1 and the second external power unit P2 so that the angular momentum of the armature and the angular momentum of the magnetic element are equal. The control device C turns on / off the dividing device 10 with respect to the external power P, changes the ratio of the first external power portion P1 and the second external power portion P2, and controls the introduction of the external power P. To do.

As the input power P, falling water, high-pressure steam, or wind power can be used, and the amount of falling water is divided into two so that the angular momentum of the armature and the angular momentum of the magnetic element are equalized by the external power split device 10. An armature composed of a coil through a first external power transmission mechanism M1, or splitting high-pressure steam into two pipes, or splitting wind power into two using two equal-area propellers 3 is rotated together with the rotating shaft 6, and the magnetic element 4 is rotated around the same rotating shaft 6 through the bearing bearing 7a in an antisymmetric manner by the second external power transmission mechanism M2. When the coil of the armature 3 has a relative velocity v at which the coil traverses the magnetic flux B flowing from N to S of the magnetic poles of the magnetic element 4, a voltage E = v · B is generated in the coil and becomes the output of the generator.

In power generation by wind power or ocean current, two propellers are used, one propeller rotates the armature in the forward direction, the other propeller rotates the magnetic element in the reverse direction, and the angular momentum of the armature is equal to the angular momentum of the magnetic element. Electric power is generated by forward and reverse rotation.

FIG. 5 is a schematic diagram of a three-phase synchronous power generator according to another embodiment of the generator of the present invention. 21 is a generator body, 22 is a circular vertical hole of the power generation body, 23 is an armature, 24 is a magnetic element, 26 is a rotating shaft, and the magnetic element 24 is made of a permanent magnet. The magnetic field element 24 is rotated together with the rotation shaft, and the armature 23 and the magnetic field element 24 are rotated with equal angular momentum in opposite directions. The magnetic element 24 is composed of a permanent magnet, but may be composed of an electromagnet. Further, a-a ′, b-b ′, and c-c ′ are electrical windings whose phases are shifted by 120 °, thereby obtaining a three-phase voltage and a three-phase current. Other configurations are the same as or similar to those of the first embodiment shown in FIGS.

As described above, in the generator of the present invention, the energy of the reaction force acting on the magnetic element due to the reaction generated between the armature and the magnetic element due to the current flowing through the load is transferred to the ground via the generator body installed on the ground. It can be prevented from flowing out.

Claims

It consists of a magnetic element that creates a magnetic field and an armature that extracts the generated current. The armature winding coil traverses the magnetic field formed by the magnetic element, so that the electromotive force is generated in the armature coil according to Fleming's right-hand rule. In the shaft rotation type generator to be generated,
The generator has a configuration in which a magnetic element and an armature are rotated in reverse directions with equal angular momentum,
The external power is divided into a first external power unit and a second external power unit so that the angular momentum of the armature and the angular momentum of the magnetic field element are equal,
Transmitting the first external power to the armature and rotating the armature in the positive direction;
By transmitting the second external power to the magnetic element and rotating the magnetic element in a direction opposite to the normal direction of rotation of the armature,
A power generator in which an armature and a magnetic element are rotated with equal rotational angular momentum in opposite directions, and a winding coil of the armature traverses a magnetic field formed by the magnetic element to generate an electromotive force.
Furthermore, the first external power transmission device that transmits the first external power to the armature and rotates the armature in the positive direction, and the second external power is transmitted to the magnetic element and transmits the magnetic element in the positive direction of the armature. The engine according to claim 1, further comprising a second external power transmission device that rotates in a direction opposite to the rotation direction.
Furthermore, it has an external electric power split device which divides | segments external electric power into a 1st external power part and a 2nd external power part so that the angular momentum of an armature and the angular momentum of a magnetic element may become equal. Generator.
A rotating shaft rotatably supported by the generator body, the magnetic element is fixed to the rotating shaft and rotates together with the rotating shaft, and the armature is disposed opposite to a cylindrical shape drawn by the magnetic element. The generator according to any one of claims 1 to 3.
The generator according to any one of claims 1 to 4, wherein the magnetic field element is formed of a permanent magnet.
It consists of a magnetic element that creates a magnetic field and an armature that extracts the generated current. The armature winding coil traverses the magnetic field formed by the magnetic element, so that the electromotive force is generated in the armature coil according to Fleming's right-hand rule. In the power generation method to be generated, the configuration is such that the magnetic element and the armature are rotated in reverse directions with equal angular momentum,
The external power is divided into a first external power unit and a second external power unit so that the angular momentum of the armature and the angular momentum of the magnetic field element are equal,
Transmitting the first external power to the armature and rotating the armature in the positive direction;
By transmitting the second external power to the magnetic element and rotating the magnetic element in a direction opposite to the normal direction of rotation of the armature,
When the armature and the magnetic element are rotated in the opposite directions with the same rotational angular momentum, and the armature winding coil crosses the magnetic field formed by the magnetic element, it occurs in the armature coil according to Fleming's right-hand rule. A power generation method characterized by generating electric power.