JP2014220978A - Single magnetic pole armature couple electric motor - Google Patents

Abstract

[PROBLEMS] To improve the phenomenon in which half of a generator loses heat due to heat generation, and to investigate the cause of the energy that causes half of the energy to escape due to heat loss when the drive motor is driven. Can be used effectively. SOLUTION: The natural law of the present invention is that when a substance is divided equally, the original space is preserved as energy by the amount of splitting and becoming smaller. Follow the principle of the cosmic explosion. The concrete solution means of the present invention relates to a method means for dividing the electricity of plus or minus one phase or more generated by a generator using wiring, and doubling and extracting the electromagnetic force energy by the divided amount and effectively utilizing it. If this split wiring method is used, the generator also has less heat loss and power generation drag, and high-speed rotation becomes easier. With this room temperature superconducting armature, the generator can be subdivided into n numbers with the conventional structural scale, and the power generation drive capability of the motor can be increased several times. [Selection] Figure 2

Description

Detailed Description of the Invention

motor

In the conventional power generation method, two rotors and a stator are integrated into a NS bipolar magnet, and the other is an armature formed of a good conductor coil wound around magnetized iron. A power generation method and a power generator for causing an armature coil to alternately generate power by movement. The drive motor applies an alternating current to the armature that is an integral part of the two-body motor generator, and applies a driving force to the N and S dipole magnets of the other body by the generated magnetic force. As a result, the armature secondarily becomes a magnet by the electricity generated in the coil. This causes a power generation drag in the generator, and causes a decrease in torque as well as rotation in the drive motor. Further, when the currents of the negative and positive phases generated in the magnetic poles N and S are short-circuited and flow in the armature coil, heat is generated and heat loss occurs. Due to these losses, most of the input energy for power generation and drive is lost as losses. The conventional countermeasures against generator power generation drag are to interpret the power generation drag as remanent magnetism during power generation, and to provide an auxiliary armature coil that has another drive armature between the armatures to counteract the power generation drag. Although equipped, power generation promotion effect is not expected so much. Since the large generator motor coil is burned due to heat loss, heat loss and the like prevent the coil from being burned by heat by making a good conductor wire into a pipe shape and passing cooling water through it. The cause of heat generation, which is the fundamental source of heat generation energy loss, has not been investigated and countermeasures have not been taken.

The armature coils of conventional generators and drive motors are directly connected in a closed circuit with one end being an input / output terminal and the other end being a star circuit or a delta circuit. For this reason, different phases in the closed circuit are short-circuited, and most of the input energy becomes heat loss. Moreover, the magnetism by the generated magnetic flux becomes the first drag.

In addition, when forming a plurality of poles using a phase different from each other as a unit pole, the armatures having the same phase are connected in series with the same magnetic pole direction and winding direction. The magnetic flux generated by this power generation is the cause of the second drag and the generation of residual magnetism. It also causes heat generation.

Problems to be solved by the invention

When electric power is generated and driven by a conventional star circuit or delta circuit electric motor, at least half of the heat is generated, resulting in heat loss. Also, power is wasted due to the closed circuit of the multiphase circuit. In addition, the generated magnetic flux becomes a power generation drag and the driving force is reduced. The first problem to be solved by the present invention is to clarify the cause of the heat loss and to eliminate the heat loss.

The second problem to be solved by the present invention is to clarify the cause of the magnetic force induced and generated between the polyphases and to eliminate the power generation drag and the drive drag.

The third problem to be solved by the present invention is a unit pole armature coil having a multi-phase different unit pole when generating and driving with a two-body motor comprising a rotor and a stator. A series connection is made between the same poles of the armature. Due to the magnetic force generated by secondary induction by this, the generator becomes a drag that rotates the generator, and the drive motor becomes a drag that reduces the rotational torque. It is an object to eliminate the drag due to the residual magnetism generated during the electric power generation of the electric motor and the generator.

As a fourth problem, a method for increasing or decreasing voltage or current by connecting in series or in parallel without causing work between a plurality of single magnetic poles has not yet been determined. It is a problem to solve this

Means to solve the problem

The means to solve the heat loss, which is the first section, is to clarify the cause of half of the heat generation and escape when the power consumption is 1, and then the device to solve this is an armature coil winding structure, It is to provide as a wiring method and apparatus. As a means to eliminate energy loss, power generation drag, and heat loss due to interaction between different phases, which is the second issue, which is the second issue, the single-pole armature connection is closed as a star circuit or delta circuit Is a means of releasing the electrode and creating a new reversed-phase electrode. The third issue, the means to eliminate the heat loss between the same phases and the power generation effect, is to eliminate the drag generated during power generation that obstructs the method of extracting the electromagnetic force that is the energy close to nuclear power originally possessed by the substance. For this reason, the single magnetic electrode elements having the same phase are connected in series, and the heat generated and consumed in the connection is released to form a new electrode. In addition, the magnetic drag due to the magnetic flux generated by the series connection is eliminated, thereby reducing the energy loss due to the drag consuming the input. Reduce energy loss due to heat loss. The means for solving the fourth problem is to connect the single-phase armatures in the same phase in series or in parallel, connect the rectifier to the single-pole electrodes, rectify, and then connect in series or in parallel. Is the solution. For parallel connection, a commutator is not required, and the effect does not change even if connected.

The first embodiment of the invention, which is the disclosure of the present invention, is to clarify the cause of heat loss in which half of the heat is generated and escapes when power is consumed. The reason is that electricity in different phases in a two-phase electrical wiring with different phases of AC power generation is short-circuited as a closed circuit, and one-phase electric machinery wastes heat. This heat generation waste is said to be half of the thermodynamics that escapes with heat, but it is not a law but just a structural problem.
In the present invention, in consideration of the phenomenon of waste of short circuit heat due to this closed circuit, the closed circuit that performs input and output between two phases is released, and one phase and the other phase are respectively set as separate input power supplies, and the power consumption of two lines. Four-phase electrical wiring including ± two-phase reverse phase with the ground wire having the electrical outlet of each phase as the ground. This can be called an N, S magnetic single pole armature pair. As a result, the NS magnetic dipole armature existing in the conventional generator and the other phase can only use half of the generated power due to the short circuit heating waste, so that the power can be changed to effective consumption. I can do it. In the second embodiment, which is a disclosure of the present invention, since the connection of the armatures having different phases is connected by a star circuit or a delta circuit, they interact with each other in different correlations, and two-phase electricity is one-phase. The magnetism generated by the flow of magnetic flux due to the induced electromotive force, which wastes heat and is the basis of the power generation drag, becomes the source of the power generation drag. An implementation method to solve this is to eliminate the first drag by eliminating the closed circuit and providing a release circuit. More specifically, when NS magnetic single-pole armature pairs are used and the electric power generated by each single-magnetic armature is consumed in the single-magnetic armature, the magnetic flux after induction electromotive force is generated in the armature-excited magnet iron. It does not occur, so no magnetism. By using this, it was possible to implement a generator with less power generation drag, and to obtain more effective energy than before. In order to increase the voltage and current with less heat loss, to connect the single magnetic armature connection in series or in parallel, connect the commutator to the electrode end of the single magnetic armature, rectify, and then in parallel or in series. By connecting, we were able to solve and implement the problem of preventing heat loss. Implementation was performed by connecting a full-wave commutator. Not shown.

In the first embodiment, first, the cause of heat generation will be described as a two-phase interaction of AC power generation in FIG. Figure 1 is a graph showing the relationship between the voltage and phase of the power supply for three-phase and two-phase interaction. The vertical direction is the voltage, and the horizontal direction is the phase indicating the relative position of the power generation magnet and coil. Two-phase electric powers with different phases have a voltage plus or minus each other, and one phase disappears, and a new one phase is formed at an intermediate phase position between the two phases. The power for one phase that disappears generates heat.

A method for generating electricity without the cause of the heat generation will be described with reference to FIG. FIG. 2 is a schematic diagram. When the magnetic pole NS is wound around a gap between the one end and the other end of the armature wound as a good conductor wire coil 2 with an insulating coating on an exciting magnetic iron 1 formed of a laminated plywood of an insulating coating, Currents + U and -U are generated at one end A and the other end B of the child coil. An electric appliance is connected to each of the two phases, and the other end of the electric appliance is connected as a ground for consumption. In the middle of this coil, the generated reverse phase of the electrical ± U phase is short-circuited to generate heat. In order to prevent this and use the power effectively, the middle of the coil wire is cut to form new electrodes C and D, and new electric phases, reverse + U phase and reverse -U, are formed. An electric appliance is connected to each of these new electrodes, and the end of each electric circuit is grounded.

The second embodiment will be described with reference to FIG. 3 as an embodiment of power generation drag and drive drag. The figure is a schematic diagram. This will be described as a three-phase AC generator. Excited magnetic iron made of insulating steel plywood is formed on the donut-shaped disk 1, and the pillars projecting inside are phase-numbered. Each conductor is wrapped with a good conductor wire, Forming. One end of this coil forms an output electrode UVW, and the conventional motor forms a closed circuit in which the other end of each coil is short-circuited as a star circuit or a delta circuit. The present invention is released without forming each other end as a short circuit closure circuit, forming a new electrode as reversed phase -U-V-W. An electric appliance is connected to each of the opposite phases, and the other end of the electric appliance is connected to the ground.

A third embodiment will be described with reference to FIG. The figure is a schematic diagram. A good conductor wire 2 with an insulating coating is wound around at least one column of the magnetized iron 1 composed of a plywood of an iron coating with an insulating coating to form an armature. 3 is a view of a motor in which N and S magnetic poles alternate with a gap at the end of a column of exciting magnetic iron 1; FIG. Although the figures only depict the same phase, the implementation may be in any number of phases. The connection of a conventional motor having the same phase and multiple poles is continuously connected in series, and both ends A and B of the wire serve as phase electrodes. The present invention is a motor in which the electrical wiring between the magnetic pole columns is cut, new electrodes C and D are newly provided, and ± electrodes corresponding to the number of poles are newly provided.

Effect of the invention

The first effect of the invention will be described with reference to FIGS. FIG. 1 illustrates a two-phase AC power source. The UV two-phase phase is distributed by a third. When work is performed between the two phases, the two-phase short-circuit interaction is indicated by reversed phase after the plus and minus are added. It can be seen that the UV two-phase waveform is a one-phase -W-phase waveform, and one phase is wasted. Next, using FIG. 2, this two-phase input is cut at the short-circuited portion, and each circuit is made independent and two lines are provided. If the output is grounded, the two-input power source is used as a separate power source so that it is not wasted. I was able to use electricity.

The second effect of the invention will be described with reference to FIG. As clarified by the effect of the above invention, the connection between the single-pole armatures UVW with different magnetic poles is opened without forming a short-circuit closed circuit like a conventional star circuit or delta circuit, and a new reversed-phase electrode is opened. When electric power is consumed by an electric appliance between a new electrode and the ground, secondary magnetic flux and magnetic force induced by conventional power generation, energy called residual magnetism, which is a power generation drag, is a single pole electric machine in the present invention. Electric power is consumed in the child, and magnetic flux does not flow between different magnetic poles. As a result, no power generation drag due to residual magnetism occurs.

The third effect of the invention is performed using FIG. FIG. 4 is a schematic diagram. Conventionally, single-pole armatures, which have the same magnetic polarity as the armature winding, are connected in parallel. As a result, the secondary magnetic flux generated by the electricity generated in the armature of the same pole flows back to the single-pole armature with different magnetic poles. As a result, a secondary magnetic flux is generated and becomes a source of power generation drag. .
In the present invention, the connection between the single magnetic poles is released to form two electrodes, and the respective electrodes and electric appliances are connected to one of the good conductive wires, and the other is connected to the ground. As a result, the electricity generated in each single-pole armature is digested in the single-pole armature and no secondary magnetic flux is generated, thereby eliminating the generation of power generation drag and realizing a motor without power generation drag. . As a first effect, the generated electricity flows in the opposite phase through the electric appliance, so the voltage is doubled. The second effect is that when the double-pole armature is converted to a single-pole armature, the power generation drag is reduced. If the input energy is the same, the product of rotation and torque is the same, so the rotation increases by the number of poles. The voltage is doubled by the number of poles. Since the total amount of motor with the same current does not change, the generator energy is doubled by the number of poles. It can be said that a generator that can be called a room-temperature superconducting motor without magnetoresistance due to induced electromotive force is realized.

1) Exciting magnetic iron 2) Coil N Magnetic pole S Magnetic poles A, B, C, D Armature terminals U, V, W AC electrical phase diagram 1 shows two-phase mutual among three-phase AC U, V, W In this graph, the vertical direction is a plus or minus voltage, and the horizontal direction is a graph showing the frequency and the phase shift between the coil and the magnet. Due to the interaction between the U and V phases, one phase of the -W phase and the reverse phase of the W phase is synthesized, and the other one phase is wasted as heat loss.

FIG. 2 is a schematic diagram showing a solenoid coil armature. Reference numeral 1 denotes an excited magnetic iron composed of a plywood plate having an insulating film. 2 is a good conductor coil with an insulating film wound around an exciting magnetic iron pole.

FIG. 3 is a schematic diagram of an armature of a motor. Reference numeral 1 shown by a dotted line is an excited magnetic iron composed of a plywood board having an insulating film.

FIG. 4 is a schematic diagram of the motor armature 1 and the NS magnet. The armature is obtained by cutting the parallel circuit of the single-pole armature and increasing the number of single-pole armature electrode terminals by the number of poles.

Claims (11)

A magnetizing iron formed of a plywood sheet of an electrically insulating coating is wound with a good electrical conductor wire coated with an electrical insulation coating as a coil to form a solenoid coil having one end and the other end of the good electrical conductor wire as electrodes. Magnets are placed at both ends of the magnetizing magnet iron of the solenoid coil with a gap between them, and the double magnetic poles N and S are alternately moved, and a magnetic flux generated by the alternating magnetic field is caused to flow alternately in the solenoid coil exciting magnet iron. Thus, in the armature that generates an alternating current in the solenoid coil, the middle of the coil is cut to form two new electrodes. A single-pole armature pair formed by a pair of single-pole armature coils with N and S magnetic poles for a double-pole armature whose armature coils straddle the double-pole N and S. And a single-pole armature pair circuit for connecting the coils of the at least one single-pole armature pair in parallel. An electric motor comprising at least one single-pole armature pair according to claim 1. One end of at least two U and V two-phase armature coil wires spanning the NS two magnetic poles of the generator are terminals of U and V electrodes, and the other two poles are connected in the middle of the two armatures. The single-pole armature pair according to claim 1, wherein the closed-circuit is opened and the plus-minus four-phase and electrode are doubled, and one end of the pair of single-pole armature electrodes has a closed-circuit as a double-pole armature. A generator and an electric motor composed of a single-pole electric motor pair that is a release circuit that is not formed. In the above-described single-pole armature generator and the generator armature that is an open circuit, the single-pole armatures of the phases with different phases of the plus and minus electrodes are combined to form a multi-phase unit-pole armature. In a generator formed of a plurality of unit pole armatures, at least one single magnetic pole armature in which at least one single magnetic pole armature connection of the same magnetic pole is connected in series as a closed circuit, Cut and release in the middle between the children to make a new electrode. A single-pole armature generator and a motor in which the series single-pole connection closed circuit composed of the unit-pole armature groups is an open circuit. A single-pole armature pair comprising a rectifier circuit that rectifies alternating current into direct current by connecting ends of at least a pair of electrodes of at least a pair of single-pole armatures according to claim 1 to a commutator. A generator comprising a rectifier circuit for the single-pole armature pair and comprising at least one single-pole armature pair. An electric motor and a generator formed of a rotor and a stator, wherein a phase of a magnet of a generator whose armature is the single-pole armature pair is shifted in phase. The single-pole armature pair, wherein each single-pole armature includes at least a secondary coil. A double-winding single-pole armature pair electric motor and a generator, each composed of the above-described double-winding single-pole armature pair. A drive generator motor having at least two of the above-described double-winding single-pole armature and an electric motor, wherein a part of one power generation is the other drive power source. A multi-stage drive generator in which at least two of the above-described single-winding single-pole armatures and electric motors are linked and each other's generated electricity is used as a drive power source.