JP2023008729A - Generator capable of continuously supplying power while rotating by itself without external auxiliary force of fire power, water power, atomic power, or the like - Google Patents

Abstract

To provide a generator for enabling self-driven rotation by providing strong drive force similar to a motor inside and using power for driving the drive force as it is, which is generated by itself.SOLUTION: A plurality of stator iron core poles, where even-numbered poles in this invention, are provided on the outside periphery of a generator like a general motor, and a coil conductor is wound around the salient pole of each iron core stator pole as shown in the figure. Also, a stator pole made only of a coil wound around each iron core stator pole with almost the same radius from a rotational axis of the center so as to draw a loop is installed at a position a little closer to a generator center part from each iron core stator pole tip surface. The number of conductors at the position is twice as many as the winding number of each coil because two coils installed so as to respectively surround adjacent iron core stator poles overlap each other in the stator poles only in the coil.SELECTED DRAWING: Figure 1

Description

The present invention is a generator, and when the rotor magnetic poles pass by the stator coils installed around the rotor, the coils generate an electromotive force and cause current to flow, which is in accordance with Faraday's law of electromagnetic induction. As a result, magnetic force resistance that prevents the rotation of the rotor is normally generated around the coil, and this works to stop the rotation of the rotor. The current situation is that the rotor is forced to rotate continuously with the help of the rotor. However, in the present invention, a plurality of rotor poles are provided, and the same number of stator coils are arranged around the rotor poles while winding the coils in a special manner, thereby resisting the magnetic force generated around the adjacent coils. Instead, it is generated as a force in a direction that helps the rotor rotate, thereby suppressing the overall magnetic force resistance to less than half and making it possible to rotate the rotor more easily. The same number of stator coil poles with iron cores as the rotor poles and stator coil poles are installed on the outer side, and the same current as that generated by the stator poles of only the inner coils is passed through all those coils and the number of the iron cored coils is applied. The winding method is such that the magnetic force is generated to always help the rotation of the rotor magnetic poles, and the rotor magnetic poles are repelled and attracted. To continue the rotation of a rotor without requiring an auxiliary force such as thermal power from the outside by enabling the generation of a rotation assisting force far exceeding the magnetic force resistance around the coil stator. Of course, it goes without saying that it is possible to continue to generate electricity during that time and to continue to supply power to the outside of the generator.

Rotating the magnet in the coil generates an electric current due to the change in magnetism. A generator is a machine that converts mechanical energy into electrical energy using the law of electromagnetic induction, and a motor is a machine that converts electrical energy into mechanical energy, but the present invention has both.

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When the rotor magnet located in the center of the generator rotates, a current is generated in the stator coil placed around it according to Faraday's right-hand rule, which itself is the purpose of the generator itself, so that's it. This is good, but the problem is that the current generates a magnetic field (magnetic field lines) around the coil, and the magnetic field lines collide with the magnetic field lines of the rotor magnet poles (north pole or south pole), and as a result, the rotation of the rotor magnet is slowed down. It causes the so-called magnetic resistance to act as an action to stop the movement. However, in order to continue power generation, it is still necessary to operate without stopping the rotation of the rotor magnetic poles. The current problem is that we have to give a powerful energy such as.

The magnetic field (lines of magnetic force) derived from the current generated in the stator coil, which generally acts in the form of magnetic resistance, is physically impossible to eliminate. However, it is possible to resist the magnetic resistance and give the rotor a strong repulsive and attractive force similar to that of a motor. be possible. As a result, the rotor pole magnets can rotate on their own, and power can be generated without any assistance from a large amount of external energy.

In general, a motor has coils wound around the iron core poles of the stator, and the stator poles are excited by passing current through the coils from the outside. The rotor is driven to rotate while repelling or attracting the rotor.

The present invention is a generator that has a strong driving force similar to that of the motor, and that uses the electric power generated by itself to drive the generator as it is, thereby enabling self-driven rotation.

The structure will be explained using FIG. The figure depicts the rotor of the generator as standing vertically upwards and rotating to the right when viewed from above. In the case of rotating to the left, the positional relationship in the figure should be reversed left to right. A plurality of stator iron core poles are provided around the outside of the generator like a general motor, but in the present invention, an even number of poles are provided. The coil conductor is wound on the . In addition, from the surface of each iron core stator pole tip, at a position slightly closer to the center of the generator, from the coil wound around the iron core stator pole with approximately the same radius from the center rotation axis, each loop is drawn. The stator poles are installed. As shown in the figure, the stator poles of the coil only have two coils installed so as to surround the adjacent iron core stator poles so that they overlap each other in the vertical longitudinal direction. Note that the number of conductors in is twice the number of turns in each coil. The method unique to the present invention is to provide two types of stator poles, the iron core stator poles and the stator poles consisting only of coils, and to wind the conductors forming the respective coils.

How to wind the conductor will be explained using Fig. 1. First, in order to form a coil A as a stator consisting only of coils, a single conductor wire is drawn from the center of the generator so as to surround the tip surface of one iron core stator pole as shown in the figure. Look and wind only the number of turns required for "right winding". After that, the end of the conductor wire is subsequently brought to the salient pole of the iron core stator immediately in front of the eye, and the coil B is formed by winding the necessary number of "left turns" around it as also shown in the figure. The number of turns of coil A and coil B does not necessarily have to be the same. As for the number of turns of coil A, electricity is generated in the coil when the rotor poles pass in front of the vertical longitudinal section of the stator, which has no iron core, and the electromotive force generated at that time is is determined in proportion to the number of turns of the coil. On the other hand, regarding the number of turns of the coil wound around the iron core stator salient poles, the same current as that generated in the coil without the iron core is made to flow through the coil, so the strength is proportional to the number of turns. The iron core is excited and magnetized, and the strength proportional to the magnitude of the magnetized magnetic force causes the rotor magnetic poles to rotate while repelling or attracting them. Determine the number of turns with that fact in mind.

Here, it is important to note that the conductor should be wound at a position slightly recessed from the tip of the pole as to the position where the conductor is wound around the iron core stator pole. The reason for this is to prevent the magnetic flux of the rotor magnets from crossing very close to the coils wound on the stator poles as the rotor pole magnets pass in front of the stator poles. If the magnetic flux crosses the coil very close to it, a current will be generated in that coil. Since the magnetic flux weakens as the distance increases, if the coils are separated by about 3 cm, the current generated in the coils will be considerably weaker and the effect will be smaller, but the distance should be determined appropriately separately. If the coil is wound too deep in the iron core stator salient pole, the magnetic force at the tip of the stator pole may decrease, but that is not a big concern. In any case, the winding position of the coil is determined so as not to allow the coil to generate current as much as possible. 3 centimeters from the tip of the stator pole serves as a guideline.

For the same reason, for the stator poles consisting of only coils without an iron core, the rotor magnets pass in front of the coil bundles placed in the vertical direction to generate electricity, so the coils are the rotor magnets. It is better to bring the magnet as close to the magnetic pole as possible because the generated power can be increased.

After winding the required number of coils B around the iron core stator salient poles shown in FIG. , to surround the surface of the tip of the iron core stator pole on the right side of the coil A as viewed from the center of the generator, but this time, wind it "left-handed" to form a coil C consisting of only the coil. In that case, the number of turns of the coil C does not necessarily have to be the same as the number of turns of the coil A on the left. It can be said that it is better to make the number of turns the same.

Subsequently, the same conductor is wound around the salient stator pole in front of the coil C at a slightly recessed position, but this time in a "right-handed" manner to form an iron core stator pole coil D. .

Similarly, using the same conductor wire, continue to wind the coil E as a stator with only coils "right-handed", then wind the iron core stator salient pole in front of it "left-handed", and so on. Similarly, each pole coil of the stator is formed. In this case, it should be noted that the same type of stator poles should be wound in the opposite direction to each other.

In this way, the coils are wound to form two types of stator poles, each iron core stator pole and a coil bundle only stator pole without an iron core. Alternatively, it may be divided into two systems, three systems, or at least the same number of systems as the even number of iron core stator poles, and a separate conducting wire may be wound for each of the divided systems. However, if the conducting wire is divided into two lines, for example, the output voltage will be reduced by about half, but since the conducting wire will be half the length, the electrical resistance value will also be reduced to about half, so the output current will not be reduced by half. In addition, when the coils are divided into a plurality of systems, how to synthesize the output power from the generator outside the generator is a separate problem from the present invention.

As mentioned above, each iron core stator pole and the rotor pole magnet are rotated in the coil formed by winding the coil only without the iron core so as to surround the tip surface of each iron core stator pole as planned. , in which case, as shown in FIG. 1, the N and S poles of each rotor pole magnet are alternately arranged, and the spacing between the respective iron core stator poles, or the vertical longitudinal direction without an iron core. Arrange them side by side so that the spacing between the stator poles of the coils alone is the same.

Rotating the rotor in such a structure results in the generation of current in the coils each time the magnetic flux of each pole of the rotor traverses the vertical longitudinal coil bundle without an iron core. As will be explained again with reference to FIG. 1, for example, when the north pole of one of the rotor magnets passes in front of the wire bundle in which the coils A and C without iron cores overlap in their vertical longitudinal direction, a current is applied to the coil, It flows in the direction of the arrow shown in the figure, that is, downward. The S pole of the rotor magnet on the right side is the vertical coil bundle in front of it, which is a stack of coils C and E in the vertical direction. , that is, the current flows upward. Therefore, in both cases, the current flows in the same direction through the same conductor. By doing so, the coils are wound in the order described above.

Thus, when all the rotor pole magnets traverse their respective coreless vertical longitudinal coil bundles in unison, corresponding electric power is generated in the coils. A magnetic field is generated around the coil bundle, and the magnetic lines of force act in a direction to prevent the rotation of the rotor pole magnets all at once, resulting in a large blocking force as a whole. This is the so-called magnetic resistance. However, as can be seen from FIG. 1, the iron core stator poles on both sides of each vertical coil bundle act as electromagnets. When it is rotating, the left stator pole generates a repulsive force and pushes it in the direction to help the right rotation, and at the same time, the right stator pole in front of the rotation obtains an attractive force, which also helps the rotation. I know that I am empowered. The forces from these iron core stator pole magnets are much stronger than the magnetic forces (magnetic drag) that develop around the vertically aligned coreless coil bundles between the two. The magnetic force becomes weaker as the distance increases, and the coil bundle without the iron core is the closest from each rotor magnetic pole, and the distance from the iron core stator magnetic poles on both sides is farther, but the distance is increased. Even if you take this into account, the force that the rotor magnetic poles receive is far superior to the magnetic force resistance generated by the coils in front of it. As in the case, you can continue to rotate until it is powerful.

As the next step, as soon as each rotor pole passes the vertical longitudinal coil bundle without an iron core in front of it and leaves, the current generated in the coil suddenly decreases. At the same time, the magnetic force of the electromagnets of the iron core stator poles on both sides also drops sharply. FIG. 2 shows it. On the other hand, the rotor pole magnets, which may be permanent magnets or electromagnets, still retain their magnetic force so that as the rotor pole magnet approaches the front iron core stator pole, the stator pole is a magnetic metal, it will be magnetized. At the time of magnetization, the rotor magnetic pole and the opposite magnetic pole are always magnetized, so the attractive force is maintained as it is, and each rotor pole can be attracted to the front stator pole and continue rotation even if the current generation of the coil is stopped. Of course, if the magnetic flux from the rotor magnetic poles still reaches the left rear coil bundle stator that does not have an iron core, the same current flow will be generated as it is, so the rotor poles will still exert a repulsive force proportional to the magnitude of the current. From the left rear and from the right front, it can continue to rotate by receiving the suction force as it is. However, if you proceed as it is, when the rotor magnetic pole comes to the position where it faces the tip of the iron core stator pole magnetized in the opposite magnetic pole, the attractive force becomes the strongest at that point. The rotation will stop. Or, it is certain that the inertia due to the momentum of the rotor acts as a force to prevent the rotation even if it does not stop. It is commonly called cogging torque in the case of motors.

However, it is also one of the features of the present invention that the rotation is continued without stopping. As shown in FIG. 3, when the rotor poles are slightly before the position where the rotor poles face the iron core stator poles, the magnetic flux from the rotor poles is transferred to the iron core installed next to the stator poles. It begins to traverse the coreless vertical longitudinal stator coil bundle. Then, as can be seen from FIG. 3, the magnetic poles of the iron core stator poles that the rotor poles are now facing begin to reverse. With this in mind, the winding method of the coils and the position of installing the stator with only the coils in the vertical direction are taken into account. At the same time, the coil bundle stator emits magnetic force lines in the form of magnetic force resistance in a direction that prevents the rotation of the rotor. Since the force still prevails, the rotor overcomes the magnetic resistance from the coil bundle and rotates forward as it is. In addition, of course, at the same timing, the magnetic poles of the iron core stator on the front side are reversed to the magnetic poles opposite to the magnetic poles of the rotor. As mentioned above, although it is a generator, it is designed so that the central rotor magnetic poles are repelled or attracted in exactly the same timing as the respective stator magnetic poles rotate, just like a motor. Without stopping, you can continue powerful rotation just by using the current generated by the generator itself.

Here, I will briefly mention the fact that it is possible to obtain more output energy than the input energy in the generator. However, the general public thinks of a generator as a closed system, and when an energy amount of 100, for example, is input from the outside, magnetic force resistance, friction, heat, etc. are generated in the system, so those negative energies are generated. Because of this, the output energy from the generator never exceeds 100 of the input energy amount, and it is according to the law of conservation of energy or the first law of thermodynamics. The idea leaves out a fundamentally important point, and no one seems to notice it. First, in the "system" of the generator, when an external energy of 100 is input to rotate the magnets of the rotor poles, the rotor receives that energy and rotates at a certain speed. It follows the law of conservation of energy, and that's fine. However, most of the considerations from then on are missing. Electricity is of course produced in the coils as the rotor poles rotate at their acquired speed and the magnetic flux of the magnets traverses in front of the stator pole coils. This is the electrical energy output from the generator, and its magnitude depends on three factors: the number of turns of the coil and the strength of the magnetic force of the rotor pole magnet (including the magnetic flux and the distance to the coil). It can be increased in proportion to the three elements of the rotational speed. This is a known fact. In other words, even if the input energy of 100 is put into the closed system of the generator, the output energy can be increased and increased depending on these three factors. The initial amount of input energy of 100 contributes to the amount of output electrical energy in terms of increasing the rotational speed of the rotor, but it is only one of three factors. Depending on two other factors, the output energy can be increased by 200, 300 or more. However, as a counterargument at this time, when the output electric energy increases proportionally, the magnetic resistance generated around the coil increases, so the rotation speed of the rotor slows down, and in the end, the output electric energy is the amount of input energy It may be said that it never exceeds 100 of . However, it is possible to eliminate at least a portion of the magnetic drag simply by making the tips of the rotor pole magnets "streamlined," as stated in the granted patent, and also by experiments. If so, it is something that anyone can easily understand immediately. As we all know, the magnetic lines of force generated around the coil have a directivity, and the strongest repulsion occurs when the magnetic lines of force coming out from the rotor magnet face each other parallel to that direction. It is also a basic knowledge of magnets to say that they will receive force. However, it is not known that the repulsive force and the attractive force become zero when the magnetic lines of force are perpendicular to each other. A simple experiment will show this as soon as possible. In short, if the magnet surface of the rotor is streamlined and the incident angle of the lines of magnetic force from the coil is set to, for example, 45 degrees on average, the magnetic force resistance can be reduced by about 30%. According to the law of conservation of energy, if the magnetic resistance is reduced by 30%, the rotation speed of the rotor is increased by about 30%, and as a result, the output energy is also increased by that amount. The magnetic force generated around the coil is certainly proportional to the electrical energy generated in the coil, but the "resistance" called magnetic force resistance can be reduced with a little ingenuity. Other frictional resistances can be similarly reduced, and even children know how to do it. Furthermore, if, as in the present invention, solenoid coils with iron cores inserted in the stator poles are arranged on both sides of the generating coil and the potential energy of the magnetic force emitted from them is used as in a motor, the magnetic field generated around the coils It is also possible to give the rotor a rotational force greater than the magnetic resistance. It is a known fact that motors do. It is exactly the same as letting an object fall in the potential energy (or potential energy) of gravity and giving it acceleration. The rotor gains acceleration in the magnetic potential energy field. This is also simple physics. Needless to say, the higher the rotational speed of the rotor, the greater the output energy. From the above, it should be understood that an energy output of over 100 can be obtained even if an amount of energy of 100 is initially input to the generator. Then, if you ask whether this is against the law of conservation of energy, it is not at all against. This is because the generator already has the amount of potential energy, which is the number of turns of the magnet and the coil, from the beginning. As for the number of turns of the coil, the number of electrons increases in proportion to it, and the output voltage is increased by the number proportional to the number of turns according to Faraday's law. . Since these potential energies have been input from the beginning, even if magnetic resistance and frictional resistance exist, and they can be reduced with a little ingenuity, the output energy is greater than the input energy. It can be done, but the total amount of energy does not increase or decrease, and is consistent with the law of conservation of energy. In addition, as in the present invention, the output current is passed through the coil wound around the iron core of the stator to excite the iron core, and the magnetic force of the magnetic force accelerates the rotation of the rotor to further increase the output energy. It does not violate the law of conservation of energy at all. At that time, the solenoid coil of the stator pole and the current flowing through it exist in a closed system called a generator in terms of physical form, but in terms of physics, in reality, electricity that has finished outputting once as a generator It's just bringing the energy back to the solenoid coil and letting it flow. In other words, the electrical energy is physically the same as in the case of a motor, and it is actually nothing but the input energy that is inputting the electricity that has been released to the generator system from the outside. Let me add. It is just that the output electric energy is devised and taken in. Of course, at that time, the electric resistance increases as the lead wire becomes longer, and a part of the output electric energy is released as heat energy, but it can still function sufficiently as a motor, and during that time, it can also generate power as a generator. be. Since the energy is positively input from the outside, it is not surprising that the output energy from the generator increases accordingly, and it does not violate the law of conservation of energy. Therefore, even in a situation where an amount of energy of 100 is input to initially rotate the rotor, it is possible to obtain more than that input energy later on during generator operation, and the additional electrical energy will keep the rotor intact. It is not strange to see from the law of conservation of energy that it continues to rotate. This is the description of the invention. In this way, the general public only "additionally" considers the negative magnetic resistance in the generator system, and cannot even think of a way to reduce the magnetic resistance, and therefore cannot consider it. . Either reduce the magnetic resistance of the negative effect, or consider "adding" the magnetic potential energy existing in the generator as well as the additional electric energy from the outside as an electric energy. It is a matter of course that "additional output" is possible. And that additional energy produces additional output power, which is exactly what the law of conservation of energy is for. However, the reality is that no one is aware of it.

Even though it is a generator, even if it has a motor function in it as a whole and magnetic resistance, which is always a problem during power generation, is generated around the coil without an iron core, the same is true. By simply using the generated electricity by continuing to flow it through each coil, it is possible to obtain from each iron core stator magnetic pole a rotation assisting force stronger than the magnetic force resistance, and therefore another external force or energy can be obtained. Even if you don't have any power, you can make it "self-powered" like a motor, and the powerful high-speed rotation can increase the output of power generation in proportion to the number of rotations. This is the greatest feature and advantage of the present invention. As a result, the generator of the present invention, which has a portable weight and size, can be used at home, for example, without the need for conventional large-scale devices such as nuclear power, thermal power, water power, wind power, or gasoline engines, or external energy sources. Of course, it can also be used in companies, factories, other automobiles and trains. Furthermore, electricity can be used as much as you want, anywhere, anytime, anywhere, on the ocean, on mountain tops, in deserts, or even in space, until it breaks down. It is a system that realizes free energy.

"Perspective view showing how the stator coil is wound in the generator of the present invention and the direction of current flowing therethrough" "A perspective view explaining that the rotor can maintain its rotation without stopping even if it is positioned between the two stator poles." "Perspective view explaining that when the rotor faces the stator poles in front, the magnetic force of the stator poles is reversed and the rotation can be continued as it is."

The present invention can be used without the aid of large-scale equipment or external energy such as nuclear power, thermal power, water power, wind power, or gasoline engine, and the size and weight can be made portable, regardless of location. It can be placed anywhere and used as an energy source.

Energy can be used not only in homes but also in companies, factories, automobiles, trains, and so on, anytime, anywhere, and forever, free of charge.

It will completely realize free energy, and it will be enough to start the industrial revolution.

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Claims (1)

The present invention is a generator, and a plurality of even number of rotor magnetic poles are arranged so that the adjacent magnetic poles are alternately opposite N poles and S poles so as to rotate about the center of the generator as a rotation axis. In addition, the stator poles consisting of only the same number of coils as the rotor poles are arranged along the wall around the generator so as to surround the rotor pole tips as viewed from the rotor rotation axis, for example, clockwise first. Wrap the appropriate number of turns in a loop, then wrap the coil wire at the next wall position similarly but this time in the opposite counterclockwise direction for the same number of turns, and so on, until the rotor pole number is determined. In this case, the number of conductors of the stator poles consisting of only the coil bundles arranged in the vertical direction is wound clockwise and counterclockwise from the left and right, respectively. It should be noted that since the number of turns is added together, the number of conductor wires twice as many as the respective number of turns will be installed as a coil stator of a coil bundle arranged in the vertical direction, and furthermore, the stator consisting only of that coil bundle. Outside the poles, but still inside the generator as a whole, are electromagnet poles with coil conductors wound around protruded iron cores similar to the stator poles of a motor, but with the coils used. As for the conducting wire, the same conducting wire that was used to make the stator consisting of only the coil conducting wire bundle described above is brought and wound around the iron core salient pole. When the tip of the rotor magnetic pole passes in front of it, it assists the rotation of the rotor magnetic pole by causing the repulsive force of the magnet from behind to assist the rotation, and also so that the attractive force of the magnet is generated from the front. It is wound to assist the rotation of the rotor magnetic poles, but once the winding direction is determined, the electricity generated by the generator is alternating current, so the rotor will always rotate regardless of the rotational position of the rotor magnetic poles. can be accelerated by magnetic repulsion and attraction. Even if there is a force that prevents the rotation of the rotor magnetic poles due to the magnetic resistance of the rotor, a stronger magnetic force is created in the iron core coil magnetic poles, and the magnetic poles of the iron core coil poles automatically rotate according to the rotational position of the rotor. A generator characterized in that the magnetic poles of the rotor are alternately alternated so that they can continue to generate electricity while continuing to rotate.

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