JPH01164276A - Power generating set - Google Patents

Abstract

PURPOSE:To generate a rotational force without setting a separate energy source, by arranging a plurality of respective rotors with their peripheral surfaces confronted, and by setting an interrupting member for interrupting a part of a magnetic replusing force or attaching force, between the respective rotors. CONSTITUTION:To the two output shafts 2-3 of a power generating set 1, generators 4-5 are connected, and the rotational force is transmitted to the generators 4-5 to generate power. In this generating set 1, the output shafts 2-3 are arranged in parallel with each other at a specified interval, and are supported pivotally and rotatably by a bearing 6. On the outer peripheries of the output shafts 2-3, rotors 7-8 are externally fixed, and a plurality of rod magnets 9 are arranged to be fixed. Besides, at the lower sides of the rotors 7-8, a cover member 10 formed with superconducting material is set, and a cooler is set. A cover-central section 13 acts as an interrupting member and both the side sections 14 works as offset members. Then, a controller 19 for controlling the rotational position of a motor 17 is set, and the positions of both the members 13, 14 are controlled, and the rotors 7-8 are rotated.

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial Application Field) The present invention relates to a power generation device that utilizes magnetic repulsion or attraction.

(Prior art) Various types of power generation devices that generate rotational force have been used as important mechanical elements in various industrial fields.For example, in automobiles, the engine generates rotation and the In home appliances, motors generate rotation to operate various mechanisms.

(Problems to be Solved by the Invention) However, all conventional power generating devices have a problem in that, due to their structure, a separate energy source is required to continuously generate rotation. For example, in an engine, the vertical motion of the piston is converted into rotational motion by a crank mechanism, so it is necessary to cause a continuous explosion within the cylinder.In addition, in a motor, the magnetic repulsion force at each rotational position of the rotor is required. Alternatively, since the rotor is rotated by an attractive force, it is necessary to switch the applied voltage to reverse the magnetic force.

In view of these conventional problems, it is an object of the present invention to provide a power generation device that can continuously generate rotation without providing a separate energy source.

By the way, with recent advances in material technology, various superconducting materials have been developed, and it is known that one of the characteristics of these superconducting materials is that they exhibit the so-called Meissner effect, in which magnetic force does not penetrate inside. ing.

As a result of intensive research to solve the above-mentioned problems, the inventor of the present invention found that if the Meissner effect described above and the same-polar repulsion or different-polar attraction of a magnet are effectively utilized, a separate energy source can be provided. We discovered that it is possible to continue rotating without any problems.

That is, when the circumferential surfaces of a pair of rotors are magnetized to the same polarity or different polarities, and both rotors are arranged with their circumferential surfaces facing each other,
Equal rotational forces in both clockwise and counterclockwise directions are applied to each rotor due to homopolar repulsion force or different polarity attraction force, so that both rotors are in a stationary state. When a superconducting member is inserted between both rotors in this state, a part of the homopolar repulsive force or different polarity attractive force between the two rotors is blocked, and the rotors are rotated into a clockwise rotation force and a counterclockwise rotation force. A force difference occurs, which causes both rotors to rotate. However, in this case, a repulsive force is generated between the superconducting member and the rotor, which causes rotational resistance of the rotor.The present invention has been completed by solving this problem.

(Means for Solving the Problems) Therefore, in the power generation device according to the present invention, a rotor is fixed to each of a plurality of output shafts, and the rotors are arranged with their circumferential surfaces facing each other. The peripheral surfaces of the rotors are magnetized with the same polarity or different polarities, and a blocking member is provided between each rotor to block part of the magnetic repulsion or attractive force. A canceling member is provided to cancel the magnetic repulsive force of the magnetic force.

Further, the power generating device according to the present invention preferably includes a drive control device that controls the position of the blocking member with respect to the position closest to each rotor, and also controls the position of the offset member with respect to the blocking member.

(Function) In this invention, when a part of the magnetic repulsion or magnetic attraction between the rotors is blocked by the blocking member, a clockwise rotational force due to the magnetic repulsion or attraction of each rotor is generated. A difference occurs between the rotational force in the clockwise direction and the rotational force in the counterclockwise direction, and the magnetic repulsion between the blocking member and the rotor is canceled by the magnetic repulsion between the canceling member and the rotor, and as a result, each rotor responds to the rotational force in the clockwise direction. It will continue to rotate due to the difference in rotational force between the rotational force and the counterclockwise rotational force.

In addition, in this invention, when the drive control device controls the position of the blocking member with respect to the position closest to each rotor and the position of the offset member with respect to the blocking member, the clockwise rotational force of each rotor and the counterclockwise rotational force are controlled. The difference in the rotational force between the two is controlled, and thereby the rotational speed of the rotor is controlled.

(Example) Hereinafter, embodiments of the present invention will be described with reference to the drawings.

1 and 2 show a power generation system to which a power generation device according to an embodiment of the present invention is applied. In the figure, 1 is a power generator, and two output shafts 2 and 3 of the power generator 1 are
A generator 4.5 is connected to the generator 4.5, and the rotational force of the power generating device 1 is transmitted to the generator 4.5 to generate electricity.

In the power generating device 1, the output shaft 2.
3 are arranged parallel to each other at a predetermined interval and are rotatably supported by bearings 6. Also,
A rotor 7.8 is externally fixed to the outer circumferential surface of the output shaft 2.3, and a plurality of bar magnets 9 are arranged on the circumferential surface of the rotor 7.8 with their S and N poles facing in the same direction. The rotors 7.8 are arranged and fixed in parallel, so that the rotors 7.8 are arranged with their circumferential surfaces facing each other and magnetized with the same polarity. Here, since the strength of magnetization of the bar magnet 9 is closely related to the generated rotational force, the strength is set according to the magnitude of the load.

Further, a cover member 10 formed of a superconducting material is disposed below the rotor 7.8, and a cooling device (not shown) is provided to cool the cover member 10 to below a critical temperature. is installed. Two approximately semi-cylindrical recesses 11 and 12 are formed in this cover member 10.
．． The lower half of the rotor 7.8 can be accommodated in the interior of the rotor 7.8, and the center portion 13 of the cover member 1O serves as a blocking member that blocks part of the magnetic repulsion between the rotors 7.8. , and both sides 14 of the cover member 10 are connected to the rotor 7.8.
It serves as a canceling member that cancels out the magnetic repulsive force between the blocking member 13 and the rotor 7.8 by the magnetic repulsive force between the shielding member 13 and the rotor 7.8.

Further, the cover member 10 is provided to be movable up and down by a guide rod 15, and a rack gear 16 is vertically fixed to the lower surface of the cover member 10, and a pinion gear 18 of a motor 17 is meshed with the rack gear 16. Further, the motor 17 is provided with a control device 19 for controlling its rotational position and position, and as described above, each rotor 7.
A drive control device 20 is configured to control the position of the blocking member 13 with respect to the closest position of the blocking member 8 and the position of the offset member 14 with respect to the blocking member 13.

Next, the operation of this system will be explained.

In this system, before the system is activated, the cover member lO is at its lowest position, and the clockwise rotational force and counterclockwise rotational force of the rotor 7.8 due to the magnetic repulsion of the bar magnet 9 are generated. , the rotor 7.8 is stationary.

In this state, when the motor 17 is operated by the output of the control device 19, the rotational force of the motor 17 is transmitted to the cover member 10 via the rack and pinion mechanism 16.18, and the cover member 10 is raised. The rotor 7.8 is housed in the recesses 11, 12 thereof, and covers the lower half of the rotor 7.8. Then, a part of the magnetic repulsion of the bar magnet 9 between the lower half of the rotor 7.8 is blocked by the central portion 13 of the cover member 10, and at the same time, the magnetic repulsion between the central portion 13 of the cover member 10 and the rotor 7.8 is The magnetic repulsion generated between the bar magnets 9 and 9 is canceled out by the magnetic repulsion generated between the side of the cover member 10 and the bar magnets 9 of the rotor 7.8, which causes a counterclockwise rotational force on the rotor. However, regarding the rotor 8, the rotational force in the clockwise direction is larger than the rotational force in each other direction, and the rotor 7 is rotated counterclockwise (in the direction of arrow A), and the rotor 8 is rotated in the clockwise direction (direction of arrow B). It starts to rotate.

When the cover member 10 further rises, the counterclockwise rotational force of the rotor 8 and the clockwise rotational force of the rotor 8 due to the magnetic repulsion force each increase more than the rotational force in the other direction,
When the rotational speed of the rotor 7.8 increases, the cover member 10 reaches the highest position, and the upper surface of the cover member 10 reaches the plane connecting the output shaft 2.3, the rotational speed of each rotor 7.8 reaches its maximum. become. The rotational force of the rotor 7.8 is then applied to the output shaft 2.
．． 3 to the generator 4.5, and power generation is performed. Furthermore, if the rotation speed of the rotor 7.8 is too high, the cover member 10 may be lowered.

In the system of this embodiment as described above, rotational force is generated by controlling the magnetic repulsion between the rotors with magnetized surfaces, so there is almost no energy loss. It is possible to generate power by generating rotational force without providing any.

In the above embodiment, the bar magnets 9 of the rotor 7.8 are arranged in the same direction so that the rotors 7.8 are magnetized with the same polarity, but the bar magnets 9 are arranged in the opposite direction so that the rotor 7.8 is magnetized with the same polarity. The magnets may be magnetized to have different polarities, and rotation may be generated using magnetic attraction. In addition, the magnetization method is not to set one end of the rotor 7.8 as an S pole and the other end as an N pole, but to
The outside of the circumferential surface may be the S pole or the N pole, and both sides may be the N pole or the S pole.

Further, although two rotors are provided in the above embodiment, three or more rotors may be provided if the structure is the same. Furthermore, it goes without saying that the power generation device of the present invention can be applied to systems other than power generation systems.

Further, in the above embodiment, the blocking member 13 and the offset member 14 are provided integrally, but they may be provided separately.

(Effects of the Invention) As described above, the power generation device according to the present invention arranges a plurality of rotors with their circumferential surfaces facing each other, magnetizes each circumferential surface with the same polarity or different polarity, and magnetizes each rotor with the same polarity or different polarity. A blocking member is provided between the rotors to block part of the magnetic repulsion or attraction force, and an offset member is provided to cancel out the magnetic repulsion between the rotor and the blocking member by the magnetic repulsion with the rotor. Since the rotational force is generated by controlling the non-uniformity of the magnetic repulsion or attraction force, it is possible to generate the rotational force without providing a separate energy source.

[Brief explanation of the drawing]

FIG. 1 is an overall configuration diagram of a power generation system using a power generation device according to an embodiment of the present invention, and FIG. 2 is a configuration diagram of essential parts of the power generation device. l...Power generator, 2.3...Output shaft'7.
8...Rotor, 13...Central part of cover member 1O as a blocking member, 14...Side part of cover member 10 as a counterbalancing member, 20...Drive control device. Patent applicant Yoshi 1) Faithful agent Patent attorney Hisao Ishii

Claims (2)

[Claims] (1) A rotor is fixed to each of a plurality of output shafts, the rotors are arranged in parallel with their circumferential surfaces facing each other, and the circumferential surfaces of the rotors are magnetized to have the same polarity or different polarity, A blocking member is disposed between each of the rotors to rotate each of the rotors by blocking part of the magnetic repulsion or attraction between the rotor circumferential surfaces, and a blocking member is provided between the blocking member and the rotor. A power generating device characterized by being provided with an offset member that offsets magnetic repulsion by a magnetic repulsion generated between the rotor and the rotor. (2) The position of the blocking member relative to the position closest to each of the rotors is controlled by the drive control device, and the position of the offset member relative to the blocking member is controlled by the drive control device. A power generating device according to claim 1, characterized in that: