JP2000041375A - Permanent magnet homopolar rotational energy amplifier - Google Patents

Abstract

PROBLEM TO BE SOLVED: To amplify energy at low cost without pollution. SOLUTION: This permanent magnet homopolar rotational energy amplifier is provided with a powerful input rotor magnet 1 and output slide stator magnets 2, which are arranged uniformly and installed so that they are singly and reciprocatively slid by a certain distance, respectively. The output slide stator magnets 2 are partly shifted by a certain distance in the direction of the rotary shaft, so that when the input rotor magnet 1 is rotated, sliding operation is repeated in the direction of the rotary shaft by repulsion between the magnets. An induction motor for input is installed on the input stator magnet 1, and there is installed on the output side an output rotor magnet 4, which transmits the reciprocative sliding force of the output slide stator magnets 2 to an output conversion slide stator magnet 3 through a coupling device and converts it into rotational force.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

[Industrial application] The rotational energy amplifying device according to the present invention can obtain a much larger output energy than the input energy by utilizing the energy held by the permanent magnet, and therefore, a part of the output energy is input. If it is applied to energy, it will be completely non-polluting, and will be a prime mover for power generation, motor vehicles, various types of transportation, small aircraft, ships, and other prime movers that use existing fossil fuels and most of the electrical equipment that uses electricity. Available. or,
It is compact and has little operating cost.
Therefore, it can be used anywhere.

[0002]

2. Description of the Related Art Conventionally, a prime mover using fossil fuel and a motor using electric energy from hydraulic power, thermal power, and nuclear power generation have been used.

[0003]

[Problems to be Solved by the Invention] Human civilization has been developed by the use of fossil fuels. However, due to the long-term accumulation of exhaust gas, the global environment such as air pollution, marine pollution, deforestation, acid rain, and global warming phenomenon The destruction of the natural environment above has progressed, and on the contrary, it has had a serious adverse effect on human life. Under the current situation, there is a limit to the amount of fossil fuel resources remaining, and it will not be possible to leave it to future humans. Furthermore, energy costs account for a very large proportion of production and economic activities, hindering development, expanding desertification phenomena by deforestation in areas with low energy resources, such as low-developed countries, and treating spent nuclear fuel in nuclear power. Is a major problem. The present invention has been made to solve such a problem.

[0004]

Means for Solving the Problems In order to achieve the above-mentioned object, a permanent magnet homopolar rotation energy amplifying device according to the present invention utilizes a repulsive force between magnets, which is a basic characteristic of a permanent magnet, to apply a bearing. A strong magnet having a uniform outer diameter and a cylindrical shape having a dimension in the direction of the rotation axis and having the same magnetic pole is attached to the outer circumference of the entire circumference. This magnet (input rotor magnet) is formed in such a shape that a part around the entire circumference in the rotation axis direction, or a multiple thereof is alternately shifted by a certain size on both sides. The input rotor magnet is held so as to slide back and forth by a certain size in the direction of the rotation axis while maintaining a certain gap with the outer peripheral surface of the input rotor magnet. (Stator magnet) so that the same pole faces the input rotor magnet. or,
Attach an induction motor to rotate the input rotor magnet. A magnet having a fixed outer diameter and a cylindrical shape having a constant outer diameter and a dimension in the direction of the rotating shaft, and having a number corresponding to the number of output slide stator magnets on the entire circumference is provided on another rotating shaft of the input rotor magnet and a coaxial line. As the magnetic poles (N pole, S pole) alternate,
Also, attach a strong magnet (output rotor magnet) so that the magnetic poles alternate with a fixed size in the direction of the rotation axis. The output rotor magnet is slid back and forth by a certain size in the direction of the rotation axis while maintaining a certain gap with the outer peripheral surface of the output rotor magnet, and is correlated with the size and number of magnetic poles in the direction of the rotation axis of the output rotor magnet. Attach a magnet (output conversion slide stator magnet) that has a correlation with the size and number of slide stator magnets. This output conversion slide stator magnet
It is connected to the output slide stator magnet by a connecting device.

[0005]

1 and 2, when the input rotor magnet (1) is rotated in a certain direction by the induction motor (7), the position of the input rotor magnet (1) in the direction of the rotation axis (5) and the output slide stator are changed. The output slide stator magnet (2) slides in the direction of the rotation axis (5) due to the repulsion between the magnets due to the positional relationship with the magnet (2). When the input rotor magnet (1) is continuously rotated, the output slide stator magnet (2) repeatedly slides back and forth. In this case, the power for rotating the input rotor magnet (1) is determined by the repulsive force between the portion of the input rotor magnet (1) in the direction of the rotation axis (5) and the output slide stator magnet (2). Input rotor magnet (1) and output slide stator magnet (2)
As the outer diameter and the size in the direction of the rotation axis (5) of the motor become larger, the repulsive force between the input rotor magnet (1) and the output slide stator magnet (2) increases, and the reciprocating slide force of the output slide stator magnet (2) increases. growing. Therefore,
If this dimension is made a certain dimension or more, the output (the reciprocating sliding force of the output slide stator magnet) becomes larger than the input, and this reciprocating sliding force is transmitted to the output conversion slide stator magnet (3) and the output rotor magnet (4). , A rotation output considerably larger than the input is obtained from the output side rotation shaft (6).

[0006]

Embodiments will be described with reference to the drawings. In FIGS. 1 and 2, the input side rotary shaft (5) supported by the bearing (9) has a cylindrical shape having a constant outer diameter and a size in the direction of the rotary shaft, and has the same magnetic pole strength toward the outside of the entire circumference. A good magnet (input rotor magnet) is attached. The input rotor magnet (1) has a shape in which about half of the entire circumference is alternately displaced by a certain size on both sides in the direction of the input side rotation shaft (5). The output slide stator magnet (2) so as to reciprocate by a certain size in the direction of the input side rotation shaft (5) while maintaining a certain gap with the outer peripheral surface of the input rotor magnet (1).
Are equally arranged, and the guide (11) is attached so as to slide back and forth smoothly. In addition, an induction motor (8) is attached to rotate the input rotor magnet (1). The input rotor magnet (1) has a cylindrical shape with a constant outer diameter and a dimension in the direction of the output rotary shaft (6) on the input rotary shaft (5) and another output rotary shaft (6) of the coaxial line. The size of the input rotor magnet (1) is correlated with the size of the input rotor magnet (1) so that the magnetic poles (N pole, S pole) of the semicircular magnet having a fixed size in the direction of the output side rotation shaft (6) are alternately arranged. It is arranged and attached to. This output rotor magnet (4)
The output side rotating shaft (6), while maintaining a constant gap with the outer peripheral surface of the
The size of the output rotor magnet (4) correlates with the size and number of magnetic poles in the direction of the output side rotating shaft (6), and the size of the output slide stator magnet (2) correlates with the size. Four output conversion slide stator magnets (3) having the same dimensions as the output slide stator magnets (2) are evenly arranged and mounted. The output conversion slide stator magnet (3) has the same slide system as the output slide stator magnet (2), and is connected to the output slide stator magnet (3) by a connection device (7). These are attached to the casing (10) or installed in the casing.

[0007] Input and output are performed by controlling the number of revolutions of the input rotor magnet (1). In this case, the rotation speed of the input induction motor is controlled by the inverter. With the above structure and system, a strong permanent magnet (for example, rare earth neodymium-iron-boron magnet)
From the repulsion force, a considerably larger rotation output than the input can be obtained.

Since the present invention is configured as described above, the following effects can be obtained.

[0009] An output larger than the input can be obtained and it is completely pollution-free.

At present, magnets having very large coercive force, residual magnetic flux density and maximum energy product such as rare earth neodymium-iron-boron permanent magnets have been developed.
From the data of the experimental results by the experimental apparatus, when this permanent magnet is used, an output of about 50 KW can be obtained in a theoretical calculation with a size of about 600Φ × 1000 L.

[Brief description of the drawings]

FIG. 1 is a side view (cross-sectional view).

FIG. 2 is a front view (cross-sectional view).

[Sign]

 REFERENCE SIGNS LIST 1 input rotor magnet 2 output slide stator magnet 3 output conversion slide stator magnet 4 output rotor magnet 5 input side rotation shaft 6 output side rotation shaft 7 coupling device 8 induction motor 9 bearing 10 casing 11 guide

Claims (1)

[Claims] The present invention applies a repulsive force between the same poles, which is a basic characteristic of a permanent magnet, to a rotating shaft supported by a bearing. Attach a strong magnet of the same polarity toward the outside of the circumference. This magnet (input rotor magnet) is formed in such a shape that a certain portion of the entire circumference or a multiple thereof is alternately shifted by a certain size on both sides in the direction of the rotation axis. The input rotor magnet is held in a fixed gap with the outer circumference thereof so as to slide back and forth by a certain size in the rotation axis direction, and the number of magnets (output slide stators) correlated with the number of displacements of the input rotor magnet in the rotation axis direction. ) So that the same pole faces the input rotor magnet. In the above, when the input-side rotary shaft is rotated by some power, the input rotor magnet rotates, and the repulsive force between the magnets acts due to the positional relationship between the position of the input rotor magnet in the rotational axis direction and the output slide stator magnet. Then, the output slide stator magnet slides in one direction of the rotation axis. When the input rotor magnet is continuously rotated, the output slide stator magnet repeats the reciprocating slide sequentially. The power for rotating the input rotor magnet is determined by the repulsion between the input rotor magnet and the output stator magnet in the direction of the axis of rotation, and by keeping the size of this shift constant outside the input rotor magnet and the output slide stator magnet. As the diameter and the size in the rotation axis direction are increased, the repulsive force of the input rotor magnet and the output slide stator magnet is increased, and the reciprocating slide force of the output slide stator magnet is proportionally increased. Therefore, if this dimension is made a certain dimension or more, the output (the reciprocal sliding force of the output slide stator magnet) becomes larger than the input. By converting the reciprocating sliding force of this output slide stator magnet into a rotational force by using the repulsive force and attractive force of a strong magnet in the same way, it is possible to obtain a considerably larger rotational force than the input. Permanent magnet homopolar rotation energy amplifier.