JPH11155280A - Inter-pole interacting type permanent motor and the motor as its application - Google Patents

Abstract

PROBLEM TO BE SOLVED: To obtain a semipermanent thrust by a magnetic force and transform the thrust into a revolving force for generating power inexhaustibly. SOLUTION: A basic constitution of this motor is such that two flat plates are placed symmetrically with respect to an expected center line but not in parallel with the expected center line so as to have a distance between one side ends of the plates to be narrow and a distance between the other side ends is wide. Fixed magnets (a) and (b) (2) are respectively provided on the inside surfaces of both the flat plates so as to have their different poles face each other, and fixed magnetic tracks A and B (1) are formed so as to increase an attractive magnetic field intensity gradually in a narrow distance direction. A movable magnet 3 which is confined to the expected center line but is movable easily is provided so as to have its polarity opposite to the polarity of the fixed magnet. When the movable magnet reaches a position where the distance between the fixed magnets is narrowest, the leading end of the movable magnet already reaches the wide diatance part of the next basic constitution to keep a thrust.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

INDUSTRIAL APPLICATION The industrial sector of the present invention is too extensive. As can be seen from the claims of the present invention, any propulsion structure driving force (motor) and power generation mechanism can be used.

[0002]

2. Description of the Related Art At present, a propulsion structure is operated by rotating a motor with electric power obtained by burning fossil fuels (such as petroleum). However, most of these electric powers end up with the fossil fuel natural gas or the like. Obtained by burning. Also, recently
Nuclear power generation and the like have also become popular, but their huge costs, difficulty in controlling them, and the seriousness of their danger have led to increasing opposition to nuclear power plants around the world. Some research has been conducted on solar power generation, wind power generation, etc., but it depends on the weather and its reliability is low.

[0003]

As described above in the section of the prior art, most of the means for generating energy today are based on the combustion of fossil fuels. Therefore, the carbon dioxide gas that these inevitably generate as a consequence is
It is clear from various signs that we are already driving the natural environment that underlies humanity into a deadly situation.

[0004]

SUMMARY OF THE INVENTION The present invention does not involve air pollution and the generation of toxic substances due to the consumption of fossil fuel, which is the source of the above-mentioned problems, and mainly uses only permanent magnets as an energy generation mechanism. If no technology is required and only the replacement or filling of the permanent magnet is performed, the input energy is completely unnecessary, and there is no doubt the benefit of the present invention that enables free and clean energy to be made semi-permanently, It was also the ultimate purpose of mankind.

[0005]

According to the basic mechanism of the present invention, a magnetic field is formed obliquely with respect to a certain straight line, the orbit is constrained on the straight line, and a movable magnet is installed with its magnetic pole facing the magnetic field. It starts with the discovery that the magnet slides in the direction in which the magnetic field narrows with respect to the straight line and moves. Therefore, an intermediate layer sandwiched between permanent magnets is provided as shown in FIG.
If the movable magnet (3) is installed at the center thereof to attract the pole faces of the permanent magnets, the movable magnet (3) will continue to move forward. However, in the present invention, if the A and B trajectories are formed symmetrically, the attractive forces on both sides are also symmetrical, and the movable magnet (5) stops at the narrowest magnetic pole (the resultant force of the strong magnetic field). By). Therefore, for example, when the fixed magnets a and b (2) on the fixed magnet base substrates A and B (1) become the narrowest, if the head of the movable magnet is already between the next orbits A and B, Thrust will be maintained. The above is the basic operation of the present invention.

[0006]

FIG. 3 shows an embodiment of the present invention. The movable magnet disk (10) is moved to a vertical shaft so that the magnetic field trajectory comes to the center line where the magnetic field region (16) between the fixed magnet trajectories A and B is located on the donut board fixed magnet base substrate (5). To be continued. In this example, the movable magnet disk (1
0) has an end-wing-type end-separation magnet structure, in which the fixed magnet magnetic field region (16) within the dotted circle is cooperatively attracted at the opening to generate thrust, but at the end, the reverse occurs. The structure is such that the end of the movable magnet (3) is bent in the center of the disk so as to be separated from the magnetic field region (16) of the fixed magnet because the structure is such that the thrust is reduced by being attracted and restrained. . Therefore, each fixed magnet receives only the attraction thrust and the attraction restraint at the time of detachment is avoided in that shape, so that a constant thrust maintenance structure is provided.

[0007]

As described above, the present invention has been imputed to be almost impossible to develop by the predecessor. Is the clean, low-cost only equipment cost that is the basis of the whole life, is safe, compact and free of energy, and is used as direct thrust and driving power, and when connected to a generator, it can be extracted as electricity This is the ultimate invention.

[Brief description of the drawings]

 "

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a plan view showing a basic structure of an inter-pole action that is the basis of the present invention. "

FIG. 2 is a drawing corresponding to a plan view and a side view. "

FIG. 3 is a plan view corresponding to a plane and a side view. FIG. "

FIG. 4 is a plan view illustrating a disk movable magnet structure having a single-wing type end portion departure magnetic field structure. "

FIG. 5 is a plan view of a disk movable magnetic field structure having a triangular wing-type end portion departure magnetic field structure.

[Explanation of symbols]

 Reference Signs List 1 fixed magnet tracks A, B 2 fixed magnets a, b 3 movable magnet 4 fixed magnet track midpoint portion 5 donut board fixed magnet base substrate 6 required bar 7 opening support bar 8 slide holding groove 9 opening support bracket bar 10 disk Movable magnet 11 Vertical shaft 12 Electromagnet head 13 Electromagnet for acceleration 14 Movable magnet wing disk start part 15 Movable magnet wing disk end part 16 Magnetic field area 17 Three fish wing magnet

Claims (10)

[Claims] (1) "Basic structure of the permanent magnet type motor"
As shown in FIG. 1, a symmetrical position is formed by two flat plates which are not parallel to the expected center line but narrowed on one side and opened on the other side.
Fixed magnets a and b (2) with different poles facing each inner surface
The fixed magnet orbits A and B (1) are formed so that the intensity of the attracted magnetic field is uniformly increased with each progress in the direction of the narrow closing, and the center line is projected between the corresponding magnetic poles. A movable magnet (3) which is constrained and can easily move on this line is formed, and the magnetic poles are fixed magnet tracks A and B.
The basic structure of the inter-pole permanent magnet motor in which the fixed magnets a and b (2) of (1) have different polarities on their pole faces. 2. "Basic structure of a linear motor applied to a controllable perpendicular magnetic pole surface action type permanent motor" As shown in FIG. 2, fixed magnet trajectories A and B (1) are formed in a C-shape symmetrically with respect to an expected center line. And it is formed so that it becomes a right-angled triangle when ascending and descending as shown in FIG.
By constituting the movable movable magnet (3), a linear movable magnet can be moved. In addition, the fixed magnet trajectories A and B (1) can be moved up and down and back and forth in the direction of the dotted line with the middle point (4) of the fixed magnet trajectory as a boundary, so that the traveling direction of the movable magnet (3) can be implemented in both directions. It has a configuration. 3. "Permanent Motor Basic Structure of Circular Fixed Magnet Track" As shown in FIG. 3, a single or a plurality of fixed magnet tracks A and B are horizontally mounted on a donut disk fixed magnet base substrate (5). A movable support bar (6) is provided so as to be slidable, and an opening support bar (7) for holding the opening is provided at a listening portion of the fixed magnets A and B (1).
The slide holding groove (8) is opened along the locus of the opening support bar (7) so that the opening support bar (7) does not hinder the donut table fixed magnet base substrate (5) when sliding in the horizontal direction. The groove is formed so as to have an intermediate width between the diameter of the support bar (7) and the diameter of the opening support metal bar (9) running at the center thereof. Therefore, the fixed magnet trajectories A and B
The magnetic field of (1) considerably protrudes from the inner peripheral portion of the donut board fixed magnet base substrate (5) to the cutout portion. Therefore, the movable magnet (3) running horizontally along the center line of the fixed magnet trajectories A, B (1) is also replaced with the fixed magnet a in the inner periphery of the donut board base board (5) as shown in FIG. b (2) A movable magnet is formed on a disk so as to run in a magnetic field in a convenient manner, and the movable magnet is formed as a disk movable magnet (10). The disk movable magnet (10) rotates in a direction in which the fixed magnet trajectories A and B (1) narrow. The basic structure of the permanent motor with a fixed circular magnet track constructed as described above. 4. A fixed magnet trajectory incorporating an electromagnet for acceleration.
An electromagnet head (12) having a movable magnet (3) sandwiched between the fixed magnet orbits A and B of the present invention so as to form a counter electrode with its pole face.
The fixed magnet orbit with the built-in electromagnet for acceleration characterized in that two are set and the electromagnet for acceleration (13) is built in. 5. A disk-impulse magnet structure having a single-wing-type end-portion departure-magnetic-field structure As shown in FIG. 4, the movable magnet (3) is not fixed uniformly to the periphery of the disk board, but is a movable magnet. The wing disk start portion (14) and the movable magnet wing disk end portion (15) are gradually wound into the inside of the disk, so that the movable magnet at the end portion (15) has a circular orbit and trajectory of the start portion (14). Are formed so as to be completely different from each other, so that the end portion (15) does not pass through the magnetic field region (16) of the circle fixed magnet orbit along the dotted line circle, so that the magnetic field region (16) can be easily separated from the magnetic field region (16). A disk movable magnet structure with a single-wing end-of-end departure magnetic field structure characterized by the following. 6. A disk movable magnet structure having a double-wing type end-part departure magnetic field structure. The disk movable magnet having an end-part departure magnetic field structure according to claim 5 of the present invention is provided not in a single circle but in two parts around the disk circumference. A disk movable magnet structure with a double-wing type end magnetic field structure formed by two or more blades. 7. A disk movable magnet structure having a triangular-wing single-blade / double-blade end-part departure magnetic field structure. In the wings according to claims 5 and 6, the magnet widths at the start part and the end part are gradually reduced. A disk movable magnet structure having a triangular wing type single wing / double wing end departure magnetic field structure characterized by using a triangular wing movable magnet (17) formed like a triangular wing as a whole. FIG. 8. The fixed magnet trajectory having the opening / sliding control function The fixed magnet trajectory according to any one of claims 1 to 4 of the present invention is moved in the horizontal direction by incorporating a small motor or the like. A fixed magnet orbit with an opening / sliding control function, characterized in that the horizontal direction and the opening angle are controlled by incorporating a motor so that the rotation speed and torque intensity of the motor can be controlled. 9. The permanent motor basic structure of the multilayer fixed circular magnet track according to claim 3 of the present invention, wherein the shaft portion of the permanent motor basic structure of the circular fixed magnet track has an upper end or a lower end having a concave or convex square shape. The basic structure of the permanent motor of the multilayer circular fixed magnet track, characterized in that the shafts are connected to each other simply by superimposing them, and the shafts are integrated to increase the thrust. 10. "Permanent motor basic structure with single circular fixed magnet track" The fixed magnet tracks A and B which develop the symmetric C-shaped fixed magnet track according to claim 1 of the present invention and gradually narrow from the opening. Is formed in a perfect circle, the narrowest portion is returned to the opening, and the joint is formed as if it were a missing mark, and the disk movable magnet according to claims 5, 6, and 7 of the present invention is incorporated. Features a permanent motor basic structure with a single circular fixed magnet track.