JP2013046562A - Magnetic force rotary engine - Google Patents

Abstract

PROBLEM TO BE SOLVED: To place a rotary device in continuous rotational motion by making a shift in relative position between opposed N and S magnetic poles of magnets of a magnet rotary body and a magnet belt of a rotary device.SOLUTION: The rotary device uses a planetary gear device, and is provided with an arm (A) of the planetary gear device and an arm (B) of the planetary gear device which differ in rotational ratio to rotate interlocking with each other like the long hand and short hand of a timepiece. A magnet rotary body (C) and a magnet belt (E) which have N poles and S poles arrayed alternately are mounted on the rotary device, a magnetic pole and a magnetic pole are continuously shifted in relative position, and the magnet rotary body (C) is rotated revolved along an inner size of an inner gear (3B).

Description

  The present invention relates to a rotating device that converts the magnetic force of a permanent magnet into rotational energy.

  The present invention uses a magnet rotating body and an annular magnet band to generate a sustained rotational motion in the rotating device, so that the relative position shift between the N-pole and S-pole facing each other is reduced. The purpose is to guide the rotational axis of the rotating device to a rotational motion with the force of returning to the relative position when applying.

In order to solve the above problems, the magnetic pole arrangement of the magnet rotating body (C) and the magnet band (E) is preferably arranged by alternately arranging N poles and S poles.

In addition, a planetary gear device is used as the rotating device, and a rotating magnet (C) and a magnet band (E) are mounted on the rotating device. It is advisable to continue and repeat the position shift.

In the planetary gear device, the arm (A) of the new planetary gear device is fixed to the shaft (1A) of the sun gear with respect to the arm (B) of the existing planetary gear device. It may be a device that provides a difference in the rotation ratio between the arm (A) and the arm (B) of the planetary gear device and rotates in an interlocking manner such as the long hand and the short hand of the watch.

The magnet rotating body (C) to which the planetary gear (2C) is fixed is attached to the arm (A) of the planetary gear device fixed to the shaft (1A) of the sun gear, and the magnet band (E) is attached to the frame ( There are two methods of fixing (fixed) to D) and fixing (movable) to the arm (B) of the planetary gear unit, and here, the above (fixed) will be described.

The internal gear (3B) that meshes with the planetary gear (2C) supported by the arm (A) of the planetary gear unit is fixed to the arm (B) of the planetary gear unit, and the arm (B) of the planetary gear unit. The internal gear (3D) that meshes with the supported planetary gear (2B) may be fixed to the frame (D).

In addition, the magnetic force generated in the magnet rotating body (C) in the interaction force due to the displacement of the relative position between the magnetic poles of the magnet rotating body (C) and the magnet band (E) is the axis of the sun gear (1A). Acting in the tangential direction as the center, the magnet rotating body (C) is preferably mounted at a position where a force in one direction always acts.

At the same time, the acting force of the planetary gear (2C) fixed to the magnet rotating body (C) is received by the internal gear (3B) fixed to the arm (B) of the planetary gear device. It is good to make it act on the arm (B) of the planetary gear device via the gear (3B).

At this time, the planetary gear (2C) fixed to the magnet rotating body (C) is not fixed to the internal gear (3B) fixed to the arm (B) of the planetary gear device, but is a planet that supports the magnet rotating body. If a force acts on the arm (A) of the gear unit, the planetary gear (2C) fixed to the shaft of the magnet rotating body (C) may be in a stationary state in which it easily rotates.

Further, the force applied to the arm (B) of the planetary gear device is applied to the sun gear (2A) via the planetary gear (2B), and at the same time, the planetary gear device fixed to the sun gear shaft (1A). It is good to make it act on an arm (A) and to act on the axis | shaft of the magnet rotary body (C) with which the arm (A) of the planetary gear apparatus was mounted | worn.

When the force acting on the arm (A) of the planetary gear device acts as a continuous force in the same direction on the axis of the magnet rotating body (C) supported by the arm (A) of the planetary gear device, According to the internal method of the internal gear (3B) fixed to the arm (B) of the rotating planetary gear device, the magnet rotating body (C) may be rotated while rotating.

That is, in the interaction force generated from the deviation of the relative position of the magnetic pole between the magnetic rotor (C) and the magnet band (E), the resultant magnetic force of the magnet rotor (C) is applied to the magnet rotor (C). The fixed planetary gear (2C) is applied to the internal gear (3B) fixed to the arm (B) of the planetary gear device, and the force is transmitted via the internal gear (3B) to the arm (B) of the planetary gear device. To act.

The acting force is applied to the sun gear (2A) via the planetary gear (2B) supported by the arm (B) of the planetary gear device, and at the same time, the force is fixed to the axis (1A) of the sun gear. The force acting on the arm (A) of the planetary gear unit is also applied to the axis of the magnet rotating body (C).

By using the planetary gear unit mechanism and fixing the planetary gear unit arm (A) to the sun gear shaft (1A), two planetary gear unit arms having different rotation ratios are provided. By attaching the magnet rotating body (C) to the arm (A) of the planetary gear unit fixed to the axis (1A) of the sun gear, and removing the rotating shaft of the magnet rotating body (C) from the center, The magnet rotating body (C) can be guided to the rotating circuit.

And the force which the magnet rotating body (C) which arises from the shift | offset | difference of the relative position of a magnetic pole and a magnetic pole in a magnet rotating body (C) and a magnet belt | band | zone (E) is the planetary gear fixed to the magnet rotating body (C) ( 2C) acts on the internal gear (3B) fixed to the arm (B) of the planetary gear device, and at the same time, the force acting on the internal gear (3B) is also the force acting on the arm (B) of the planetary gear device. The force acting on the arm (B) of the planetary gear device acts on the axis of the planetary gear (2B) supported by the arm (B) of the planetary gear device.

The force acting on the shaft of the planetary gear (2B) acts on the sun gear (2A) via the planetary gear (2B), and at the same time, the force acting on the sun gear (2A) is the arm of the planetary gear device. Acting on (A) and acting on the shaft of the magnet rotating body (C) supported by the arm (A) of the planetary gear device, the planetary gear (2C) fixed to the magnet rotating body (C) is rotated and moved. The magnet rotating body (C) can be guided to a circular motion.

And the force which arises in a magnet rotating body acts on the axis | shaft of a magnet rotating body (C) through each gear and the arm of a planetary gear apparatus, and the force is a magnet rotating body (C) and a magnet belt | band | zone (E). The magnet rotating body (C) is moved to a position that generates the next deviation with respect to the magnetic rotating body (C). As a result, the magnet rotating body (C) and the magnet strip (E) are displaced with respect to the next relative position. ) And the magnet band (E), a new interaction force is generated.

In addition, by using a gear device as a force transmission device, it is possible to position to the intended continuous rotating motion, and as shown in FIGS. A series of consecutive relative position shifts of the magnetic poles in the rotating body (C) and the magnet strip (E) can be generated.

It is a figure which shows one Embodiment of this invention. [FIGS. 2-3] It is a figure which shows the cut surface (1) (2) (3) in FIG. [FIG. 3-3] It is a figure which shows the influence which the magnetic force of a magnet rotary body (C) has on a planetary gear (2C). It is a figure which shows transmission of the force which a magnet rotary body (C) acts. FIG. 5-36 is a diagram showing the positioning of continuous rotation due to the relative position shift between the magnet rotating body (C) and the magnet band (E).

Embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a diagram showing an embodiment, in which a magnet band (E) is fixed to a frame (D), an internal gear (3B) is fixed to an arm (B) of a planetary gear device, The arm (A) of another planetary gear device is fixed to the shaft (1A) of the sun gear (2A). A magnet rotating body (C) to which the planetary gear (2C) is fixed is attached to the arm (A) of the planetary gear device.

FIG. 2A is a section (1) showing the arrangement and positioning of the magnetic poles of the magnet rotating body (C) and the magnet band (E) in FIG. And the positioning for the resultant force (F) of the magnetic force of the magnet rotating body (C) acting on the magnetic poles acting on the magnetic poles to act on the tangential direction around the rotating shaft (1A) of the sun gear (2A) is shown. Is.

FIG. 2-2 is a section (2) showing meshing and positioning of the planetary gear (2C) and the internal gear (2B) fixed to the magnet rotating body (C) in FIG.

FIG. 2-3 is a cut view showing the meshing and positioning of the planetary gear (2B) supported by the sun gear (2A) and the arm (B) of the planetary gear unit in FIG. 1 and the internal gear (3D) fixed to the frame. Surface (3).

As shown in FIG. 3-1, when the resultant force (F) of the magnetic force acts on the planetary gear (2C) fixed to the magnet rotor (C) in the planetary gear device, the axis of the magnet rotor (C) is applied. Generates a moment of force with the meshing point (point P) of the planetary gear (2C) fixed to the magnet rotating body (C) and the internal gear (3B) as a fulcrum.

The planetary gear (2C) in which an arbitrary force of the magnet rotating body (C) is fixed to the magnet rotating body (C) in the interaction force generated between the magnetic poles of the magnet rotating body (C) and the magnet strip (E). FIG. 6 is a diagram in which the resultant magnetic force (F) acts outside the meshing point (point P) between the planetary gear (2C) and the internal gear (3B).

At this time, when the resultant force (F) of the leftward magnetic force acts outside the meshing point (point P) between the planetary gear (2C) and the internal gear (3B), the shaft of the magnet rotating body (C) A clockwise force moment occurs at the meshing point (point P) as a fulcrum, and a rightward force (FI) is applied to the arm (A) of the planetary gear unit that supports the shaft of the magnet rotating body (C). Works.

3-2 is a diagram in which the resultant force (F) of the magnetic force acts on the inner side of the meshing point (point P) between the planetary gear (2C) and the internal gear (3B).

At this time, when the resultant force (F) of the leftward magnetic force acts on the inner side of the meshing point (point P) between the planetary gear (2C) and the internal gear (3B), the shaft of the magnet rotating body (C) A counterclockwise force moment is generated with the meshing point (point P) as a fulcrum, and a leftward force (FII) is applied to the arm (A) of the planetary gear device that supports the shaft of the magnet rotating body (C). ) Acts.

FIG. 3C is a diagram in which the resultant magnetic force (F) acts on the meshing point (point P) between the planetary gear (2C) and the internal gear (3B).

As shown in FIGS. 3A and 3B, the meshing point (point P) between the planetary gear and the internal gear is a branch point in the direction of the force acting on the shaft of the magnet rotating body (C). At any time, when the resultant force (F) of the magnetic force acts on the meshing point (point P) of the planetary gear (2C) and the internal gear (3B), the force is fixed to the arm (B) of the planetary gear device (3B). Leftward force (FIII) acts on the shaft of the magnet rotating body (C), no rotational moment is generated on the shaft of the magnet rotating body (C), and no force is applied to the arm (A) of the planetary gear unit that supports the magnet rotating body (C). Will not work.

Next, the form of the gear device of the present invention will be described with reference to FIGS. 2-2 and 2-3.

As shown in FIG. 2-3, in the planetary gear device, << the number of teeth of the sun gear (2A): the number of teeth of the planetary gear (2B): the number of teeth of the internal gear (3D) >> is << 1: 1: 3 >>. At the ratio, the relationship between the sun gear (2A) and the planetary gear (2B) is that when the planetary gear (2B) makes one rotation of the internal method of the internal gear (3D), the sun gear (2A) makes one rotation from the original position. And turn 1/3.

This is because when the planetary gear unit arm (B) rotates 120 degrees, the planetary gear unit arm (A) fixed to the shaft (1A) of the sun gear (2A) rotates 480 degrees, and the planetary gear unit arm ( The rotation ratio between B) and the planetary gear unit arm (A) is << 1: 4 >>.

At the same time, when the internal gear (3B) fixed to the arm (B) of the planetary gear device rotates 120 degrees, the planetary gear (2C) fixed to the magnet rotating body (C) supported by the arm (A) of the planetary gear device. )) Also rotates, and the internal method of the internal gear (3B) goes around 480 degrees.

And, as shown in FIG. 2-2, << the number of teeth of the planetary gear (2C) fixed to the magnet rotating body (C): the number of teeth of the internal gear (3B) fixed to the arm (B) of the planetary gear unit >> When the ratio is << 1: 4 >>, the rotating inner gear (3B) is rotated while the magnet rotating body (C) rotates, and the original mounting position is rotated three times with respect to the underframe (D). Return.

FIGS. 5-1 to 5-36 show the positioning of the continuous rotation due to the displacement of the relative positions of the magnet rotating body (C) and the magnet band (E). A series of successive relative position shifts of the magnetic poles of the magnetic strip (E) are formed.

Effects of the embodiment

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

As shown in FIG. 3C, the meshing point (point P) of the planetary gear (2C) and the internal gear (3B) is the force acting on the arm (A) of the planetary gear device fixed to the sun gear (2A). When the resultant force (F) of the magnetic force of the magnet rotating body (C) acts on the meshing point (point P) of the planetary gear (2C) and the internal gear (3B) at any time, the force is the planetary gear. It acts on the internal gear (3B) fixed to the arm (B) of the device, and no force acts on the arm (A) of the planetary gear device that supports the planetary gear (2C).

At this time, the magnet rotor (C) is not fixed to the meshing point (point P) between the planetary gear (2C) and the internal gear (3B), and a force acts on the sun gear (2A), If a moment of force is generated in the arm (A) of the planetary gear unit fixed to the sun gear shaft (1A), the magnet rotating body (C) supported by the arm (A) of the planetary gear unit easily rotates. It is an unstable state that can be caused.

Then, the inner gear (3B) is fixed to the arm (B) of the planetary gear device, and the magnet rotating body (C) and the planetary gear (2C) supported by the arm (A) of the planetary gear device are connected to the planetary gear device. When it is incorporated in the internal gear (3B) fixed to the arm (B) and a relative position shift is given to the magnetic poles of the magnet rotating body (C) and the magnet strip (E) as shown in FIG. 2-1, the magnet rotating body In (C), a force F is generated to return to the relative position.

When the force F to return to the relative position acts on the meshing point (point P) of the planetary gear (2C) and the internal gear (3B), the arbitrary force acting on the magnet rotating body (C) is At the same time on the internal gear (3B) fixed to the arm (B) of the device, and simultaneously via the internal gear (3B), from the arm (B) of the planetary gear device to the planetary gear (2B), and from the planetary gear (2B) to the sun. It acts on the gear (2A) and also on the arm (A) of the planetary gear unit via the sun gear (2A), and the acting force can be applied to the axis of the magnet rotating body (C).

As shown in FIG. 4, when the force acting on the magnet rotating body (C) resulting from the deviation of the relative positions of the magnetic poles in the magnet rotating body (C) and the magnet strip (E) is the force F, the magnet The force acting on the planetary gear (2C) fixed on the rotating body (C) acts as the force F1 on the internal gear (3B) fixed on the arm (B) of the planetary gear device, and at the same time on the internal gear (3B). The acting force F1 is also a force F1 acting on the arm (B) of the planetary gear device, and the force F1 acting on the arm (B) of the planetary gear device is a planetary gear supported by the arm (B) of the planetary gear device. Acts as a force F2 on the axis (2B).

Further, the force F2 acting on the axis of the planetary gear (2B) acts as the force F3 on the sun gear (2A) via the planetary gear (2B), and at the same time, the force F3 acting on the sun gear (2A) is It can be explained that it acts as a force F4 on the axis of the magnet rotating body (C) supported by the arm (A) of the planetary gear device, and the force F4 rotates and moves the axis of the magnet rotating body (C). (C) can be led to a circular motion.

Then, as shown in FIG. 2-2, the number of teeth of the gear of << the planetary gear (2C) fixed to the magnet rotating body (C): the internal gear (3B) fixed to the arm (B) of the planetary gear unit >> When the ratio is 1: 4 >>, the arm (A) of the planetary gear device rotates 480 degrees when the internal gear (3B) rotates 120 degrees, so that the shaft of the magnet rotating body (C) rotates and rotates 480 degrees. Then, since the magnet rotating body (C) rotates 480 degrees while rotating 4 times with respect to the inner method of the rotating internal gear (3B), the magnet rotating body (C) is rotated 3 times with respect to the frame (D). Return to the original mounting position.

When the positioning of the magnet rotating body (C) and the magnet band (D) repeats the positioning shown in FIGS. 5-1 to 5-36 sequentially, the magnet rotating body (C) and the magnet band (D) In the interaction force generated between the magnetic poles, a series of consecutive relative positional deviations between the magnetic poles is formed, and the magnet rotating body (C) can be rotated while rotating along the internal method of the internal gear (3B). This is a rotating engine that uses the magnetic force of the magnet as an energy source, and has been established to maintain a continuous rotational motion by the gear device.

Since the magnetic force of the magnet is used as the rotational energy source of the rotating device, it is possible to focus on energy problems and create a new wide range of industries.

A New planetary gear unit arm B fixed to the shaft of the sun gear B Existing planetary gear unit arm C attached to the planetary gear unit Magnet rotating body D frame E frame E mounted on the planet gear unit arm (A) 1A Sun gear shaft 2A Sun gear 2B Planetary gear 2C of an existing planetary gear device Planet gear 3B fixed to a magnet rotating body Internal gear 3D fixed to the arm (B) of the planetary gear device Internal gear

Claims (5)

  A rotating device provided with a planetary gear device.   A rotating device comprising a planetary gear device arm (A) and a planetary gear device arm (B) having different rotation ratios that rotate in conjunction with each other such as a long hand and a short hand of a timepiece.   A rotating device characterized in that the magnetic force of a magnet is used as a rotational energy source.   A rotating device characterized in that the magnet arrangement of the magnet rotating body and the magnet band is arranged by arranging N poles and S poles alternately.   A rotating device characterized by continuously repeating and continuing a shift of a relative position between a magnetic pole and a magnetic pole of a magnet rotating body and a magnet band.

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