WO2008009220A1

WO2008009220A1 - Magnetic repulsion power machine

Info

Publication number: WO2008009220A1
Application number: PCT/CN2007/002139
Authority: WO
Inventors: Gang Liu; Guimin Yang; Ziyi Liu
Original assignee: Gang Liu; Guimin Yang; Ziyi Liu
Priority date: 2006-07-12
Filing date: 2007-07-12
Publication date: 2008-01-24
Also published as: CN101106340A

Abstract

A magnetic repulsion power machine comprises a stator, a rotor, a body (15) of magnetic conductance material, permanent magnets having a same polarity are fixed on the stator and the rotor, before the permanent magnets (12) of the rotor approach the permanent magnets (2) of the stator, the body of magnetic conductance material shields the magnetic field of the stator or the rotor so that the magnetic repulsive force between the stator and the rotor does not act, when the permanent magnets of the stator move far away from the permanent magnets of the rotor, the body of magnetic conductance material is moved off rapidly, the permanent magnets of the stator opposite the permanent magnets of the rotor which have the same polarity as the stator, and the magnetic repulsive force rotates the rotor to output power.

Description

Magnetic repulsion machine

BACKGROUND OF THE INVENTION 1. Field of the Invention This invention relates to a magnetic repulsion machine, and more particularly to a magnetic repulsion machine that relies on magnetic poles of different permanent magnets in the same direction and corresponding to each other as a power source. Background technique

At present, most known power machines are powered by oil, coal, electricity, water, wind and solar energy. Most of the power machines have problems such as excessive manufacturing cost or waste of resources in work, pollution of the environment, etc. The study of power came into being. The announcement number is

The Chinese patent of CN1144415 (patent number: 96118612. 7) discloses an "electrically controlled magnetic motor" consisting of a stator magnet, a rotor magnet, a magnetic flux gap and a control coil, and both the stator and the rotor magnet are permanent magnets, in the rotor A magnetic flux gap is left on the magnet, and a control coil 装有 is arranged in the gap, and the control coil is connected with intermittent DC power, and the rotor is rotated by the magnet. Since the DC power is required to be uninterrupted, the operation is troublesome. Chinese Patent Application Publication No. CN1431764 discloses a "new type of magnetic power machine" which adopts two magnetic plates with a certain angle on the outer side of the rotor, and the two magnetic plates are opposite to the same pole of the rotor, although the angle is Adjust, but adjustment during work is very inconvenient, it is difficult to achieve the desired effect when starting or stopping. Summary of the invention

The present invention is directed to the above-mentioned deficiencies, and provides a magnetic repulsion machine that generates a magnetic repulsive force by interacting with a magnet of the same polarity when the same magnetic pole is fixedly arranged on the stator and the rotor is rotated.

The technical solution adopted by the present invention is:

A magnetic repulsion machine includes a base, a casing, a push-pull mechanism and a transmission shaft, wherein the transmission shaft has a joint sleeve, and one end of the sleeve has a slot connected with the push-pull mechanism, and the other end of the sleeve is fixed The circumferential sleeve bracket has a fixing bracket at the periphery of the sleeve bracket, the fixing frame has at least one permanent magnet arranged in the same polarity, the casing is fixed with the annular bracket, and the annular bracket has at least one The above permanent magnets are arranged in the same polarity in the same direction. The fixing frame and the magnets of the same polarity arranged in the fixing frame form a rotor, and the ring-shaped bracket and the magnets of the same polarity arranged in the ring bracket form a stator, a stator and a rotor. The upper magnets are magnetically identical to each other; the annular support on the stator or the inner side of the casing has at least one track or round seat, and the cam shaft is fixed with a cam groove, an electromagnetic, a light sensing device and a live connection. The mechanism such as the swinging rod controls the magnetically permeable material body and other materials to integrally slid or slide in the track to slide or rotate on the round seat, or the rotor shaft fixing bracket has at least one track or round seat, and the swing rod is connected In the rotor shaft fixing frame, one end of the swinging rod is connected to the body of the magnetic conductive material, and the other end is fixed on the stator or the cam groove fixed on the inner side of the casing, electromagnetic, optical sensing device and the like. The control magnetic material body and other materials are integrally slid in the track to slide or abut on the round seat; the rotor magnet and the stator magnet have the same polarity, and the stator magnet and the rotor magnet have the same polarity corresponding surface Before the motion process is close to the phase, the magnetic field of the magnet is turned on by the control system with the magnetic material, so that the magnetic field of the magnet is closed, and no magnetic repulsive force is generated between the stator magnet and the rotor magnet; when the motion is controlled by the control system The magnetic material body is quickly removed, causing a large repulsive force between the stator magnet and the rotor magnet.

The body of magnetically permeable material is a slider composed of a magnetically permeable material.

The sliding or rotating of the body of the magnetically permeable material in the slide is composed of a combination of a cam groove, a swing rod, an electromagnetic, a light sensing device and the like to form a control system to control the sliding or rotating of the body of the magnetic material.

The stator is magnetically aligned with the magnetic poles of the magnets on the rotor.

The stator and the magnet poles on the rotor are magnetically corresponding to each other.

The drive shaft and the sleeve are agitated by a shaft key or a flange.

The push-pull mechanism is a link push-pull mechanism or a hydraulic push-pull mechanism.

The connecting rod pushing and pulling mechanism is composed of a crank, a fulcrum and a flail, and the end of the connecting rod has a shifting fork, and the supporting point is movably connected to the supporting seat, and the supporting seat is fixed on the casing. The drive shaft has a fan wheel at one end and an output wheel at the other end of the drive shaft.

The number of magnets in which the stator magnet and the rotor magnet are closely arranged in a fixed manner is combined with at least two or more magnets to form different powers.

The invention has reasonable structure, convenient use, cleanness and no pollution, and can be widely used in power equipment such as automobiles and ships. DRAWINGS

Fig. 1 is a schematic view showing the spatial distribution of the magnetic field of the stator and the magnet near the front and the position of the magnet; Fig. 2 is a schematic view showing the spatial distribution of the magnetic field and the position of the magnet when the stator and the rotor magnet are completely corresponding;

Figure 3 is a schematic view showing the position of the magnetically permeable material body when it is about to leave the stator and the rotor magnet when the stator and the rotor magnet are completely corresponding;

Figure 4 is a schematic diagram showing the spatial distribution of magnetic lines of force and the position of the magnet when the stator and rotor magnets do not correspond exactly;

5 is a schematic view showing the spatial distribution of the magnetic field lines and the position of the magnets before the stator and the rotor magnet are separated; FIG. 6 is a schematic structural view of the present invention;

Figure 7 is a cross-sectional view taken along line A-A of Figure 6;

Figure 8 is a cross-sectional view taken along line B-B of Figure 6. detailed description

The present invention will be further described below in conjunction with the accompanying drawings:

Figure 1 Figure 5 is a schematic diagram of the principle of the present invention. As is known, the magnets are different in polarity, and the magnetic lines of force travel from the N pole through the shield to the S pole. When the two magnets are close to each other, they repel each other, and when the polarities are close to each other, they attract each other. When one of the two magnets corresponds to the same polarity surface, the other one is fixed, and the other magnet is subjected to a certain repulsive force when it moves close to the fixed magnet, and also receives a certain repulsive force when leaving the fixed magnet; for the moving magnet , when it approaches or leaves the fixed magnet The sum of the interacting magnetic repulsions is equal to zero. In order to solve the problem that the sum of magnetic repulsion is equal to zero, the problem can be solved by the principle shown in FIGS. 1 to 5. In Fig. 1, the stator magnet 2 is fixed, the rotor magnet 12 is moved in the V direction, the magnetic material body 15 is located between the stator magnet 2 and the rotor magnet 12, and the annular holder 1 is also a magnetically permeable material. When the rotor magnet 12 approaches the stator magnet 2, due to the shielding of the body 15 of the magnetic material, the magnetic lines of force of the stator magnet 2 all pass through the body 15 of the magnetic material, and return to the stator magnet 2 via the annular bracket 1 and the stator magnet 2 There is no interaction with the rotor magnet 12, and there is no magnetic repulsion between the stator magnet 2 and the rotor magnet 12.

In Fig. 1 and Fig. 2, when the rotor magnet 12 approaches the stator magnet 2, the magnetic flux of the rotor magnet 12 first passes through the magnetically permeable material body 15, passes through the space and returns to the rotor magnet 12, and the rotor magnet 12 approaches. When the stator magnet 2 reaches the full correspondence, the magnetic lines of force in the rotor magnet 12 mostly pass through the body 15 of the magnetic material, and return to the rotor magnet 12 through the space. The rotor magnet 12 has no interaction with the stator magnet 2, and the pair of rotor magnets 12 The stator magnet 2 also does not generate a magnetic repulsive force, but the rotor magnet 12 is attractive to the magnetically permeable material body 15, and the acceleration rotor magnet 12 moves toward the magnetic material body 15, as shown in Figs.

In FIG. 3, when the rotor magnet 12 moves away from the stator magnet 2 from the completely corresponding direction to the incomplete corresponding direction, the magnetically permeable material body 15 is rapidly moved away from the stator magnet 2, and the magnetic lines of force of the rotor magnet 12 and the stator magnet 2 are formed in the space. As shown in Fig. 4 and Fig. 5, the interaction between the rotor magnet 12 and the stator magnet 2 generates a repulsive force, and the stator magnet 2 is fixed due to the fixation, and the rotor magnet 12 is moved by the magnetic repulsion received. The above method solves the problem that the sum of magnetic repulsions is equal to zero, which is mainly due to the fact that magnetic lines of force prefer to pass through the most easily permeable magnetically permeable material. The stator magnet 2 for the rotor magnet 12, the magnetic field line 23 of the stator magnet 2 is completely enclosed by the magnetic material body 15 in the magnetic material body 15 and passed through the magnetic material body 15, and returned through the gap and the magnetic conductive material. In the stator magnet 2; since the magnetic permeability and the volume cross section of the magnetic material body 15 are sufficiently used, most of the magnetic lines 23 of the rotor magnet 12 also pass through the magnetic material body 15, and return to the rotor magnet 12 through the space, so the magnetic lines of force 23 is also enclosed in the body 15 of the magnetically permeable material, there is no interaction between the stator magnet 2 and the rotor magnet 12, and there is no magnetic repulsion; In the case of the stator magnet 2, the magnetic field of the magnetic material 15 巳 leaves the stator magnet 2, and the magnetic field lines 23 of the stator magnet 2 and the rotor magnet 12 are suddenly released in space due to the loss of the most easily permeable magnetic material body 15, and the stator magnet 2 The distance between the faces of the same polarity of the rotor magnet 12 remains unchanged, and the magnetic field lines 23 of the stator magnet 2 and the rotor magnet 12 are returned from the N pole to the S pole through the space, and the magnetic field of the stator magnet 2 and the rotor magnet 12 are maintained. The interaction also causes the sudden increase in the density of the magnetic lines of force 23, as in the case of a normally flowing liquid in a pipe, as the liquid flow pressure increases as it is smaller than the diameter of the original flow pipe. A large repulsive force is generated, and the rotor magnet 12 is moved by the magnetic repulsive force.

As shown in Fig. 1 to Fig. 5, we arrange n magnets in the same polarity and fixed on the bracket or casing formed by the annular bracket 1 to form the stator, and arrange the il magnets in the same polarity and the stator magnets. 2 The same polarity surface is fixed relative to the fixing frame composed of the magnetic conductive material and the sleeve bracket 6 together to form the rotor, and the sleeve bracket 6 and the rotating shaft 17 are slidably engaged, and one end of the sleeve is provided with the sliding groove 7 and the control is retracted. The shifting fork 5 is in sliding contact, and the shifting fork 5 is hingedly connected with the connecting jaw 9 by the external crank handle 10 of the casing to control the retreat; the other end of the rotating shaft 17 is fixed with a cam 19, and the cam '19 is rotated by the rotating shaft 17 The swinging of the rod 20 controls the magnetic material body 15 to oscillate, the rod 20 swings back and forth, and the magnetic material body 15 reaches the polar surface of the stator magnet 2, and all of the corresponding faces are shielded and then retracted, and the cam 19 rotates the magnetic material 15 to advance and retreat. The swinging rod 20 is rotated and fixed to the rocker bracket 16 fixed to the casing, so that the above components are assembled and integrated to form a magnetic repulsion machine, as shown in FIG. When the crank 10 and the connecting rod 9 propel the rotor and the rotor magnet 12 approach the position corresponding to the stator magnet 2 and gradually reach the corresponding position of the stator magnet 2, the rotor magnet 12 fixed on the rotor is gradually rotated to the maximum speed due to the magnetic repulsion. When the crank 10 and the Lianxuan 9 are pulled back to exit the rotor and gradually move away from the stator, the rotor magnet 12 is no longer subjected to the magnetic repulsion and gradually decelerates to stop the rotation, realizing the magnetic motor to start working and stop working freely.

Is the energy of the magnetic repulsion machine constant? We know that permanent magnets, after magnetization, are the energy of the permanent magnets themselves, and this energy is very strange. Its magnetic field lines always start from the N pole, and the magnetic lines are no matter what medium passes through. Many roots are back to the S pole, this is It means that the energy of the permanent magnet can be used repeatedly, or the permanent magnet can reduce the magnetic energy and demagnetize for a long time once it has reduced energy. Of course, under abnormal conditions, the magnet may be demagnetized due to excessive temperature, strong external magnetic field, or damage to the magnetic domain. We have two permanent magnets with a small energy difference that are close to the same pole. The magnetic repulsion increases as the rotor magnet 12 approaches the stator magnet 2, repeating the repetition, and there is no repulsion, which means The magnetic field of the magnet is very conservative. It will not lose energy due to the proximity of the external magnetic field or the magnetic field line will be distorted (as shown in Figure 4 and Figure 5, the distribution of magnetic lines in space) will return to the original magnet; as shown in Figure 4, the stator The magnetic field lines 23 of the magnet 2 and the rotor magnet 12, where they interact, the magnetic lines of force 23 are only squeezed, and the magnetic lines 23 in this space repel each other and are squeezed back to the original magnet. This phenomenon is only permanent magnets. We must make full use of and develop this field source. Then, how much energy does a magnetic repulsion machine have? If there are n magnets that interact with each other, the external output power of the magnetic repulsion machine is equal to the interaction energy between n permanent magnets minus the weight of the rotor and the body of the magnetic material of n pieces of permanent magnets. The attraction of the 15 generated by the mill 4 is the energy lost. That is to say, from a magnetic repulsion machine, the energy conservation, from the external phenomenon of the magnetic repulsion machine, the sensory energy is not conserved, the key is that we do not want the energy of the 4 bar magnet to be lost, and the permanent magnet magnetic field line is very special, not After use, there is no more, like the oil is burned and converted into other substances, the magnetic field lines can be repeated without changing their own properties, so the magnet energy determines the energy of the magnetic repulsion machine, and the magnetic repulsion power output energy plus its own energy consumption. Equal to the energy acting between the magnets.

6 to 8 are schematic views of the structure of the present invention. As shown in FIG. 6, FIG. 7, and FIG. 8, the magnetic repulsive power machine includes a base 14, a casing 21, a push-pull mechanism and a transmission shaft 17; and the transmission shaft 17 has a sleeve 8 which is alived. One end of the sleeve 8 has a slot 7 connected to the push-pull mechanism, and the bottom end of the sleeve 8 has a fixed circumferential sleeve bracket 6 . The sleeve bracket 6 has a fixing bracket 3 at the periphery thereof, and the fixing bracket 3 has at least One or more permanent magnets 12 are arranged in the same polarity, the casing 21 is fixed with an annular bracket 1 , and the annular bracket 1 has at least one permanent magnet 2 arranged in the same polarity, the fixing frame 3 and the fixing frame 3 The coaxial magnets 12 arranged in the same direction constitute a rotor, and the annular bracket 1 and the magnets of the same polarity arranged in the annular bracket 1 form a stator, and the magnetic poles of the magnets on the stator and the rotor are arranged in the same direction and are magnetic The poles correspond to each other; the annular bracket 16 fixed on the stator or the inner side of the casing has at least one swinging rod 20, and the swinging rod 20 is abutted on the body 15 of the magnetic material, the body 15 of the magnetic material and other materials Sliding or activating in the track 13 for rotation; or a mechanism for controlling the magnetically permeable material body 15 such as the electromagnetic groove, the electromagnetic induction device and the movable pendulum rod 20 on the rotating shaft 17 to slide or rotate Or the fixing bracket fixedly mounted on the rotating shaft 17 has at least one track or a round seat, and the magnetic material body 1 and other materials are integrally joined to slide in the track or live on the round seat, and the swing rod is alive. Rotor shaft fixing frame, one end of the swinging rod is connected to the body 15 of the magnetic conductive material, and the other end is fixed on the stator or the cam groove fixed on the inner side of the casing, electromagnetic, optical sensing device and the like, and the magnetic permeability is controlled. The material body slides or rotates; the rotor magnet 12 and the stator magnet 2 have the same polarity, and the stator magnet 2 and the rotor magnet 12 have the same polarity corresponding surface, and the control system guides the movement process before the movement process is completely opposite. Magnetic material body 15 Wherein the magnetic field line of the magnet is turned on, so that the magnetic field of the magnet is closed, and no magnetic repulsive force is generated between the magnet and the magnet; when the corresponding surface of the same polarity of the magnetic pole of the stator magnet 2 and the rotor magnet 12 is completely opposite to the opposite phase, the control is controlled by The system rapidly removes the magnetically permeable material body 15 to cause a large repulsion between the stator magnet 2 and the rotor magnet 12. One end of the sleeve 8 has a slot 7 connected to the push-pull mechanism, and the push-pull mechanism is a push-pull mechanism or a hydraulic push-pull mechanism. The link push-pull mechanism can be composed of a crank 10, a fulcrum 11 and a connecting rod 9, the end of the connecting rod 9. With a shifting fork 5, the pivot point 1 1 is movably connected to the support base, the support base is fixed on the casing 21, and the shift fork 5 cooperates with the slot 7 of the sleeve 8, so that the sleeve 8 together with the sleeve bracket 6 and the sleeve are fixed The rotor magnets 12 on the cartridge holder 6 can axially correspond or stagger the stator magnets 2, thereby rotating or stopping the rotation of the rotor. The sleeve 8 is connected to the rotating shaft 17 via a shaft key 22, the drive shaft 17 has a fan wheel 18 which can be ventilated and ventilated, and the other end of the drive shaft 17 has an output wheel 4. The stator magnet 2 and the rotor magnet 12 can be combined in different numbers, 2, 4, 8, 30, 80 or even more to increase the output power to meet the needs of different places and different powers. Of course, the stator magnet 2 and the rotor magnet 12 may be unipolar (N-pole or S-pole) arranged in the same direction, and the magnets may correspond to each other; or may be bipolar (N-pole and S-pole) isotropically arranged, and the magnetic equivalents.

The working process is as follows: When operating the control link push-pull mechanism, the shift fork 5 pushes the sleeve 8 to make the rotor As the rotor magnet 12 and the stator magnet 2 approach the same magnetic pole corresponding surface, the rotor begins to be gradually rotated by the magnetic repulsion force and drives the cam 19 to rotate, and one end of the movable swing lever 20 swings in the cam groove 19 as the cam rotates. The other end of the flyweight swing lever 20 drives the magnetizer slider 15 to slide between the stator magnet 2 and the rotor magnet 12 on the rail 13, and when the rotor magnet 12 approaches the stator magnet 2, the magnetizer slider 15 enters the two magnets. Between when the rotor magnet 12 is away from the stator magnet 2, the magnetizer slider 15 quickly comes out between the two magnets, so that the rotor magnet 12 corresponds to the stator magnet 2 at a certain position, and is constantly rotated by the magnetic repulsion; The fork 5 pushes the sleeve 8 to increase the working area of the rotor magnet 12 corresponding to the corresponding surface of the stator magnet 2, and the rotor rotational speed also gradually increases; when the rotor magnet 12 and the isotropic magnetic pole face of the stator magnet 2 completely correspond, the rotor magnet 12 and The magnetic field force between the stator magnets 2 is the largest, and the rotor magnet 12 has the largest force at this time. The magnetic repulsion power machine performs work on the external output; Sliding system link mechanism, the rotor magnet 12 away from the stator magnet 2, so that no magnetic force of the rotor magnet interaction, will gradually decelerate the rotor and the stator magnet 12 between the two, eventually stops rotating, the magnetic repulsive power machine accordingly stops acting.

Claims

Rights request

1. A magnetic repulsion machine comprising a base, a casing, a push-pull mechanism and a drive shaft, wherein: the transmission shaft has a live sleeve, and one end of the sleeve has a slot connected with the push-pull mechanism, and the sleeve The other end of the cylinder has a fixed circumferential sleeve bracket, and the sleeve bracket has a fixing bracket at the periphery thereof, and at least one permanent magnet is arranged in the same polarity in the fixing bracket, and the casing is fixed with a ring bracket, the ring The at least one permanent magnet is arranged in the same polarity direction in the bracket, the magnets in the same direction and the same polarity arranged in the fixing frame form a rotor, and the annular bracket and the same-polarity magnet arranged in the annular bracket The stator is formed, and the magnets on the stator and the rotor are magnetically identical to each other; the annular bracket fixed on the stator or the inner side of the casing has at least one track or a round seat, and the rotor shaft is fixed with a cam groove, electromagnetic, The light-sensing device and the movable pendulum control mechanism and the other materials are integrally connected and slid or slid in the track to slide or rotate on the round seat, or the rotor shaft fixing bracket At least one or more rails or round seats, the swinging rod is abutted on the rotor shaft fixing frame, one end of the swinging rod is abutted on the body of the magnetic conductive material, and the other end is fixed on the stator or the cam groove fixed on the inner side of the casing, In the electromagnetic, optical sensing device, etc., the control magnetic material body and other materials are integrally slid in the track to slide or abut on the round seat; the rotor magnet and the stator magnet have the same polarity, and the stator magnet and the rotor magnet are the same Before the polarity corresponding surface is incompletely corresponding to the motion process in which the corresponding phase is close, the magnetic field line of the magnet is turned on by the control system by the magnetic conductive material body, so that the magnetic field of the magnet is closed, and no magnetic repulsive force is generated between the stator magnet and the rotor magnet; When the poles of the same polarity of the stator magnet and the rotor magnet are completely opposite to each other, the control system rapidly removes the body of the magnetic material, causing a large repulsive force between the stator magnet and the rotor magnet. .

2. A magnetic repulsive power machine according to claim 1, wherein: said magnetically permeable material body is a slider composed of a magnetically permeable material. '

3. The magnetic repulsive power machine according to claim 1, wherein: the sliding or rotating of the magnetically permeable material body in the slide is controlled by a combination of a cam groove, a swing rod, an electromagnetic, an optical sensing device, and the like. The system controls the body of the magnetically permeable material to slide or rotate.

4. The magnetic repeller according to claim 1, wherein: said stator and rotor are magnetic The body magnetic poles are magnetically aligned.

The magnetic repeller according to claim 1, wherein the stator and the magnetic poles on the rotor are magnetically corresponding to each other.

6. The magnetic repulsive power machine according to claim 1, wherein: the transmission shaft and the sleeve are agitated by a shaft key or a flange.

The magnetic repulsive power machine according to claim 1, wherein the push-pull mechanism is a link push-pull mechanism or a hydraulic push-pull mechanism.

8. The magnetic repulsive power machine according to claim 7, wherein: the link pushing and pulling mechanism is composed of a crank, a fulcrum and a connecting rod, the end of the connecting rod has a shifting fork, and the supporting point is movably connected to the supporting seat, and the supporting base Fixed to the case.

9. The magnetic repulsive power machine according to claim 1, wherein: the transmission shaft has a fan wheel at one end, and the other end of the transmission shaft has an output wheel.

10. The magnetic repulsive power machine according to claim 1, wherein: the stator magnet and the rotor magnet are fixedly arranged in a total amount of at least two or more magnets to form different dynamic forces.