WO2008154864A1 - Appareil d'énergie cinétique magnétique - Google Patents

Appareil d'énergie cinétique magnétique Download PDF

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Publication number
WO2008154864A1
WO2008154864A1 PCT/CN2008/071337 CN2008071337W WO2008154864A1 WO 2008154864 A1 WO2008154864 A1 WO 2008154864A1 CN 2008071337 W CN2008071337 W CN 2008071337W WO 2008154864 A1 WO2008154864 A1 WO 2008154864A1
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WIPO (PCT)
Prior art keywords
magnetic
magnet
reciprocating
kinetic energy
force
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PCT/CN2008/071337
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English (en)
Chinese (zh)
Inventor
Ru Yao
Original Assignee
Ru Yao
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Publication date
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Publication of WO2008154864A1 publication Critical patent/WO2008154864A1/fr

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Classifications

    • HELECTRICITY
    • H02GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
    • H02KDYNAMO-ELECTRIC MACHINES
    • H02K49/00Dynamo-electric clutches; Dynamo-electric brakes
    • H02K49/10Dynamo-electric clutches; Dynamo-electric brakes of the permanent-magnet type

Definitions

  • the present invention relates to a magnetic kinetic energy device, and more particularly to a magnetic field energy balance and conversion device in which a plurality of sets of magnets and a magnet are combined.
  • the magnetic poles of the two magnets are perpendicular to the same center line, one of the magnets is rotated in the center of the center line, and the other magnet does not rotate to reciprocate with the center line as the moving direction.
  • the magnet and the magnetic pole of the magnet are from the same to the opposite, one magnet will rotate as the magnetic pole and the other magnet attracts, while the same-sex repulsive change to the opposite-phase attracting; then from the opposite to the same process, a magnet needs to be rotated as the magnetic pole Repelling another magnet, and the opposite phase attracts the same-sex repulsive; the magnet and the magnet pole are the same to the opposite and the opposite to the same medium force change is the common magnetic force force conversion, and also the performance of the two common magnetic field forces, The common magnetic field is the repulsive force after the common magnetic field is converted. Coupled with the same-sex magnetic pole force of the same magnetic line of the two magnets, these three forces are the common magnetic force of the magnet and the magnet.
  • the motor changes the magnetic field pole after the rotor crosses the equilibrium position, and the common magnetic field absorbs the repulsion force to make the rotor rotate rapidly in the stator.
  • the power consumption is converted into magnetic energy and the magnetic field generates kinetic energy. How much power is used by the motor to generate kinetic energy .
  • the generator is constantly rotating the magnetic pole.
  • the generator uses the water level and the high bottom drop force to convert into electric energy, and the internal combustion engine burns the chemical energy in the fuel.
  • the conversion into kinetic energy these are the performance of local indirect energy conversion in the atmosphere.
  • the conversion of energy should be viewed from the large circulation system in the atmosphere.
  • Hydropower is the energy of nature, which causes the difference between the high and the bottom to flow. It is actually converting the energy of nature into electricity, and the chemistry of burning fuel.
  • the energy of the Earth's strata keeps the fuel flowing. It is also transforming the energy of the Earth's strata into kinetic energy.
  • Generators and internal combustion engines are just an indirect conversion device that converts energy in the atmosphere into kinetic energy. If there is no energy in the atmosphere to do work. Indirect kinetic energy will not be realized.
  • the technical problem to be solved by the present invention is to provide a common magnetic field force of a magnetic field of a magnet and a magnet through the device, so that the unprofitable energy is balanced in the device, and the beneficial energy is directly converted into the kinetic energy of the engine device, or the generator device.
  • the present invention provides a magnetic kinetic energy device, wherein the device is provided with at least two sets of magnetic kinetic energy mechanisms; the magnetic kinetic energy mechanism is provided with at least two sets of magnets combined with a magnet, the magnet
  • the combination with the magnet includes a reciprocating magnet (4) and a rotating moving magnet (6), and the reciprocating magnet (4) is provided with a power output device (3), and the rotating moving magnet (6) is provided with a driving (7).
  • the reciprocating magnets of the at least two sets of magnets combined with the magnets are connected by a connecting rod (5).
  • the adjacent magnetic kinetic energy mechanisms on the device are connected to each other by a drive (7) provided on the rotary moving magnet (6), and the drive mechanism is connected by a shaft (12).
  • the magnetic poles of the reciprocating magnet (4) and the rotating moving magnet (6) are perpendicular to the reciprocating direction of the reciprocating magnet (4), the reciprocating magnet (4) and the rotating moving magnet ( 6) On the same axis.
  • the magnetic poles of the reciprocating magnet and the rotating moving magnet of the first set of magnets and the magnet are the same, and the reciprocating magnet and the rotating of the second set of magnets and the magnet are combined.
  • the magnetic poles of the moving magnets are opposite, the third group is the same as the first group, the fourth group is the same as the second group, and so on; or the magnetic poles of the reciprocating magnet and the rotating moving magnet of the first group of magnets and the magnet are opposite,
  • the reciprocating magnets of the two sets of magnets and the magnets are the same as the magnetic poles of the rotating moving magnets, the third group is the same as the first group, the fourth group and the second group are the same, and so on.
  • adjacent rotating moving magnets (6) are sequentially different by a certain angle, or the magnetic pole directions of the adjacent reciprocating magnets (4) are sequentially different by a certain angle, and the angle is 180 degrees and the quotient of the number of sets of the magnetic kinetic energy mechanism in the apparatus.
  • the power output device is a magnetic kinetic energy engine device, or a magnetic kinetic energy generator device (1), or a device in which a magnetic kinetic energy engine and a generator are integrated.
  • the generator device (1) performs linear magnetic line cutting in a magnetic field.
  • a flywheel device is provided in the device.
  • At least two sets of magnetic kinetic energy mechanisms are provided in the device, and the magnetic kinetic energy mechanism combination is the at least two sets of magnetic kinetic energy mechanisms.
  • the rotational motion magnet of the first group of magnets and the magnet and the magnetic pole of the reciprocating magnet are opposite to the same, At this time, the opposite-phase attracting changes to the same-sex repulsive, while the rotating magnet of the second group of magnets combined with the magnet and the magnetic pole of the reciprocating magnet are from the same to the opposite, when the same-sex repulsive change to the opposite-phase attracting, the third set of magnets and magnets
  • the combination is the same as the first group, the fourth group and the second group are the same, and so on.
  • the at least two reciprocating magnets simultaneously perform a movement in one direction simultaneously with the at least two common magnetic field forces of the combination of the at least two sets of magnets and the magnet; when the driving of the magnetic kinetic energy mechanism continues to rotate synchronously, the rotating moving magnet is at 180- In the 360 degree process, the rotating magnets of the first group of magnets and the magnets and the magnetic poles of the reciprocating magnets are from the same to the opposite, when the same-sex repulsive change is changed to the opposite-phase attraction, and the rotating motion of the second group of magnets combined with the magnets
  • the magnetic poles of the magnet and the reciprocating magnet are reversed to the same, and the opposite phase attracts the same polarity, the third group of magnets and the magnet combination are the same as the first group, the fourth group and the second group are the same, and so on.
  • the at least two reciprocating magnets simultaneously perform a movement in the other direction while the at least two common magnetic fields of the combination of the at least two sets of magnets and the magnet are simultaneously; the rotating and rotating magnets are continuously synchronized, and the reciprocating magnets are continuously stopped. Do a synchronous round trip.
  • the present invention is that the magnetic poles of the combination of the magnet and the magnet are perpendicular to the same center line, and one of the magnets is rotated in the center of the center line, and the other magnet does not rotate, and the center line is moved in the direction of motion, in the atmosphere.
  • the magnetic poles of at least two sets of magnets combined with the magnets are from the same to the opposite and opposite to the same geomagnetic field common magnetic field force, through the magnetic kinetic energy device, the unbalanced geomagnetic energy is balanced in the device, and the beneficial energy is directly converted into the engine device.
  • Kinetic energy, or kinetic energy of a generator unit, or engine The kinetic energy of the unit with the generator.
  • Figure 1 is a schematic view of the structure of the present invention
  • Figure 2 is a schematic view showing the repulsation of two magnets
  • Figure 3 is a schematic view of the attraction of two magnets
  • FIG. 4 is a schematic view showing the working principle of the two sets of magnetic field and magnetic field combination of the present invention.
  • Figure 5 is a schematic view showing the working principle of the two sets of magnetic field and magnetic field combination of the present invention.
  • Figure 6 is a schematic diagram of the working principle of the heteropolar shunt force and the heteropolar reaction force completely;
  • Figure 7 is a schematic view showing the operation of the synchronous reciprocating moving magnet in the same period of the same distance reciprocating motion
  • Figure 8 is a schematic view of the driving mechanism 7 of Figure 7 rotated to 36 degrees
  • Figure 9 is a schematic view of the drive mechanism 7 of Figure 7 rotated to 72 degrees;
  • Figure 10 is a schematic view of the drive mechanism 7 of Figure 7 rotated to 108 degrees;
  • Figure 11 is a schematic view of the drive mechanism 7 of Figure 7 rotated to 144 degrees;
  • Figure 12 is a schematic view of the drive mechanism 7 of Figure 7 rotated to 18 degrees;
  • Figure 13 is a schematic view of the drive mechanism 7 of Figure 7 rotated to 9 degrees;
  • Figure 14 is a schematic view of the drive mechanism 7 of Figure 7 rotated to 27 degrees;
  • FIG. 15 is a schematic diagram of a synchronous reciprocating magnet cross-circulating equidistant reciprocating motion
  • FIG. 16 is a schematic diagram of adding a set of magnetic kinetic energy mechanisms in FIG.
  • Figure 17 is a schematic view showing a combination of a magnetic field and a magnetic field in Fig. 16 and a set of driving mechanisms;
  • Fig. 18 is a schematic view showing a magnetic kinetic energy mechanism in which a rotating moving magnet is composed of a magnet;
  • Fig. 19 is a view showing the stationary state in which the rotary moving magnet of Fig. 18 is rotated by 180 degrees.
  • a reciprocating magnet is referred to as a reciprocating magnet
  • a rotating moving magnet is abbreviated as a vibrating magnet
  • a rotating magnet 6 and a vibrating magnetic 9 are synchronously rotated, and the rotating magnetic 6 and the rotating magnetic 9 are referred to as synchronous rotation.
  • Moving magnet Round-trip magnetic 4 and reciprocating magnetic 11
  • the reciprocating magnetic 4 and the reciprocating magnetic 11 are referred to as synchronous reciprocating magnets
  • the first group of magnetic kinetic energy mechanisms is referred to as the first group, and the other groups of magnetic kinetic energy mechanisms are also the same.
  • G is the reciprocating distance
  • 1 is the generator device
  • the quality and specifications are the same
  • the quality and specifications of the reciprocating magnetic 4 and the reciprocating magnetic 11 are the same, or the quality and specifications of the rotating magnetic and reciprocating magnetic are the same.
  • the direction of the magnetic poles to the magnetic 4, the gyromagnetic 6, the gyromagnetic 9 and the reciprocating magnetic 11 is perpendicular to the direction of the reciprocating motion thereof, and the reciprocating magnetic 4, the gyromagnetic 6, the gyromagnetic 9 and the reciprocating magnetic 11 are on the same axis.
  • the gear drive 7 provided on the gyromagnetic 6 is driven by a gear 7 to make the two gyromagnetics perform a synchronous rotational motion.
  • the reciprocating magnetic 4 and the reciprocating magnetic 11 are synchronously reciprocated by the magnetic pole coordination and the connecting rod 5, and the two common magnetic field repulsive forces of the reciprocating magnetic 4 and the rotating magnetic 6, the reciprocating magnetic 11 and the rotating magnetic 9 are concentrated in the synchronous reciprocating motion.
  • the magnet is also concentrated on the power output device 3 provided on the reciprocating magnet 4 or on the power output device 10 provided on the reciprocating magnet 11, so that the work of the synchronous reciprocating magnet to move back or forth is passed through the power output device 3 or
  • the power output device 10 directly converts the kinetic energy of the engine device, or the kinetic energy of the generator device, or the kinetic energy of the engine and the generator in one device.
  • the gyromagnetic 6 and the reciprocating magnetic 4 are opposite to each other.
  • the gyromagnetic 9 is the same as the reciprocating magnetic 11 magnetic pole, and during the rotation of the gear driving 7 by 180 degrees, The gyromagnetic 6 and the reciprocating magnetic 4 magnetic poles are reversed to the same, at which time the anisotropic absorbing is changed to the same repulsion, while the gyromagnetic 9 and the reciprocating magnetic 11 magnetic poles are from the same to the opposite, that is, the same-sex repulsive change to the opposite sex attracting, which
  • the time-synchronous reciprocating magnet performs a movement in one direction simultaneously under the action of the common magnetic force of the gyro 6 and the reciprocating magnetic 4, the gyromagnetic 9 and the reciprocating magnetic 11: when the gear drive 7 is rotated to 180 degrees, then the rotation Magnetic 6 and reciprocating magnetic 4
  • the rotating magnetic 6 and the reciprocating magnetic magnetic pole are The same to the opposite, that is, from the same-sex repulsive change to the opposite-sex attraction, while the gyromagnetic 9 and the reciprocating magnetic 11 magnetic pole are opposite to the same, at this time, the opposite-phase attraction changes to the same-sex repulsive, and then the synchronous reciprocating magnet is in the gyromagnetic 6 With round-trip magnetic 4,
  • the magnetic field 9 and the reciprocating magnetic force 11 simultaneously perform a return motion in one direction and return to FIG. 4, and so on.
  • the gear drive 7 continuously rotates and rotates the moving magnet, the reciprocating magnet is in two common magnetic fields. At the same time, the force is continuously synchronized to make a round-trip motion.
  • the common magnetic field of the earth's magnetic field is extremely strong:
  • Figure 2 shows the magnetic poles of the two magnets (the two poles and the magnetic poles refer to the magnet south pole S and the north pole N).
  • the opposite magnets are oppositely attracted. This force is the common magnetic attraction of the magnet and the magnet.
  • Figure 3 shows the same magnetic field repulsion of the two magnet poles. This force is the common magnetic repulsion of the magnet and the magnet.
  • Zhou Ji suction and Zhou Ji repulsive force are collectively referred to as Zhou Lili.
  • the gyromagnetic 9 rotates the magnetic pole with the center line 16 from the vertical through the opposite to the magnetic reciprocating magnetic 11 magnetic After the pole vertical balance line, the change of the peripheral suction force into the circumferential repulsive force is the conversion of the common magnetic field force.
  • This process is referred to as the reciprocating magnetic field 11 being squirmed by the gyromagnetic 9; the gyromagnetic 6 is rotated by the center line 16 from the vertical through the same After crossing the vertical balance line of the magnetic 4 magnetic pole, the change of the circumferential repulsion into the circumferential suction is also the conversion of the common magnetic force.
  • This process is referred to as the reciprocating magnetic 4 and the gyromagnetic 6 suction.
  • the two converted circumferential repulsion forces simultaneously force the force to reciprocate the moving magnet to work vigorously on the moving distance G.
  • the magnetic energy consumed by this process of repulsion work is quickly supplemented by the magnetic field of the magnet by the geomagnetic field.
  • the suction and repulsive force after the conversion of Zhou Lili is a kind of push-pull performance.
  • the common magnetic field of the earth's magnetic field is different:
  • the magnetic poles When the magnetic poles are from the same to the opposite balance line, one magnet will rotate as the magnetic pole and the other magnet will not rotate with the external force during the suction process, that is to say, the common magnetic force of the magnet and the magnet itself rotates to change the magnetic pole, which can replace
  • the external force rotating magnetic pole is from the same to the opposite.
  • This same rotating force as the external force rotating direction is the common magnetic field rotating force of the magnet and the magnet, which is referred to as the heteropolar smoothing force.
  • the power generated during the rotation process is also referred to as the heteropolar smoothing.
  • the opposite-pole and the opposite-pole force are collectively referred to as the different-pole force.
  • the forward-reverse rotation of the different-pole force is a manifestation of the rotating work.
  • the magnetic energy that needs to be consumed during the rotation of the work is quickly charged by the earth's magnetic field to the magnetic field of the magnet.
  • the force that needs to be overcome by rotating the left or right side of the two small magnets by the two hands in the process of the two small magnets from the opposite to the same is the common magnetic field rotating force of the two small magnet poles from the same to the opposite. Therefore, the combination of the magnet and the magnet in the combination of the magnet and the magnet is the same magnetic field force of the magnet and the magnet, so the magnetic pole of one magnet and the other magnet rotate from the same to the opposite and then from the opposite to the same, two When the distances of the magnets are equal, the difference of the poles of the poles not only changes the direction of the magnetic pole, but also is equal to the reaction force of the opposite poles.
  • the gyromagnetic 9 repels the reciprocating magnetic force 11 to generate a reciprocal reaction force and a repulsive force after a circumferential force conversion, and at the same time, the gyromagnetic 6 suction reciprocating magnetic force 4 generates a circumferential force conversion after the suction force and a heteropolar force;
  • the gyromagnetic 9 and the reciprocating magnetic 11 are from the same to the opposite.
  • the gyromagnetic 6 again repels the reciprocating magnetic force 4 to generate a reciprocal reaction force and a repulsive force after a circumferential force conversion, and the gyromagnetic 9 suction magnetic reciprocating magnetic force 11 produces a circumferential force conversion after suction and a different polarity.
  • the force of the circumferential force is the same.
  • the force-receiving magnet can be composed of 1 magnet or 2 magnets. It is a kind of rotational force, so the four poles of the opposite poles are subjected to the force of the gyro and the gyro.
  • the magnet of the different force is the same.
  • the magnet can be composed of 1 magnet or 2 magnets, as shown in Fig. 4. And Figure 18 shows. Figure 19, Figure 18 and Figure 4, Figure 5 are the same.
  • the external force changes the opposite-pole reaction force to make the magnet and the magnet poles from the opposite to the same, and the peripheral suction force is converted into the circumferential repulsion; no external force is required to rotate the different-pole force so that the magnet and the magnet poles are from the same to the opposite, and the circumferential repulsion Convert to weekly suction.
  • Both the circumferential force and the different-pole force are the common magnetic field forces of the geomagnetic field in which the magnets and the magnets are opposite from the opposite to the same and the same to the opposite.
  • the transformation of the heteropolar reaction force into a heteropolar force is a conversion when the magnetic pole of the rotating moving magnet crosses the same balance line of the magnetic pole of the reciprocating moving magnet, and the transformation of the heteropolar force into the opposite pole is the magnetic pole of the rotating moving magnet crossing the magnetic pole of the reciprocating moving magnet. Conversely, the balance line is converted.
  • the different poles are the poles of the rotating motion magnet and the reciprocating magnet from the same to the opposite.
  • the opposite pole force is the magnetic pole of the rotating motion magnet and the reciprocating magnet from the opposite to the same; the circumferential suction is the rotary motion.
  • the magnetic pole of the magnet and the magnetic pole of the reciprocating magnet are from the opposite to the perpendicular, and the circumferential repulsive force is such that the magnetic pole of the rotating moving magnet and the magnetic pole of the reciprocating magnet are from the same vertical to the vertical, so the peripheral absorbing force is the magnetic pole of the rotating moving magnet.
  • the magnetic pole of the reciprocating moving magnet is vertically balanced when it is converted. The bipolar force and the circumferential force rotate the moving magnet clockwise or counterclockwise when the rotating magnet and the magnetic pole of the reciprocating magnet are the same or opposite.
  • the rotating motion magnet and the reciprocating magnet are converted from the opposite to the same and the same to the opposite, and the heteropolar force changes to the opposite pole force and then changes to the heteropolar force.
  • the cyclic change is a heteropolar cis-force conversion.
  • Shun force conversion the simultaneous conversion of these two cycles is an iso-polar force interchange; the cycle repulsive force changes to the cyclone force and then changes to the cycle repulsive force, and so on.
  • the cyclic change is the cycle repellent force conversion, and the circumferential suction force changes into the peripheral repulsive force.
  • the cyclic change that is changed to the circumferential suction and the like is also the conversion of the circumpolar repulsion force.
  • the simultaneous conversion of the two cycles is the weekly force exchange.
  • the magnetic poles of the reciprocating magnet and the rotating moving magnet of the first set of magnets combined with the magnet are the same, and the magnetic poles of the reciprocating magnet and the rotating moving magnet of the second set of magnets combined with the magnet are opposite
  • the third group is the same as the first group, the fourth group and the second group are the same, and so on; or the first group of magnets and the magnet combined with the reciprocating magnet and the rotating moving magnet have opposite magnetic poles, and the second group of magnets and magnets
  • the combined reciprocating magnet and the rotating moving magnet have the same magnetic pole, the third group is the same as the first group, the fourth group and the second group are the same, and so on.
  • This method does not limit whether the reciprocating magnet and the rotating moving magnet are composed of one magnet or two magnets, and it is not limited whether the magnetic poles composed of the two magnets are the same or opposite.
  • the magnetic pole and the gyromagnetic of the reciprocating magnetic body of FIG. The magnetic poles of the same magnetic poles of 6 are repulsive, and the magnetic poles of the magnetic reciprocating magnets 11 and the magnetic poles of the vibrating magnetic flux 9 are opposite, that is, the magnetic poles of the reciprocating magnets 11 and the vibrating magnets 9 are attracted, regardless of whether the magnetic poles of the vibrating magnets 6 and the vibrating magnets 9 are the same or opposite.
  • the method comprises at least two common magnetic fields combined with at least two sets of magnets and magnets by at least two reciprocating magnets connected by the connecting bars when at least two rotating magnets of the at least two sets of magnets and the magnets are synchronously rotated. Respiratory force, simultaneous synchronous movement to the same direction ⁇ 1.
  • the magnetic poles of the adjacent reciprocating magnets are the same, and the magnetic poles of the adjacent rotating moving magnets are sequentially different by a certain angle: or adjacent rotational motion
  • the magnetic poles of the magnets are the same, and the magnetic poles of the adjacent reciprocating magnets are sequentially different by a certain angle.
  • Synchronous reciprocating moving magnets are sequentially circulated in equal distances:
  • the five sets of magnetic kinetic energy mechanisms of Fig. 7 are the same as those of Fig. 4.
  • a plurality of sets of magnetic kinetic energy mechanism adjacent magnets and magnets are combined with a magnet to be provided with a gear drive 7 having the same diameter and closely connected to the drive mechanism 7.
  • the drive mechanism 7 rotates in the device to perform rotational motion and force transmission.
  • 8 is the driving wheel
  • 15 is the white arrow
  • 21 is the transition gear to make the rotary motion
  • the magnets rotate in the same direction, and the rotating moving magnets can be rotated in the same direction by the coordination of the magnetic poles without the need of a transition gear.
  • the five groups are the same to the magnetic 4 poles, and the magnetic poles of the five groups of the gyro 6 are sequentially different by 36 degrees (divided by 180 degrees by the number of the kinetic energy mechanism group 5 equals 36 degrees)
  • the magnetic poles of the first group of reciprocating magnets 4 are the same
  • the five sets of reciprocating magnetic poles 11 are the same
  • the five sets of gyromagnetic 9 magnetic poles are sequentially different by 36 degrees
  • the magnetic poles of the first group of reciprocating magnetic poles 11 are opposite.
  • the magnetic poles of the first set of gyromagnetic 6 and the reciprocating magnetic 4 have reached the same, the magnetic poles of the gyromagnetic 9 and the reciprocating magnetic 11 have reached the opposite direction, and the reciprocating magnetic 4 and the gyromagnetic 6 are completely repelled, and the reciprocating magnetic 11 and the gyromagnetic 9 are completely phased. Suck. Therefore, when the driving mechanism 7 is rotated to 36 degrees, at this time, the second group of the gyromagnetic 6 and the reciprocating magnetic 4 magnetic pole arrive at the same, and the reciprocating magnetic 11 and the gyromagnetic magnetic pole reach the opposite direction, and the reciprocating magnetic 4 and the gyromagnetic 6 are completely opposite.
  • the reciprocating magnetic 11 and the gyromagnetic 9 are completely attracted, as shown in FIG.
  • the driving mechanism 7 is rotated to 144 degrees
  • the magnetic poles 6 of the fifth group of magnetic kinetic energy mechanisms are the same as the magnetic poles of the reciprocating magnetic bodies 4, and the magnetic poles of the reciprocating magnetic bodies 11 and the rotating magnetic bodies 9 reach opposite, while the magnetic reciprocating magnetic field 11 and the rotating magnetic field 9 is completely attracted, and the reciprocating magnetic 4 and the rotating magnetic 6 are completely repelled, as shown in FIG.
  • the drive mechanism 7 continues to rotate 144 degrees to 360 degrees, it is analogously similar to that of Figs. 7 to 11, and one of the figures returns to Fig. 7, that is, the drive mechanism 7 is rotated by 36 degrees.
  • one of the magnetic kinetic energy mechanisms and the adjacent magnetic reciprocating magnetic poles arrive at the opposite and the same at the same time, completely attracting and repulsing, and the non-stop rotary drive mechanism 7 and five sets of synchronous reciprocating
  • the moving magnet continuously circulates at equal distances in the moving distance, as shown in Fig. 7 to Fig. 11.
  • the driving mechanism 7 rotates 180 degrees to generate five sets of synchronous reciprocating moving magnets to move back or forth once, and rotate 360 degrees to generate five sets of synchronous reciprocating moving magnets.
  • the magnetic poles of the adjacent reciprocating magnets are opposite in order, and the magnetic poles of the adjacent rotating moving magnets are sequentially different by a certain angle; or adjacent The magnetic poles of the rotating moving magnets are reversed in order, and the magnetic poles of the adjacent reciprocating magnets are sequentially different by a certain angle.
  • the method makes the synchronous reciprocating moving magnets of at least two sets of magnetic kinetic energy devices on the device cross-rotate and reciprocate at equal distances in the moving distance. As shown in Figure 1.
  • the reciprocating motion of the equidistant distance is sequentially and sequentially repeated, FIG. 1 to FIG. 19
  • the white arrow 15 on the reciprocating magnet indicates the direction of movement of the reciprocating magnet in the structure; and the reciprocating magnetic field is repelled by the magnet behind the arrow while attracting the magnet in front of the arrow tip.
  • the gyromagnetic 6 and the gyromagnetic 9 rotate synchronously, the gyromagnetic 6 and the reciprocating magnetic 4 magnetic pole are perpendicular to the (b) vertical circumferential repulsive force from (a) perpendicular, and the gyromagnetic 6 magnetic pole passes over the reciprocating magnetic magnetic pole (a) After the vertical balance line, the common magnetic force of the reciprocating magnet 4 at the gyro 6 and the reciprocating magnetic 4 and the gyro 6 are converted from the attracting to the repulsive to the complete repulsive motion.
  • This repulsion also hinders the continued rotation of the crankshaft, and also balances the sequential reciprocating motion of the reciprocating motion on the crankshaft of the adjacent kinetic energy mechanism at the moving distance G. It’s very positive to go back to the week, so this week’s repulsion is extremely negative.
  • the positive pole positive force and the positive front force are collectively referred to as the positive pole force.
  • the positive pole force is simultaneously applied to the magnets of the force moving synchronously, so that the synchronous moving magnet moves back and forth at a certain moving distance.
  • Suck Negative force and Zhou Ji repulsion are collectively referred to as Zhou Li negative force.
  • the mass of the rotary motion magnet and the reciprocating magnet of the five sets of magnetic kinetic energy mechanisms are the same, and the positive and negative force of the magnet and the magnet are equal. Therefore, the resistance method is not desirable in the magnetic kinetic energy device.
  • the successful conversion of Zhou Jizheng into kinetic energy firstly disconnects and balances the negative force in the device.
  • the magnet 17 and the magnet 20 are fixed and non-rotating without reciprocating magnets, and the magnet 18 and the magnet 19 can only be rotated in situ.
  • the magnet 17, the magnet 18, the magnet 19 and the magnet 20 are of the same quality and specifications and are on the same axis.
  • the magnetic poles are also perpendicular to the same axis, and the magnetic poles of the gyromagnetic 18 and the magnet 17 are opposite poles in the process of arbitrary rotation of 180 degrees, and the magnetic poles of the gyromagnetic 19 and the magnet 20 are the same in the process of rotating 180 degrees arbitrarily.
  • the extreme reaction force, the gyromagnetic 18 and the gyromagnetic 19 magnetic poles are opposite and closely connected, then the gyromagnetic 18 and the gyromagnetic 19 are in synchronous rotation, and the gyromagnetic 18 generates a heteropolar force at the same equilibrium line across the magnet 17, and the gyromagnetic 19
  • the opposite balance line of the magnet 20 generates a counter-reaction force: the gyromagnetic 18 generates an opposite-pole reaction force across the opposite balance line of the magnet 17, and the gyromagnetic 19 also crosses the same balance line of the magnet 20 to generate a heteropolar force; therefore, the gyromagnetic 18
  • the opposite pole or reverse work with the magnet 17 is balanced with the opposite pole work or the smoothing of the magnet 19 and the magnet 20, and the gyro 18 and the gyro 19 are idling (except friction), the gyro 18 and the magnet 17 suction
  • the two poles of the gyromagnetic 9 and the reciprocating magnetic 11 are different from each other in the process from the same to the opposite, while the gyromagnetic 6 and the reciprocating magnetic 4 are opposite poles in the process from the opposite to the same, and the two groups are common.
  • the magnetic field is extremely cis-reverse force is rotating in the same direction, the different-pole reaction force needs external force to change the direction of the magnetic pole, and the different-pole force is the rotation force of the magnet and the magnet itself to change the direction of the magnetic pole, and the negative force of the circumference is passed.
  • the two magnets are completely attracted, they continue to attract each other. After the two magnets completely repel each other, they continue to repel each other.
  • the synchronous reciprocating motion at this time is a stationary state, because of the distance difference between the two sets of two magnets.
  • the differentiating force generated by the gyromagnetic 9 and the reciprocating magnetic force 11 of FIG. 4 can be transmitted through the driving mechanism 7 to balance the part of the gyromagnetic 6 and the reciprocating magnetic force 4 to generate the opposite pole reaction force. The same is true for the opposite pole and the opposite pole.
  • the gyromagnetic 6 and the gyromagnetic 9 are continuously synchronously rotated.
  • the force is synchronously reciprocated.
  • the magnet in the same direction of the two common magnetic field forces of the two sets of the gyromagnetic and the reciprocating magnetic force, when the circumferential force and the dissimilar force of the magnetic kinetic energy device are simultaneously exchanged, the synchronous or reciprocating movement of the magnet moves synchronously, Both the extreme force and the different force will change as the angle of rotation and the distance of the two magnets change.
  • the heteropolar force increases inversely proportionally with the decrease of the distance between the gyromagnetic and the reciprocating magnetic attraction motion, and the heteropolar reaction force decreases inversely proportionally with the increase of the distance between the gyromagnetic and the reciprocating magnetic repulsive motion;
  • the repulsion increases inversely proportionally as the gyromagnetic and reciprocating magnetic fields decrease from vertical to the same rotation angle, and decreases inversely proportionally as the distance between the two magnets increases;
  • the circumferential suction increases with the gyromagnetic and reciprocating magnetic fields from vertical to The opposite rotation angle decreases and becomes inversely proportionally increased, and also increases inversely proportionally as the distance between the two magnets decreases.
  • the common magnetic field explosive force of the two sets of magnets and the magnet combination can drag the displacement force of the multiple object displacement work and the required motion distance G-like.
  • the maximum and maximum force of the differential force of Figure 6 are equal (in practice, the two small magnets that are opposite to each other are separated by the two-handed rotation method, and the rotational force used to separate the two small magnets of the opposite poles is smaller than that used by the straight pull method. pull).
  • the maximum value is set to A. Because the two sets of gyromagnetic and reciprocating magnetic fields are provided with equal and equal moving distance G, the different polar cis-reverse force will not be balanced as shown in Fig. 6.
  • the opposite polarity and the peripheral repulsion force are at In the motion of the synchronous reciprocating magnet, as the rotation angle and the moving distance of the two magnets change, the minimum values of the bipolar force and the circumferential force in the motion state of FIG. 4 are also equal, and the minimum values are each set to B, then In the rotation of the synchronous rotating moving magnet of 4, when a set of gyromagnetic magnetic poles rotates to be exactly the same as the magnetic poles of the reciprocating magnetic pole, the maximum repulsive force A of the minimum distance of the two magnets, plus the other set of gyromagnetic magnetic poles rotates to and When the magnetic poles of the reciprocating magnetic pole are completely opposite, the minimum value of the suction force of the maximum distance of the two magnets B; or the maximum value of the suction force A of the minimum distance of the two sets of opposite magnets, plus the minimum repulsive force B of the maximum distance of the other two identical magnets; In order to make the force of the force synchronously reciprocating the moving magnet,
  • the two groups of common magnetic field push and pull forces are simultaneously in the same direction, it is A plus B.
  • the maximum value of the differential reactance force A generated by the minimum distance between a set of gyromagnetic and reciprocating magnetic fields, and the minimum value B of the heteropolar force generated by the maximum distance between the other set of gyromagnetic and reciprocating magnetic fields due to the two groups of common magnetic field
  • the counter-reaction force needs external force to change direction.
  • the different-pole force is the rotation force of the magnet and the magnet itself changing direction, which can balance part of the counter-reaction force, so it is A minus ⁇ Therefore, the motion state A of FIG. 4 plus B is greater than A minus B.
  • the difference between A plus B and A minus B is a difference of one).
  • the synchronous rotary motion magnet rotates for one revolution, and the synchronous reciprocating magnet generates a reciprocating motion once, and the reciprocating motion is once. Equal to 1 week of rotation, so the week is extremely
  • the power (output power) generated by the reciprocating moving magnet in the reciprocating motion distance G is greater than the power of the isokinetic counter-rotating moving magnet in the rotating motion. (input power).
  • the circumferential repulsive force increases inversely proportionally as the gyromagnetic and reciprocating magnetic fields decrease from vertical to the same rotation angle, and the circumferential suction increases inversely proportionally as the gyromagnetic and reciprocating magnetic fields decrease from vertical to opposite rotational angles;
  • the heteropolar force increases inversely proportionally with the decrease of the distance between the gyromagnetic and the reciprocating magnetic attraction motion, and the heteropolar reaction force decreases inversely proportionally with the increase of the distance between the gyromagnetic and the reciprocating magnetic repulsive motion;
  • the repulsive force is not the same when the gyromagnetic and the reciprocating magnetic vertical are not the same.
  • the circumferential suction force can be synchronized to the reciprocating motion of the magnet.
  • the required weight is at the moving distance G when the gyromagnetic and the reciprocating magnetic vertical are not reversed.
  • the upper displacement works, because the required weight is reduced, the output power is correspondingly reduced, because the distance between the two magnets to generate the different poles is reduced, the distance between the two magnets to generate the different pole reaction force is increased, and the magnetism and the reciprocating magnetic generation are simultaneously generated.
  • the minimum value B of the different polarity of the different poles increases correspondingly, and the maximum value A of the different pole reactance decreases correspondingly, and the portion of the counter-pole reaction of the different poles increases also, and the input power also decreases accordingly. Therefore, in the rotation of the synchronous rotating magnet in Fig. 4, when the static state of the synchronous reciprocating motion is synchronized, the different poles can balance a part of the counter-reverse work, so in the motion state of the synchronous reciprocating magnet of Fig. 4, A plus B is always greater than Eight minus 8.
  • the heteropolar force increases inversely proportionally with the decrease of the distance between the gyromagnetic and the reciprocating magnetic attraction motion, and the heteropolar reaction force decreases inversely proportionally with the increase of the distance between the gyromagnetic and the reciprocating magnetic repulsive motion;
  • the extreme repulsive force decreases inversely proportionally with the increase of the distance between the magnetism and the reciprocating magnet.
  • the circumferential suction increases inversely proportional to the distance between the two magnets minus 'J.
  • the moving distance G of the magnetism and the reciprocating magnetic body is set to be small, and the synchronous reciprocating motion of the reciprocating magnet is equal to one rotation for one week, the minimum value of the peripheral suction or repulsive force B is increased, and the output power is correspondingly increased;
  • the minimum value B of the differential current generated by the reciprocating magnetic force is increased, and the cross-polarization of the different poles is increased, and the input power is correspondingly reduced. Therefore, in the rotation of the synchronous rotating magnet in Fig. 4, when the static state of the synchronous reciprocating motion is synchronized, the different poles can balance a part of the counter-reverse work, so the moving distance G is set to be small, and the moving state A of FIG. 4 plus B is larger than A. Subtract B, assuming that the difference between A plus B and A minus B is the difference two, then the difference two is greater than the difference one.
  • FIG. 8 to 11 are schematic views of Fig. 7 in a stationary state with a rotation unit of 36 degrees.
  • the moving state of the synchronous reciprocating moving magnet is also five sets of synchronous reciprocating moving magnets, which are sequentially cyclically equidistant and reciprocating in the moving distance and the white arrow 15 illustrates the opposite polarity Schematic diagram of force balance.
  • Figure 12 is a schematic view showing the stationary state of the drive mechanism 7 of Figure 7 when it is rotated to 18 degrees
  • Figure 13 is a schematic view of the stationary state of Figure 7 when the drive mechanism 7 is rotated to 9 degrees
  • Figure 14 is the rotation of the drive mechanism 7 of Figure 12 to 9 degrees.
  • Schematic diagram of the stationary state, FIG. 12 to FIG. 14 are schematic diagrams of the motion state of FIG. 7 rotated by 9 degrees as a rotation unit to FIG. 8, and also shows the balance of the opposite poles.
  • Figure 15 shows the working principle, motion state, quiescent state and the balance of the sinusoidal counter-reverse power in the same way as in Figures 7 to 14. The difference is that the adjacent reciprocating magnets of the five sets of magnetic kinetic energy mechanisms are opposite in turn, or the adjacent rotating moving magnets are reversed in turn, and the five sets of synchronous reciprocating moving magnets are crossed and reciprocated in the same distance in the moving distance G. Cross-reciprocating motion does not require a transition gear.
  • Figure 16 is the same as Figure 15, and Figure 16 is a combination of a set of magnetic kinetic energy mechanisms based on the structure of Figure 15.
  • the magnetic kinetic mechanism can also be continuously added according to the coordinated method of reciprocating the reciprocating moving magnetic poles in an equal sequence.
  • the drive mechanism 7 of Fig. 16 is rotated in units of 30 (180 divided by 6 equal to 30) degrees.
  • FIG. 1 is a frame
  • FIG. 1 is a combination of a set of magnets and magnets added to the six sets of magnetic kinetic energy mechanisms of FIG. 16, and a drive 7 is provided on the rotating moving magnet, and a set of driving mechanisms 14, a driving mechanism 14 and The driving mechanism 7 is similarly treated, and at the same time, six sets of gyromagnetic 13 synchronous rotation and force transmission are performed, and six sets of gyromagnetic 13 and six sets of gyromagnetic 6 are similar.
  • FIG. 17 is a schematic view showing the state in which the drive mechanism of Figure 1 is rotated to 330 degrees.
  • Fig.7 Five sets of synchronous reciprocating moving magnets are cyclically equidistant in the reciprocating motion in the moving distance. When the bipolar force and the circumferential force are simultaneously interchanged, the five sets of synchronous reciprocating magnets are first set to the stationary state in motion to see the opposite pole force. .
  • the moving distance between the second set of reciprocating magnets 11 and the gyromagnetic 9 is equal to the moving distance of the fifth group of the gyromagnetic 6 and the reciprocating magnetic 4, and the second group of reciprocating magnetic waves are equal because the distances are equal and the same 11 and the polar-magnetism of the gyromagnetic 9 and the fifth-group gyromagnetic 6 and the reciprocal magnetic force of the reciprocating magnetic 4 are equal, and the reciprocating magnetic force of the reciprocating magnetic 4 and the gyromagnetic 6 in the second group and the fifth
  • the group of the gyromagnetic 9 and the reciprocating magnetic 11 have the same mutual polarity, so that the second and fifth groups of the bipolar cis-force can be balanced by the transmission mechanism 7 (this cis-reaction balance means positive and negative Offset)
  • the third group, the fourth group, the second group, and the fifth group are similar.
  • the first group of the opposite polarity is the same as the static state of Figure 4.
  • the first group of the reciprocating magnetic 11 and the gyromagnetic 9 magnetic pole are opposite pole to the same in the opposite to the same, while the gyromagnetic 6 and the reciprocating magnetic 4 magnetic pole are from the same to the opposite, which is the opposite pole, and the third group of the reciprocating magnetic 11
  • the gyromagnetic 9 magnetic pole is a heteropolar force in the same to the opposite, while the gyromagnetic 6 and the reciprocating magnetic 4 magnetic pole are opposite to the same, which is a heteropolar reaction force, so the first and third groups of the opposite polarity cis-force
  • the balance is transmitted by the drive mechanism 7.
  • the fourth group and the fifth group have the same principle and the second group and the fifth group of Fig. 7, and the second group is similar to the first group of Fig. 7.
  • 9 to 11 are similar to the same as FIG. 8 and so on.
  • FIG. 13, and FIG. 14 are the stationary states of FIG. 7 to FIG. 8 with the rotation unit of 9 degrees. Then, the three figures divide the distances of the motion states of FIG. 7 to FIG. 8 into four, and FIG. 12 is FIG.
  • the synchronous reciprocating moving magnet moves to the stationary state of FIG. 8 - half
  • FIG. 13 is the stationary state of the synchronous reciprocating moving magnet of FIG. 7 to half of FIG. 12
  • FIG. 14 is the synchronous reciprocating moving magnet of FIG. 12 to the stationary state of FIG.
  • the balance of the opposite polarity of Figure 12 is the same as that of Figure 7.
  • the second group of gyromagnetic 6 and the reciprocating magnetic force 4 have a larger moving distance than the first group of gyromagnetic 6 and the reciprocating magnetic 4 (heteropolar force) of 1/10G, the first group of rotation
  • the moving distance between magnetic 9 and reciprocating magnetic 11 (heteropolar reaction) is greater than 1/10G of the second group of gyromagnetic 9 and the reciprocating magnetic 11 (heteropolar force), the fifth group of gyromagnetic 6 and the reciprocating magnetic 4 (different pole
  • the moving distance of the reaction force is greater than 1/10G of the third group of gyromagnetic 9 and the reciprocating magnetic 11 (heteropolar force)
  • the movement distance of the third group of gyromagnetic 6 and the reciprocating magnetic 4 (heteropolar reaction) is greater than the fifth The group of gyromagnetic 9 and the reciprocating magnetic 11 (heteropolar force) 1/10G, the fourth group of gyromagnetic 6 and the reciprocating
  • the first group of gyromagnetic 6 and the reciprocating magnetic 4 have a larger moving distance than the second group of gyromagnetic 6 and the reciprocating magnetic 4 (heteropolar reaction) of 1/10G, the second set of rotation
  • the moving distance between magnetic 9 and reciprocating magnetic 11 is greater than 1/10G of the first set of gyromagnetic 9 and reciprocating magnetic 11 (heteropolar reaction)
  • the third set of gyromagnetic 9 and reciprocating magnetic 11 (different pole
  • the moving distance of the smooth force is greater than 1/10G of the fifth group of the gyromagnetic 6 and the reciprocating magnetic 4 (the heteropolar reaction force)
  • the movement distance of the fifth group of the gyromagnetic 9 and the reciprocating magnetic 11 is greater than the third
  • the rotational distance of the group of gyromagnetic 6 and the reciprocating magnetic 4 (heteropolar reaction) is greater than that of the fourth group of gyromagnetic 6
  • the five sets of synchronous reciprocating magnets of FIG. 7 sequentially cycle the equidistant round-trip motion over the moving distance.
  • the different-pole force increases inversely proportionally with the decrease of the distance between the gyromagnetic and the reciprocating magnetic flux in FIG. 7 to FIG. 8, and the different-pole reaction force increases with the gyromagnetic and the reciprocating force.
  • the distance between the magnets increases, the inverse ratio decreases.
  • the distance between the magnets of the different poles and the counter-forces is equal, the two poles are equal and the two forces are equal. Then, FIG. 12 reaches the motion state of FIG.
  • the resulting heteropolar process can balance the greater than the counter-reverse work generated by the flywheel device storage and drive mechanism 7 to the state of motion of FIG. 8 to 11 is the same as that of FIGS. 7 to 8 in the state of movement between the two figures of the driving mechanism 7 in units of rotation of 36 degrees.
  • the driving mechanism 7 of FIG. 7 is rotated by 180 degrees to 360 degrees.
  • the same as Figs. 7 to 14. 8 to 11 are the state of motion of Fig. 7, and the transfer of the different poles and the reverse power through the drive mechanism 7 is also balanced.
  • the different polar cis-reverse power generated by the respective groups of the magnetic kinetic energy mechanisms of Figs. 7 to 11 in the state of motion is the same as that of Fig. 4. The same applies to the processing of multiple sets of magnetic kinetic energy mechanisms.
  • the six sets of synchronous reciprocating moving magnets of Fig. 16 are sequentially crossed and reciprocated at the same distance of the moving distance G, according to the white arrow 15 and the equal distance and the different poles and the counter-reciprocal force are also equal to understand Fig. 16, the second group and The sixth group of the balance of the opposite poles, the balance of the third group and the fifth group, the balance between the fourth group of the gyro 6 and the reciprocating magnetic 4, the reciprocating magnetic 11 and the gyromagnetic 9
  • the equal difference is the balance of the opposite poles.
  • the first group is the same as the first group of Fig. 7.
  • Fig. 16 shows the driving state of the driving mechanism 7 in a rotation unit of 30 degrees, and the balance is transmitted by the driving mechanism according to the distance between the white arrow and the magnet and the magnet combined with the magnet, and so on.
  • the sixth group is 5/2G away from the direction of the difference of the direction of the opposite pole; the fifth group of the counter-force is larger than the second group, and the difference is also 1/6G, the third group
  • the different-pole reaction force is greater than the fourth group of the same-pole force, and the difference of the motion distance is also 1/6G.
  • the first group is 5/6G away from the direction of the opposite-pole reaction force; this Figure 1 is larger than the different-pole force can be used with the flywheel.
  • the device is stored to balance the counter-reaction force of Figure 17, so that the other rotation angles of Figure 1 are greater than the corresponding rotation angles.
  • the heteropolar shunt is balanced by the flywheel device storage.
  • the magnetic kinetic energy device combined with the plurality of sets of magnetic kinetic energy mechanisms
  • the gyromagnetic and the reciprocating magnetic perpendicular to the same angle
  • the gyromagnetic and the reciprocating magnetic perpendicular to an opposite angle vertical to the same
  • the explosive force and the explosive force distance generated by one angle and the vertical to the opposite angle are equal to the total output power, and the difference between the input and output powers of the plurality of sets of the kinetic energy mechanism is required.
  • Magnetic kinetic energy device
  • the device uses a standard synchronous reciprocating motion to balance the reciprocating motion of the reciprocating magnet to balance the unfavorable negative force of the pole, and then use the spine transmission, hydraulic or The method of pneumatic turbine transmission, hydraulic or pneumatic crankshaft transmission disconnects the negative force of the circumference, so that the beneficial positive force of the force on the reciprocating moving magnet will not work on the standard round-trip distance G. Balanced by Zhou Li.
  • the circumferential force and the dissimilar force are the common magnetic field forces of the geomagnetic field of the magnet and the magnetic pole of the magnet from the opposite to the same and the same to the opposite. Weekly force and different force are two different forces, but they interact.
  • the forward and reverse rotation of the differential force is the rotational force of the geomagnetic energy
  • the repulsive force after the conversion of the circumferential force is the thrust of the geomagnetic energy.
  • the magnetic field is quickly supplemented by the magnetic field of the magnetic kinetic energy device when the magnetic energy is consumed. Referring to Fig. 1 through Fig. 2 to Fig. 17, the circumferential force and the disparity force have been separated.
  • the beneficial heteropolar process can balance the unbalanced part of the reverse pole work in the device through the flywheel device, the drive mechanism 7, the shaft 12 and the drive mechanism 14; the standard round-trip motion is limited by the limited reciprocating magnet, and the unfavorable peripheral force is negative. It has been balanced in the device, and the positive magnetic field force has been independently present in the device.
  • the beneficial positive force of the force in the independent device is made, so that the force of the plurality of sets of the magnetic kinetic energy mechanism is synchronously reciprocated to the moving magnet, sequentially or crosswise in the standard round-trip moving distance G.
  • the current generator is a circular magnetic line cutting motion in a magnetic field to convert other forms of energy into electrical energy.
  • the magnetic kinetic energy generator device is continuously or in a straight line in the magnetic field through the power output device 3 provided.
  • the magnetic induction line cutting motion converts the peripheral repulsion work into electrical energy.
  • the current generator is consuming it
  • the magnetic energy of the magnetic field and the magnetic field generates electric energy
  • the magnetic energy generator device balances the magnetic energy of the earth magnetic field and the earth magnetic field, and the beneficial magnetic energy generates electric energy with the magnetic energy of the earth magnetic field.
  • each group of magnetic kinetic energy mechanisms in the device are sequentially or cross-circularly reciprocated and reciprocated at a moving distance G
  • the power output device 10 and the spine energy transmission device are sequentially circulated in the same manner as the internal combustion engine to push or pull the crankshaft.
  • the current internal combustion engine converts chemical energy into kinetic energy in the combustion fuel; the electric motor consumes kinetic energy from the magnetic energy that consumes electric energy and the geomagnetic field; and the magnetic kinetic energy engine device balances the magnetic energy that makes the earth magnetic field and the geomagnetic field unhelpful, and the beneficial magnetic energy is directly converted into kinetic energy.
  • the magnetic kinetic energy generator device 1 can be used as a main device and the magnetic kinetic energy engine device can be used as an auxiliary device according to various needs of kinetic energy. Or a magnetic kinetic energy engine device as a main device, a magnetic kinetic energy generator device
  • the internal combustion engine is a chemical fuel that expands in the combustion fuel to drive the crankshaft to generate kinetic energy.
  • the magnetic kinetic energy device combines magnetic kinetic energy of nature through a plurality of sets of magnetic fields and magnetic fields, so that unprofitable magnetic energy is balanced in the device, and beneficial magnetic energy is directly converted into kinetic energy by the device.
  • the working principle of the car is to separate the kinetic energy generated by the engine from the multi-directional kinetic energy, such as the mechanical kinetic energy, the charging or lighting of the generator to the battery, the heat dissipation of the fan and the forward movement of the car.
  • the kinetic energy of the magnetic kinetic energy device after the driving wheel 8 is activated can also separate the multi-directional kinetic energy from the mechanical kinetic energy and various other kinetic energy needs.
  • the magnetic kinetic energy device has the disadvantage that the generator, the engine and the internal combustion engine have no disadvantages, and the power line is not required to be connected, and the mechanical structure is simpler than the internal combustion engine. It is not a local indirect energy conversion device, but a magnetic energy balance and direct conversion device in the atmosphere; magnetic energy is not as day and night as solar energy; there is no pollution to the environment in the atmosphere.

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  • Engineering & Computer Science (AREA)
  • Power Engineering (AREA)
  • Connection Of Motors, Electrical Generators, Mechanical Devices, And The Like (AREA)
  • Particle Accelerators (AREA)

Abstract

L'invention concerne un appareil d'énergie cinétique magnétique qui comprend au moins deux mécanismes d'énergie cinétique magnétiques. Le mécanisme cinétique magnétique comprend au moins deux combinaisons d'un aimant et d'un aimant. La combinaison d'un aimant et d'un aimant comprend un aimant ayant un mouvement de va-et-vient (4) et un aimant rotatif (6). Un dispositif de sortie de puissance (3) est monté sur l'aimant ayant un mouvement de va-et-vient (4) et un élément de commande (7) est monté sur l'aimant rotatif (6).
PCT/CN2008/071337 2007-06-18 2008-06-17 Appareil d'énergie cinétique magnétique WO2008154864A1 (fr)

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Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB2466034A (en) * 2008-09-02 2010-06-16 Nicholas William Field Improved electrical power transmission system for a faraday cage

Families Citing this family (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
TW201601448A (zh) * 2014-06-20 2016-01-01 Yuan-Chen Tsai 磁力運轉控制設備

Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4011477A (en) * 1974-07-19 1977-03-08 Scholin Harold W Apparatus using variations in magnetic force to reciprocate a linear actuator
WO2006116542A2 (fr) * 2005-04-27 2006-11-02 Stephen Kundel Moteur comprenant des aimants permanents oscillants et rotatifs
CN201054557Y (zh) * 2007-06-28 2008-04-30 姚儒 一种磁动能装置
CN101174803A (zh) * 2007-06-18 2008-05-07 姚儒 磁动能装置

Patent Citations (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
US4011477A (en) * 1974-07-19 1977-03-08 Scholin Harold W Apparatus using variations in magnetic force to reciprocate a linear actuator
WO2006116542A2 (fr) * 2005-04-27 2006-11-02 Stephen Kundel Moteur comprenant des aimants permanents oscillants et rotatifs
CN101174803A (zh) * 2007-06-18 2008-05-07 姚儒 磁动能装置
CN201054557Y (zh) * 2007-06-28 2008-04-30 姚儒 一种磁动能装置

Cited By (1)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
GB2466034A (en) * 2008-09-02 2010-06-16 Nicholas William Field Improved electrical power transmission system for a faraday cage

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