A permanent magnet motor is constructed of a plurality of permanent magnets arranged in a circular arrangement on a base of the motor, and with a first cylindrical magnet and a second cylindrical magnet mounted on respective first and second radial shafts that project from a gear box on a center shaft to positions over the circular arrangement of permanent magnets. The motor operates to move the first and second cylindrical magnets in rotation over the circular arrangement of the plurality of permanent magnets in response to a one time initial motion and does not require communication with any outside source of energy and does not require an input of energy to the permanent magnet motor for continued operation of the permanent magnet motor.

A permanent magnet motor is constructed of a plurality of permanent magnets arranged in a circular arrangement on a base of the motor, and with a first cylindrical magnet and a second cylindrical magnet mounted on respective first and second radial shafts that project from a gear box on a center shaft to positions over the circular arrangement of permanent magnets. The motor operates to move the first and second cylindrical magnets in rotation over the circular arrangement of the plurality of permanent magnets in response to a one time initial motion and does not require communication with any outside source of energy and does not require an input of energy to the permanent magnet motor for continued operation of the permanent magnet motor.

Enhanced network power factor corrective designs are presented that can use corrective devices that achieve long-term, operationally stable mechanical work. Embodiments can utilize reverse-winding induction motor designs with engineerable parameters and configurations for the reverse winding (13) in systems and through methods where an inductive motor (1) can present a current that leads voltage and a leading power factor (16) to correct other existing induction motors (8) in an initial network (9) or be optimized for a particular application. Designs also present a power factor correction that can present a variable correction without altering the character or physical capacitive value of an electrical correction component. Individual induction motors that have leading current and a leading power factor (16) can be provided to improve reverse winding induction motors. Progressive start controls (23) can also be used in a manner that limits inrush current to operational levels with passive current establishment control where reverse winding (13) effects can be used and perhaps even delayed to passively limit and even effect a current decrease while rotational acceleration continues after initial start transition.

A torque multiplier (1) comprising a movable axle (2) having a variable incline with a specific ball joint terminal (3), which has a mechanical energy source M1 as an input and acts as a lever arm, providing an output torque on the other end, which is greater than the input torque, which can be used to actuate a mechanical device. The present invention also comprises an energy-generating system that operates on the basis of the torque multiplier principles, consisting of an axle (2A) associated with a ball joint terminal (3A), characterising a first torque multiplier (1A) having an oscillating mass (10) on the end thereof. The rotation of the mass (10) generates the continuous displacement of the centre of gravity thereof and provides constant movement of the movable axle (2A).

The torque-increasing device includes multiple rotating discs, rings, or rotors, each including embedded or affixed magnets. The discs are canted toward each other, thus passing closer to each during the first half of a rotation, and further apart during the second half of a rotation. As the adjacent magnets attract each other, the attractive force is split into two vectors: a vector that is perpendicular to an imaginary plane that divides the discs, and a torque vector that is parallel to the face of the rotors. Disruption of the attraction of the magnets on either the upper or lower half of the rotor, or a segment of the upper or lower half, unbalances the rotors and captures a torque.

A magnetic apparatus and related method and energy product-by-process to motivate linear or rotational motion, comprising: at least one magnet ring tier comprising a ring of a plurality of permanent magnets; a central core comprising a permanent magnet projectile movement channel, an axis of the channel aligned in a direction normal to a geometric plane defined by the magnet ring, and running through a geometric center of the magnet ring; and each of the permanent magnets mounted in the ring at a mount angle thereof, with the components of their polar alignments parallel to the central core all oriented in the same direction; wherein: if the polar alignment of a permanent magnet projectile was introduced with a particular duality-dependent orientation into the permanent magnet projectile movement channel, the magnetic forces between the ring magnets and the projectile would be capable of motivating the permanent magnet projectile relative to the channel.

A magnetic apparatus and related method and energy product-by-process to motivate linear or rotational motion, comprising: at least one magnet ring tier comprising a ring of a plurality of permanent magnets; a central core comprising a permanent magnet projectile movement channel, an axis of the channel aligned in a direction normal to a geometric plane defined by the magnet ring, and running through a geometric center of the magnet ring; and each of the permanent magnets mounted in the ring at a mount angle thereof, with the components of their polar alignments parallel to the central core all oriented in the same direction; wherein: if the polar alignment of a permanent magnet projectile was introduced with a particular duality-dependent orientation into the permanent magnet projectile movement channel, the magnetic forces between the ring magnets and the projectile would be capable of motivating the permanent magnet projectile relative to the channel.

A generator system having a dynamo that contains an armature, a stator and a housing. The armature rotates about a first axis of rotation. The stator is concentrically positioned around the armature. Both the armature and the stator are free to rotate in opposite directions about the first axis of rotation. The housing of the dynamo is connected to a motor that can rotate the dynamo around a second axis of rotation. There is an angle of inclination between the first axis of rotation and the second axis of rotation. This angle of inclination is selectively altered during operation. By changing the angle of inclination between the two axes of rotation, a precession can be created that adds rotational energy to both the armature and the stator. This increases the output of the dynamo and creates a highly efficient electrical generator.

A generator system having a dynamo that contains an armature, a stator and a housing. The armature rotates about a first axis of rotation. The stator is concentrically positioned around the armature. Both the armature and the stator are free to rotate in opposite directions about the first axis of rotation. The housing of the dynamo is connected to a motor that can rotate the dynamo around a second axis of rotation. There is an angle of inclination between the first axis of rotation and the second axis of rotation. This angle of inclination is selectively altered during operation. By changing the angle of inclination between the two axes of rotation, a precession can be created that adds rotational energy to both the armature and the stator. This increases the output of the dynamo and creates a highly efficient electrical generator.

This invented electric motor is a new type of motor that is based on a principle in which many of an identical electric motors working at the same power and speed simultaneously to generate combined greater power.

It comprises of a numerous small identical motors (component motors), depending on the output required. These component motors are connected into the main motor along with gears, capacitors and controller units. This motor will generate great amount of power while consuming very small amount of an electricity due to switching of these small component motors to rotate the gears and generate power.