CN107078601A - Self-powered alternative energy machines that generate electricity - Google Patents

Abstract

Alternative energy generating devices are provided. The apparatus includes one or more stationary metal coils positioned above, below, or beside a magnet or a magnet rotor having one or more embedded magnets (e.g., rare earth magnets). The magnets may be embedded along the exterior of the disk rotor. One or more coils may be held in a coil plate arrangement substantially parallel to the magnet rotor. The provided apparatus further comprises a shaft having a gear ratio for rotating the magnet rotor, such as by hand or a motor, to achieve a high rotational speed. The magnet generates an electromagnetic field that, when rotated relative to the stationary metal coil, generates an electric current.

Description

Self-powered alternative energy machines that generate electricity

Relevant US application materials

This patent document claims U.S. Provisional Patent Application Serial No. 62/076,847, filed November 7, 2014, entitled "SELF-POWERED ALTERNATIVE ENERGYMACHINE TO GENERATE ELECTRICITY," and filed March 17, 2015, entitled "SELF-POWERED ALTERNATIVE ENERGY MACHINE TO GENERATE ELECTRICITY", the disclosure of which is incorporated herein by reference. This patent document is also a continuation-in-part of U.S. Patent Application Serial No. 14/737,001, filed June 11, 2015, entitled "ALTERNATIVE ENERGY GENERATOR," which claims the title "ALTERNATIVE ENERGY GENERATOR," filed June 11, 2014 Priority of U.S. Provisional Patent Application Serial No. 62/010,698, the disclosure of which is incorporated herein by reference.

technical field

The present invention relates generally to methods and apparatus for generating large amounts of electrical power using self-powered alternative energy machines, and more particularly to mechanical equipment machines having sets of metal coils and rotating magnets that can be rotated by hand or by a motor through a shaft having a gear ratio To propel the mechanical equipment machine to generate the rotational speed of rotation to generate the electromagnetic field used to generate electricity.

Background technique

Energy can be generated from wind and solar sources as well as fossil fuel and chemical sources. Generating alternative forms of electricity is important for many reasons, such as reducing costs to the public. In general, for example, windmills to capture wind energy and solar panels to capture sunlight energy continue to be costly due to complex manufacturing methods and weight of materials. In general, solar panels also provide cost-inefficient energy and require a large installation space. Using chemicals as energy sources is potentially dangerous and harmful to the environment. Accordingly, there is a need for safe, cost-effective methods and devices that can be configured to continuously generate electricity at reasonable cost for public use, residential areas, commercial areas, and to power motors in general and motor vehicles. Alternatively and more specifically, there is a need for alternative sources using cost-effective methods and devices that also generate electricity continuously (e.g., twenty-four hours a day, seven days a week (hereinafter denoted 24×7). Wind energy, solar Energy and other grid energy sources are not available 24×7 because they depend on specific weather conditions. Alternative energy sources are also needed to mitigate or eliminate global warming. Therefore, alternative energy sources with minimal to zero carbon footprints can be expected as sustainable energy.

Contents of the invention

Devices are provided that include one or more stationary metal coils positioned above, below or beside a magnet or magnet rotor with one or more embedded magnets, similar to the internal arrangement of a Shurite ammeter. The magnets can be embedded along the outside of the disc rotor, similar to the numbers on a clock, and can be numerous and close to each other or not far and far apart from each other. Additionally, one or more coils are held in a coil plate substantially parallel to the magnet rotor. The coils can be placed on the outside of the board device and can also be placed closer together or farther apart, similar to the numbers on a clock. The provided apparatus further comprises a shaft with a gear ratio for turning the magnet rotor, such as by hand or a motor, to achieve high rotational speeds. A magnet generates an electromagnetic field, which, when rotated relative to a stationary metal coil, generates an electric current.

A first aspect of the invention comprises an electric generator arrangement comprising: a rotating device having an axis of rotation and a mass; at least one metallic coil disposed on the rotating device; at least one stationary magnet, the magnetic flux field of which interacts with the metal Coil contacts; a shaft fixed to a rotating device along the axis of rotation; a mechanical motion conveying device in mechanical contact with the shaft; and a gear set having more than one gear ratio, which is in mechanical contact with the rotating device and the mechanical motion conveying device via the shaft , where energy is generated when the metal coil passes through the magnetic flux field of the magnet.

A second aspect of the invention includes a power generator comprising: a rotating device having an axis of rotation; at least one magnet disposed on the rotating device; at least one stationary metal coil, the magnetic flux field of the magnet being in contact with the metal coil; A shaft fixed to a rotating device along an axis of rotation; a mechanical motion conveying device in mechanical contact with the shaft; and a gear set having more than one gear ratio in mechanical contact with the rotating device and the mechanical motion conveying device via the shaft, where when When the magnetic flux field of the magnet passes through the metal coil, energy is generated.

A third aspect of the present invention includes a method of operating an electrical generator comprising: powering a motor with an external source in mechanical contact with a rotatable device embedded with one of a metal coil or magnet; at least 5 revolutions per minute (RPM) rotating the rotatable device; passing the metal coil through the magnetic field via the rotational motion of the rotatable device; generating a current based on the metal coil passing through the magnetic field; disconnecting the external source; and powering the motor with the generated current.

Description of drawings

These and other features of the present invention will be more readily understood from the following detailed description of various aspects of the invention, taken in conjunction with the accompanying drawings, in which:

Figure 1 is a side view of an embodiment of the invention showing a device with two magnet rotors and a coil plate device with mounted magnets, according to an embodiment of the invention.

Figure 2 is a top-down interior view of an embodiment of the present invention.

Figure 3 is a front view of an embodiment of the invention with a mounted coil plate arrangement (left) and a mounted view of a magnet rotor arrangement (right) according to an embodiment of the invention.

Figure 4 is a front interior view of another embodiment of the invention utilizing a coil plate on a coil frame apparatus mounted in the center of two magnet rotors on either side of the coil plate clamping the coil plate with the magnet rotors very close to the coils In the middle, where the magnet rotor and coil plate do not touch or touch each other, and form a centrifuge-like arrangement.

Figure 5 is a peripheral view of another embodiment of the invention quadrupling the coil plate and magnet rotor arrangement of Figure 1 into four consecutive units driven by a motor and a gearbox to generate electrical current.

Figure 6 is a peripheral view of another embodiment of the present invention which unifies six coil plate and magnet rotor arrangements of Figure 1 into six consecutive units. The six serial units are driven by a motor and a gearbox to generate electric current.

Fig. 7 is a front interior view of another embodiment of the present invention in which the coil plate rotates while the two magnet rotors remain stationary without rotating. a coil plate mounted on a coil frame apparatus between two stationary magnet rotors, wherein the coil plate is sandwiched with the magnet rotors in close proximity to the coils, but the magnet rotors and coil plates do not touch or touch each other; and form a centrifuge shaped arrangement.

Figure 8 is a top front view of a device according to an embodiment of the invention.

Figure 9 is a front view showing another embodiment of the invention of an apparatus having two magnet rotors with mounted magnets and a coil plate arrangement.

10A is a view of a device initially driven by a hand crank, according to an embodiment of the present invention.

10B is a view of a device initially driven by a mechanical device such as a motor powered or powered by a DC/AC battery, according to an embodiment of the present invention.

10C is a diagram of one or more capacitor devices or other similar electrical devices used as a transfer means to transfer power to a motor, according to an embodiment of the present invention.

The drawings are not necessarily drawn to scale. The drawings are merely schematic representations, not intended to portray specific parameters of the invention. The drawings are intended to depict only typical embodiments of the invention, and therefore should not be considered as limiting the scope of the invention.

detailed description

Herein, illustrative embodiments will now be described in more detail with reference to the accompanying drawings in which embodiments are shown. However, this disclosure may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the disclosure to those skilled in the art. In the description, details of well-known features and techniques may be omitted to avoid unnecessarily obscuring the presented embodiments.

The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the present disclosure. As used herein, the singular forms "a", "an" and "the" are intended to include the plural forms as well, unless the context clearly dictates otherwise. Furthermore, use of the terms "a", "an", etc. does not denote a limitation of quantity, but rather means that there is at least one of the referenced items. The term "set" is intended to mean a quantity of at least one. It should be further understood that when used in this specification, the term "comprises" and/or "comprises" or "includes" and/or "includes" designates said features, regions, integers, steps, operations, elements and/or or components, but does not preclude the presence or addition of one or more other features, regions, integers, steps, operations, elements, components and/or groups thereof.

Reference throughout this specification to "one embodiment," "an embodiment," "embodiments," "exemplary embodiment," or similar language means that a particular feature, structure, or characteristic described in connection with the embodiment is included in the invention. In at least one embodiment of . Thus, appearances of the phrases "in one embodiment," "in an embodiment," "in various embodiments," and similar language throughout this specification may, but do not necessarily, all refer to the same embodiment.

Referring now to FIGS. 1 , 2 and 3 , embodiments of the present invention provide one or more stationary coils positioned above or below a magnet or a magnet rotor with one or more embedded magnets or Beside, similar to the internal arrangement of the Shurite ammeter. The magnets can be embedded along the outside of the disc rotor, similar to the numbers on a clock, and can be numerous and close to each other or not far and far apart from each other. Additionally, one or more coils are held in a coil plate generally substantially parallel to the magnet rotor. The coils can be placed on the outside of the board device and can be placed closer together or farther apart similar to the numbers on a clock. The provided apparatus further comprises a shaft with a gear ratio for turning the magnet rotor, such as by hand or a motor, to achieve high rotational speeds. A magnet generates an electromagnetic field, which, when rotated relative to a stationary metal coil, generates an electric current.

In an embodiment of the invention, there is no minimum or maximum number of magnets or coils embedded on any device such as a rotor or plate. In one illustrative embodiment, the magnet rotors 100 may each include 32 magnets 101 , and the coil plate 200 may include 8 coils 201 . In general, the more magnets 101 and coils 201 added in the magnet rotor 100 and coil plate 200, the greater the electromagnetic field generated. This allows for the generation of higher (eg, measurable in Volts (V)) potentials and the generation of larger (eg, measurable in Amperes (A)) currents.

In some embodiments, the magnets 101 on the rotor 100 may be positioned and spaced apart from each other by half an inch to many inches, similar to the numbers on a clock. Likewise, similar to the numbers on a clock, the coils 201 on the board 200 can be positioned and spaced apart from each other by half an inch to many inches. The coils and magnets need not be in equal numbers, but should be located in close proximity to allow the magnetic field of the magnet 101 to interact with the coils 201 . In any event, the magnet rotor 100 and magnets 101 may be rotated by a mechanical device 300 (eg, including a manual device such as a crank, or a motor energized or powered by a battery or by one or more capacitors). When rotated in the presence of coil 201 , magnet 101 generates a self-generated Faraday electric field for electric current.

In embodiments of the invention, the holding device arrangement for the magnets 101 and coils 201 (e.g., the magnet rotor 100 and coil plate 200) may be of any shape or size, such as a plate with recesses, a disc, a rotor, or a clock in which One or more magnets or coils may be inserted or embedded. Likewise, magnet 101 may be of any size and shape, and may be made of any magnetic material including rare earth magnets. Coil 201 may be of any size and shape, and may be made of metal or an electrical or conductive material. In some embodiments, coil 201 may comprise a single solenoid coil that may be rotatable or stationary, and may be located in the device of the present invention instead of coil plate 200 . The magnet rotor 100 is fastened and fixed to the frame 500 of the energy machine device by a strong support of wood, plastic, metal or other strong material comprising a support rod or shaft 400 or two or more rods or shafts 400 . The magnet rotor 100 or magnets 101 may be further supported or balanced by bearings 401 and 301 at the ends of the rod or shaft 400 which is attached to the frame 500 of the energy machine device using bearings and couplings.

Frame 500 may be made of plastic, wood, metal or any other material, although a heavy, strong material is preferred to balance the rotation of magnet rotor 100 (or coil plate 200 as discussed below with respect to FIG. 7 ). In embodiments of the invention, it is generally preferred that the materials from which the magnet rotor 100, coil plate 200, and shaft or rod 400 are made are strong and resilient to withstand the strong forces resulting from the operation of embodiments of the energy machine device. Electromagnetic force and electromagnetic torque electrical loads. Likewise, bearings 401 and 301 fastened to the walls of frame 500 may be made of wood, metal or plastic or any other strong material to support strong electromagnetic torque and The velocity of the panel in question (200) is balanced. It should be understood that the magnets 101, rotor 100, and/or coils 201, coil plate 200 can potentially weigh hundreds or thousands of pounds depending on the needs and requirements of a particular embodiment of the invention. Therefore, when one of the coil(s) or magnet(s) rotates, the structure supporting them should be balanced and stable to avoid friction that can cause easy and early wear of parts of the energy machine device. It should also generally be understood that, in embodiments of the present invention, the magnet 101 and coil 201 cannot be rotated simultaneously to generate electricity.

Referring now to FIGS. 1 , 2 and 3 , rotational motion can be induced in the magnet rotor 100 of the magnet set 101 by the mechanical device 300 , while the coil plate 200 remains stationary, via the shaft 400 at a rate (e.g., at The magnet rotor 100 is driven at any rotational speed measured in revolutions (RPM). For example, magnet rotor 100 may be rotated by mechanical equipment at any rotational speed between 5 RPM to over 100,000 RPM such that coil set 201 cross-cuts the flux lines of the magnetic field generated by magnet set 101 . When the coil set 201 cross-cuts the magnetic field or flux lines of the magnet set 101 , this ultimately causes the generation of a current in the coil 201 .

In addition to referring to FIGS. 1 , 2 and 3 , reference is now made to FIGS. 10A-10C . Mechanical device 300 may be initially driven by one of several mechanical, chemical or electrical means. For example, as shown in FIG. 10A , mechanical device 300 may include or be attached to hand crank 300A. The mechanical device 300 may further include a motor 300 energized or powered by the hand crank 300A. In other embodiments, as shown in FIG. 10B , the motor 300 may be initially energized or powered by using a DC/AC battery 800 . In some cases, current from battery 800 may pass through DC to AC converter 700 and/or control drive 600 before being used to power motor 300 . In other embodiments, as shown in FIG. 10C , the motor 300 may be initially powered by a capacitor drive 900 or similar capacitor device or a similar transfer device attached to the battery 800 or a similar power source.

Referring back to FIGS. 1 , 2 and 3 , in an embodiment of the present invention, the motor 300 and gear ratio 303 may be combined to produce revolutions per minute (RPM) from 5 RPM to over 100,000 RPM by the mechanical device of the present invention. It has been demonstrated in laboratory testing that the higher the RPM, the higher the resulting voltage (and likewise the amperage and wattage) generated in the mechanical device of an embodiment of the present invention.

Many magnet and coil device units 1 as shown in FIG. 1 may be arranged in series and driven by a single mechanical device 300 . For example, as shown in FIG. 5 , four magnet and coil device units may be arranged in series and driven by a shaft 400 attached to mechanical device 300 . In FIG. 5 , a total of eight magnet rotors 100 are shown, each magnet rotor 100 having a plurality of magnets 101 . A pair of magnet rotors 100 sandwich coil plates 200 each having a plurality of coils 201 . Likewise, in FIG. 6 six magnet and coil device units are shown in a series arrangement and driven by a shaft 400 attached to the mechanical device 300 . In FIG. 6 , a total of twelve magnet rotors 100 are shown, each magnet rotor 100 having a plurality of magnets 101 . A pair of magnet rotors 100 sandwich coil plates 200 each having a plurality of coils 201 . It should be understood that the series of magnet and coil device units is not limited to four or six as shown in Figures 5 and 6 respectively, but that any number of units may be used. Likewise, there is no limit to the number of individual magnets 101 and coils that may be arrayed across the cell.

As noted above, embodiments of the present invention provide methods and apparatus for generating electrical power to a tangible degree. In one embodiment, similar to the arrangement inside a Shurite ammeter, magnet sets 101 with magnetic force may be placed in close proximity above or below or next to coil sets 201 to generate electricity when one magnet set rotates. The magnet 101 or magnet rotor 100 comprising magnet set 101 as shown in FIG. 1 rotates or the coil 201 or coil plate 200 comprising coil(s) 201 as shown in FIG. 7 rotates while the other plate or rotor remains stationary. A magnetic field surrounds the magnet set 101 and generates current in the metal coils 201 as long as the coil set is within and cross-cuts the flux lines of the magnets 101 or magnet rotor 100 . For example, this current can be used for residential and commercial use and as electricity to power motors and motor vehicles.

"Magnetic field" and "electric field" as used herein refer to the "electromagnetic field" to which the present invention relates. And the electronic field is the core and foundation of the electromagnetic field. In general, the stronger the magnet 101, the more electrons it has available, and the more potential electrical energy that can be generated through the operation of the energy machine device of an embodiment of the present invention. More specifically, stronger magnets radiate more flux lines, and when the flux lines are traversed by the metal coil 201 containing free electrons due to the rotation of the magnet rotor 100 or coil plate 200, the electrons are induced to flow, thereby generating a current . In the laboratory, it has been shown that a magnetic field cannot exist without an electric field, and likewise, an electric field cannot exist without a magnetic field, so magnetic and electric, north and south, negative and positive charges of electricity The charges, the attractive and repulsive forces of this electromagnetic field, the mass and the momentum or the velocity of motion of the mass all form a unified electromagnetic field of an embodiment of the present invention in which an electrical current is safely generated using an energy machine device of an embodiment of the present invention , to provide mechanical force to generate electricity and power itself.

Referring now to FIGS. 1 to 9 , the magnet set 101 and the coil set are disposed in the magnet rotor 100 and the coil plate 200 respectively. In some embodiments, the magnet rotor 100 and the coil plate 200 may have the magnets 101 or the coils 201 firmly fixed on the The concave part is used to withstand the electric torque force and magnetic torque force in the electromagnetic field. In some embodiments, each coil 201 or magnet 101 may be held in place by glue or screws or any other material that holds the coil 201 or magnet 101 securely in place during rotation. Location. Each magnet rotor 100 and coil plate 200 may have any number of magnets 101 and coils 201 of any size and/or shape, respectively. As an alternative to a single magnet, an array of magnets may be used on the magnet rotor 100 . Furthermore, an array of many coils may be used on the coil board 200 .

In some embodiments, the magnets are rare earth magnets and may include neodymium magnets and/or samarium cobalt magnets. In some embodiments, the magnets 101 are the same size and have the same surface Gauss, and in other embodiments the magnets may be different sizes with different surface Gauss from each other. Magnets with stronger and wider magnetic fields may be used as desired to configure embodiments of the present invention.

In some embodiments, the coils 201 may be the same size and have the same gauge wire, and in other embodiments, the coils 201 may be different gauge wires with different metal or copper wires from each other, where only the total resistance (in ohms) will be different. For example, copper wires, silver wires, tungsten wires, gold wires, and other wires of different gauges can be used together to generate more or less current depending on the desired configuration and needs or requirements. Silver, tungsten and gold wires will allow for a greater amount of power than copper, but copper is more cost effective and makes the energy machine devices of embodiments of the present invention more cost effective. In some embodiments of the present invention, the coil 201 may be one or more triangular coils, rectangular coils or square coils. In further embodiments, the coil 201 may have shapes such as trapezoids and trapezoids, among other similar shapes.

The winding metal coil set 201 may be formed by winding a long copper (or other metal) wire in a helical shape. The coil(s) 201 act like a magnet when current is passed or induced. The metal coil 201 has magnetic field lines around it similar to those around a normal magnet, and also forms part of the electromagnetic field of the embodiment of the present invention. As described below, a current is generated on a load (eg, scale 210 or other receiving device) whenever flux lines cross-cut winding metal coil(s) 201 in a full circuit based on revolutions per minute.

According to Faraday's law, electricity is generated each time the magnetic field lines of the magnet 101 intersect the metallic (eg, copper) toroidal coil 201 that is part of a complete electrical circuit. This can happen when the copper loop wire coil(s) 201 move (FIG. 7) or when the magnet(s) 101 move (FIG. 1) to generate electricity.

It should be understood that electricity is generated with every 360 degree rotation of the magnet rotor 100 or coil plate 200 and that the amount of electricity generated is directly related to the number of coils 201 employed. For example, one coil generates 2X the power, two coils generate 4X the power, and three of the coils generate 6X the power. This aspect of the invention of adding coils is not limited to the number of coils as long as the coils are within the magnetic field of the magnet rotor 100 or magnet(s) 101 .

In some embodiments of the invention, the magnet rotor 100 or centrifuge assembly (see below) of FIG. 8 may be rotated by any attached mechanical device 300 where mechanical device 303 is fixed to a mechanical device 300 that is also in motion. In some embodiments, mechanical device 300 may include motor 300 . The motor 300 can be plugged into an electrical outlet or other power source such as a battery which, if a DC battery, can be inverted or rectified from DC to AC. In other embodiments, a delivery device such as a battery (e.g., 6 volt, 12 volt, 24 volt, 48 volt or lower or higher volt battery) or a device with rectifier capacitor(s) may be used or sufficient Other electrical devices that act as delivery means to provide voltage, amperage, and wattage to meet the requirements of a particular motor 300 supply the motor 300 with the rated electrical volts and amperage or wattage. The motor 300 is used to rotate the magnet rotor 100 or the coil plate 200 to start self-generated power. Once activated, the same electricity generated can be used to power the motor 300 at the same time.

Electricity generated by an energy machine device of embodiments of the present invention may be used to recharge one or more batteries used to start the energy machine device while also powering another load such as a home or building or other motor or application. Once the magnet rotor 100 or coil plate 200 or centrifuge of FIG. 8 produces a threshold level of energy, the motor 300 can be unplugged or disconnected from the utility and power to rotation of the rotor 100 or plate 200 is no longer required. , because the energy machine device can now power itself using an electrical device such as a rectifier capacitor(s) or other electrical device sufficient to act as a transfer device to provide voltage, amperage, and wattage to meet the requirements of the motor 300, while providing Electricity to power another load such as a residence, commercial enterprise or other device, machine or motor of any size.

In another embodiment of the present invention, as shown in FIG. 7, instead of rotating one or more magnet rotors 100, the coil assembly 100 is placed and embedded on a coil plate 200, which is provided by an attachment providing mechanical movement force. The device or mechanism or motor 300 rotates while the magnet rotor 200 with the magnet set 101 is stationary and provides flux lines in close proximity to the rotating coils to generate electric current.

Referring now to FIGS. 1 and 2 , in a related embodiment, one or more rotors 100 are attached to a shaft 400 that is fixed into bearings 401 and 301 on opposite sides of the rotor 100 and is passed through bearings and couplings. 401 and 301 are fixed into the walls of the energy machine plant frame 500 . In a preferred embodiment, bearings and couplings 401 and 301 are strong and resilient, but non-magnetic. In some embodiments, wires 208 and 209 are attached to a meter or load 210 to form a circuit, and meter 210 may be configured to display voltage, amperage, or wattage readings.

In some embodiments, a single shaft is used for one or more magnet rotors 100 , where the embedded magnets 101 are rotated or in motion, and only one shaft 400 holds the magnet rotors 100 . At the same time the coil plate 200 with the coils 201 is stationary. Positive 208 and negative 209 leads for electric fields and circuits can be attached directly to coil 201 . The coil plate 200 may be centered on the rotating shaft 400 but not in contact with the rotating shaft 400 , and the coil plate 200 remains stationary and fixed by the holding device 202 which may attach the coil plate 200 to the frame 500 .

In an alternative embodiment, as shown in FIG. 7 , instead, the coil 201 or one or more coil plates 200 are attached to a shaft 400 fixed into bearings 401 and 301 on opposite sides of the coil plate 200, And fixed into the wall of the energy machine plant frame 500 by bearings and couplings 401 and 30 . In this embodiment, electricity is generated by rotating coils attached in the energy machine device, with a single shaft and separate shafts attached to either side of the magnet rotor 100 . A positive lead wire 208 and a negative lead wire 209 with wires or brushes may be attached to respective shafts of each coil plate 200 , wherein the coil plate 200 with the coils 201 is rotated by a mechanical device or a motor 300 . With each shaft rotating against the wire brushes, electrical energy can be captured. Meanwhile, in the embodiment shown in FIG. 7 , the magnet rotor 100 with the magnet group 101 is stationary and may be fixed to the frame 500 by the holding device 202 .

In the foregoing embodiments of the invention, the magnet rotor 100 or coil plate 200 may be heavy (eg, weighing hundreds or thousands of pounds), and thus the magnet rotor 100 ( FIG. 1 ) or coil plate 200 ( FIG. 7 ) Once angular momentum is in motion by a mechanical device rotating the magnet(s) or coil(s) at a high speed or revolutions per minute (RPM), utilizing mechanical device 300 requires either the magnet rotor 100 (FIG. 1 ) or With a small torque of the coil plate 200 ( FIG. 7 ), the magnet 101 or the coil 201 respectively will relatively easily continue to rotate independently in a 360 degree motion for a considerable period of time. The angular momentum according to Figures 1, 5 and 6 provides additional torque propulsion due to the speed or RPM of the magnet rotor and the weight of the magnet and rotor when the coil 201 is at rest, or due to Electromagnetic centrifuge propulsion torque in the case of 7 in which the coil 201 rotates and the magnet 101 is stationary. In any case, any one weight can spin anywhere from 5RPM to 3900RPM to over 100,000RPM and can weigh from 50 pounds to hundreds or thousands of pounds. Continuous rotation (e.g., 24×7) of such aforementioned weights creates mass momentum and relieves the torque force required to rotate magnet or coil centrifuges, thus overcoming electromagnetic centrifuge propulsion torque, to allow embodiments of the present invention to operate from Less power from the motor 300 or gear ratio 303 or any part of the mechanical device produces more current. The less work or torque the motor 300 or gear ratio 303 or mechanical device does, the less wear and tear on the motor and gears and the longer the life of the mechanical device and gears and the lower the maintenance costs.

It should be appreciated that in some embodiments any motor 300 of any mechanical force or size may be used to generate RPM as long as the mechanical force turns the magnet rotor 100 (FIG. 1) or coil plate 200 (FIG. 7). As long as the magnet set 101 or the magnet rotor 100 is attached to the motor 300 or mechanical equipment and rotated with the coil set 201 cross-cutting the magnet flux lines, electric power is generated. Likewise, in some other embodiments, a manual or mechanical device or motor 300 or other mechanical device may be used to rotate a shaft or shafts 400 such that when the mechanical device moves or rotates, the shaft moves or rotates, and in turn Electric power is generated by moving or rotating the magnet rotor 100 ( FIG. 1 ) or the coil plate 200 ( FIG. 7 ).

Embodiments of the invention also include loading or receiving means. In an example embodiment, the receiving device may be a micro/milliamp meter (also referred to herein as a “scaler”) 210 . Scale 210 is an illustrative example only, and is not limiting. Scale 210 is only intended to illustrate the current produced by an embodiment of the present invention. Scale 210 may also be referred to or considered herein as a receiving device that ultimately utilizes the generated current and measures the voltage, amperage or wattage generated and used by embodiments of the present invention.

Referring now to FIG. 4 , in another embodiment of the invention, only a pair of magnet rotors 100 attached to a rotating shaft 400 is shown. A coil plate 200 including one or more coils 201 is between the rotors 100 . As the rotating shaft 400 spins the magnet rotor 100, the flux lines of the magnet(s) 101 are crossed or cut by one or more coils, thereby generating an electrical current. In the embodiment shown in FIG. 4 , wires 208 and 209 may be positioned along an axis of rotation 400 for delivering electrical current to load 210 . For example, electrical transmission at the plate 200 can be achieved by wire brushes disposed on the stationary plate 200 or rotating shaft 400, and at the end of the shaft 400 by wire brushes also disposed on stationary external wires or rotating shaft 400 electricity transmission.

Referring now to FIG. 9 , in another embodiment of the invention, a single eccentric magnet rotor 100 with magnet set 101 is present together with coils 201 or coil plates 200 in an energy generator machine according to an embodiment of the invention. All other elements of the power generator remain the same as discussed above in other embodiments. As the magnet set(s) 100 rotate, their flux lines are intersected by one or more coils 201 or coil plates 200 , causing the generation of electrical current. It should be appreciated that although the coil sets 201 are shown to the side of the magnets 101 , the coil sets 201 may be located anywhere that the flux lines of the magnets 101 intersect the coils 201 as one or more magnets 101 rotate.

Thus, regardless of whether the magnets are inside or outside or right or left of the coil pack 201, as long as one or more coils or magnets are in motion and the other coils or magnets are stationary, an electric field or current is still generated. Vice versa, if any external magnet 101 is in motion and comes close to the stationary coil 101, an electric field or current is still generated. Additionally, in alternative embodiments, the coils and/or magnets may be configured to have linear motion rather than rotational motion. For example, a constant alternating front-to-back position can be used to generate an electric field when passing a magnetic field near the coil. In some embodiments, a single magnet rotor 100 may be fixed and a single coil plate 200 may be rotated.

In a preferred embodiment of the invention, if more than one coil is used, the coils may be placed or connected in parallel or series parallel or series to produce more or less current and power respectively based on desire, need or requirement. In any case, electricity is generated. Coils connected in parallel have less resistance (measured, for example, in ohms), and thus allow a stronger current flow and produce more amps or watts. However, generally a smaller voltage is generated.

Embodiments of the present invention provide methods and apparatus for generating electricity by moving a coil 201 of any size, shape, or other electrical material or moving any magnet 101 of any size, shape, material, or the like. Electricity is generated by the movement of the coil(s) 201 or the movement of the magnet(s 101 ) by a mechanical device or device or any motor 300 that moves the coil(s) or ( magnet(s) such that the coils intersect the flux lines of the magnetic field generated by the magnet(s). The mechanical device moves one or more magnets 101 such that the flux lines of the magnet(s) 101 intersect the stationary coil(s) 201, thereby generating an electric field or electricity. In these respects, it may be desirable to suppress the magnetic field force generated by the magnet(s) 101 to avoid interference with the motor 300 or other similar mechanical or device or electronic devices in or around the alternative energy machine of embodiments of the present invention. magnetic interaction.

Like electrons, protons, neutrons or atoms, magnets have poles surrounding their mass. Like Newtonian gravity or Coulomb negative or positive charges, magnetic forces like electricity or electromagnetic forces like electrostatic forces are inversely proportional to the square of their distance. Therefore, in some embodiments, as shown in FIG. 8, the rotor 100 and/or the coil plate 200 of the alternative energy machine of the embodiment of the present invention can be placed in a centrifuge of non-magnetic stainless steel 503, which is completely Around the foam 502 and the magnetic steel 501 , the magnetic steel 501 completely surrounds or encapsulates or surrounds the coil plate 200 and the magnet rotor 100 . These enclosures contain the electromagnetic field field within them and also minimize or prevent the magnetic flux density field of the magnet 101 from escaping from the centrifuge of FIG. 8 as much as possible. The structure also prevents the magnetic field domains generated by the magnets and coils from propelling motion beyond the alternative energy machine frame 500 when the mechanical device rotates the coils 201 (as shown in FIG. 7 ) or the magnets 101 (as shown in FIG. 1 ) to generate electricity.

The centrifuges of some embodiments of the present invention also provide the advantage of producing greater flux density and intensity in the electric and magnetic domains to generate even greater amounts of current, voltage and wattage as well as suppressing the magnetic field as described. In order to suppress, minimize or prevent magnetic flux density fields, steel centrifuges are used in the walls of the inner partition plates 501, 502 and 503 as described above. Thus, the divider plates 501, 502 and 503 can be made of steel to suppress magnetic fields, but can also be made of any metal or wood or plastic or heat or any hard material for blocking or for blocking or reducing or minimizing (more a) the flux lines of the magnet 101 to avoid interference with the motor 300 or other similar electronic devices or equipment or electronic instruments in or outside the alternative energy machine of embodiments of the present invention. However, due to the radioactive and highly charged nature of uranium rock, uranium rock material is preferable to the aforementioned materials, but magnetic steel and metallic lead are excellent substances that can also be used in embodiments of the present invention or other embodiments of the present invention, This will serve to block or minimize the flux lines of the magnet(s) 101 or the centrifuge propulsion of FIG. 8 . The centrifuge propulsion in the inventive embodiment of the self-powered alternative energy machine is a significant increase in the linear density and intensity of the magnetic flux produced by each of the centrifuges of FIG. 8 . The higher the magnetic flux density and intensity produced by the present invention, the greater the current, voltage and wattage produced and available for the workload. Also, the greater the current and wattage, the less HP and the less FT PD or mechanical force required by the mechanical device or motor 300 .

Electromagnetic field:

Like electrons, protons, neutrons or atoms, magnets and coils have poles around their mass. Like gravity, the magnetic, electrostatic, and electromagnetic forces of electricity are all inversely proportional to the square of the distance.

In an embodiment of the invention, the magnetic field and the electric field embody an electromagnetic field. At the heart of the electromagnetic field is the electronic field of atoms that includes and generates the dual magnetic and electric forces that form the singularity or singular force in embodiments of the present invention. The density and strength propelled by the centrifuge of the radiating Faraday flux lines determine the magnetic and electric fields. The flux line field is also determined by Maxwell waves or frequency. In the present invention, the centrifuge-propelled flux linear density and intensity radiated by the centrifuge-propelled density and intensity increases the magnetic force of the magnets and the electrical power of the coils, resulting in larger amounts of current, voltage and wattage.

As determined by experiments with embodiments of the present invention and energy machine devices according to embodiments, the flux line waves around a magnet are generally constant, but never distributed evenly around the surface of the magnet from north to south poles on and around the magnet . The north and south fields are also weakened and weakened by other electric and magnetic forces of adjacent magnets. Therefore, magnetic and electric fields of this nature and used in a conventional manner are weak, as determined experimentally. Having stronger magnetic and electric fields produces larger currents, voltages and wattages and is therefore desirable and would provide a more cost-effective solution for public use due to little or no investment in additional equipment to regulate the voltage. electricity. Thus, embodiments of the present invention do not require transformers, voltage regulators or inverters to increase current, voltage and wattage. On the contrary, at the rotation speed inside the centrifuge or in the propulsion of the centrifuge, strong magnetic and electric field singularities, electromagnetic fields generate more energy in mass motion or magnet motion or coil motion, proving that the higher the mass motion, the higher the mass motion, the The more electrons or atoms the singular force radiates, thus generating more electricity for public use in a very cheap way. The higher the flux density and strength, the less work or torque or FT PD done by the mechanical device or motor 300 or gear ratio 303, the less wear and tear on the motor and gear and the longer the life of the motor and gear, and alternative energy devices The lower the maintenance cost of the device.

Embodiments of the present invention provide the added advantage of replacing the use of fossil fuels to preserve the environment for the public good and support public health if sufficient and substantial amounts of energy in the form of current, voltage, and wattage are available for public use. Mass, i.e. the motion of the coil 201 or magnet 101 respectively, wherein the electrons of the coil 201 or coil plate 200 are radiated by moving the magnet flux line waves or lines caused by the motion of the motor 300 or any other mechanical device, wherein the magnet 101 Or the rotation or speed of the magnet rotor 100 such that the copper wire coils 201 cross cut the flux lines of the rotating magnet 101 or magnet rotor, so the electrons generate more energy and electricity in this centrifuge propulsion of FIG. 8 .

Additionally, as shown in Figure 3, in embodiments of the electromagnetic field of the present invention, the use of north and south poles can be configured to provide more powerful singularities to generate greater amounts of power. In the laboratory, it has been shown that a magnetic field cannot exist without an electric field, and likewise, an electric field cannot exist without a magnetic field, so magnetic and electric, north and south, negative and positive charges of electricity The attractive and repulsive forces of charge, electromagnetic field, mass and momentum or velocity of motion of mass form a unified electromagnetic field of an embodiment of the invention in which electric current is safely generated using centrifuge propulsion for self-generated electricity and self-powered, Also powers another load such as residential and commercial buildings and motors and other devices that require electricity to operate.

As noted above, all embodiments of the present invention provide methods and apparatus for moving a coil 201 of any size, or shape, or electrical material, etc., or moving a coil 201 of any size, shape, material, etc. Any movement of the magnet 101 etc. generates electricity to generate current, voltage and wattage.

In an embodiment of the invention, as shown in FIGS. 1 , 3 and 4, when the north pole surface and/or the south pole surface of the magnet set 101 or in the magnet rotor 100 are alternated, more current, voltage and wattage are produced. number. In some embodiments, the magnet 101 may be positioned directly adjacent to the coil 201 or coil set 201 in the coil plate 200 with only a thin space between the alternating north and south pole surfaces of the magnet 101 or magnet rotor 100 . This is to maximize the magnetic conversion of power based on the inverse square law and magnetic conversion to generate current, voltage and wattage.

It is generally known in the art that the north and south poles of a particular magnet or magnets are traditionally used in magnetic fields to generate electricity in various applications, where the lines of flux flow from the north poles of the magnets, diverge to converge at the south pole of the same magnet. However, in such an application using north and south poles of one magnet, there is a lower flux line density, which also provides less magnetic switching for generating electricity, and thus this equates to less flux from the coil and magnet interaction. Less electrical power.

In another embodiment of the invention and as demonstrated in the laboratory, for example, instead of utilizing the conventional flux line flow of one magnet 101 flowing from north to south for a single magnet using its flux line density, the present invention also utilizes the alternating change the magnetic poles of the magnets (for example, FIG. 3 ) and in the magnetic north and magnetic south poles of the magnet 101 or the magnet rotor 100, wherein in FIGS. 1, 2, 6, 5, 4, 8, the north and south poles In each magnet rotor 100 of the centrifuge (Fig. 8). The north poles of the poles 101 in the first magnet rotor 100 face directly the south poles of the magnets 101 in the second magnet rotor 100 of the same centrifuge. The north pole of each magnet in one magnet rotor directly faces the south pole of the magnet in the other magnet rotor. For example, in the embodiments shown in Figures 1, 5 and 6, this method is employed. According to laboratory experiments, switching or rerouting the north and south poles of the magnets 101 (using the north pole of one magnet and the south pole of the other magnet) allows the 10 gauge copper wire coil 201 to generate more than three times the voltage. Reversing or rerouting the north and south poles of the magnet 101 is also advantageous because it makes the RPM of the centrifuge more stable when using amps or watts in combination with motors, home commercial appliances, and light bulbs, negating the need for voltage regulators or electrical transformers and gears needs. Nonetheless, embodiments of the invention may use gears, transformers, and voltage regulators to support power generation and regulation.

In one example, when the 16 magnets 101 in the magnet rotor 100 were each alternated with north and south poles in the magnets 101, they were found to interact to produce higher flux densities and strengths for greater power generation and power. Higher flux densities that generate higher amounts of electricity are generated. This higher flux density is significantly more intense and dense when the flux lines travel directly from north to south with the north and south poles of the magnet 101 or magnet rotor 100, and the distance traveled in the laboratory example is less than the distance traveled by the coil 201 or magnet rotor 100 The coil plates 200 are spaced at inch intervals.

In an embodiment of the invention and as demonstrated in the laboratory, and as shown in Figure 8, the magnet rotor 100 and coil plate 200 may be made of magnetic metal laminate or magnetic steel similar to a sealed box or fully enclosed box or Iron or magnetic metal or a non-magnetic metal like stainless steel surrounds, thereby confining the flux lines of the magnet 101 within the centrifuge. This makes the flux density and strength stronger for the coil 201 because the magnetic metal laminate or steel or iron or metal is magnetized by the coil 201 and the magnet 101 making the magnetic field stronger in the centrifuge. Because of this greater flux density and intensity, higher potential differences or voltages can be generated, and thus more current and wattage can also be generated. This is also important for the electromagnetic field and torque power conversion discussed in the Mechanical Device Power section below. As noted above, the stronger flux density and strength to the coil 201 reduces the need for more energy (e.g. HP or FT PD) from the mechanical device or motor 300 and/or gears and gear ratios 303 in order to still produce Lots of voltage, current and wattage. The flux density and strength of the centrifuge produces large amounts of torque, reducing or eliminating any requirement for more power (e.g. HP or more FT PD) that has traditionally limited the generation of large amounts of cheap energy by other conventional applications Electricity is for public use. Stability and consistency of electrical power production in centrifuge propulsion of flux density and intensity also additionally or independently eliminate the need for voltage regulators or electrical transformers and gears other than certain embodiments of the present invention.

In the present invention and as demonstrated by this laboratory, in the embodiments shown in Fig. 1, Fig. 2, Fig. 6, Fig. 5, Fig. 4 and Fig. 8 and Fig. 9, even if not enclosed, the ( A plurality of) magnet rotors 100 and coil plate(s) 200 or magnet rotors 100 and coil plates 200 or a single magnet rotor 100 and coil plate 200 as shown in FIG. 9 may also be driven by the motor 300 . The motor 300 may be initially plugged into an electrical socket or plugged into a battery or a transformer attached to a source of electrical power or a rectifier capacitor or capacitors attached to a source of electrical power. Whether the outlet or battery is set to 110 volts or 220 volts, the motor 300 can be used in motion to turn the magnet rotor 100 and coil plate 200 to generate voltage. The embodiment of the invention shown in Figures 1 and 7 can generate more than 220 volts and generate voltages in excess of one thousand (1000) volts. Some embodiments of the invention such as those shown in Figures 5 and 6 can generate thousands or hundreds of thousands of volts from a 110 volt or 220 volt outlet or a single battery. Therefore, embodiments of the present invention can generate more voltage than the input voltage.

In the illustrative examples and embodiments of the invention described above, smaller volts (eg, 110V or 220V) were used to generate larger volts. The invention itself can also be long lasting, for example, generating 110 volts or 220 volts at 60 Hz, or whatever volts are needed to power the motor 300 from the centrifuge. Thus, embodiments may generate the same amount of volts as if plugged into a 110 volt or 220 volt outlet or plugged into a battery or a transformer attached to an electrical power source or a rectifier capacitor or capacitor attached to an electrical power source for (multiple ) the motion or RPM of the coil 201 or the magnet(s) 101 . At the same time, embodiments can also provide electrical power to power 45KVA and larger residential and commercial appliances, motors, light bulbs.

In some embodiments of the invention, there may be 2 coil plates 200 for each magnet rotor 100 . In other embodiments, where there is a series of alternative energy generators, such as Figure 5, there may be 8 coil plates 200, 4 magnet rotors 100, where the magnet rotor 100 is sandwiched by each of 2 coil plates 200 . In many other variations, there can also be many coil plates 200 sandwiching or being sandwiched by many magnet rotors 100, and the coils 201 rotate while the magnets 101 are stationary, and all the coil plates 200 It can be on the same axis 400 or on many axes like axis 400 . Further, if the coil 201 is stationary while the magnet 101 is rotating, then all the magnets can be on the same axis 400 . There may also be many rows of coil plates 200 rotating on one or many different axes while the magnets are stationary, and many magnet rotors 100 rotating on many axes while the coils 201 are stationary. Therefore, the combination of magnetic rotor 100 and coil plate 200 is not limited as it may be desired to generate hundreds or thousands or millions of volts, amps or watts for private or public use or residential or commercial use, or for motor or motor Powering vehicles, also powering large motors, or generating large amounts of volts or amps for marine or aerospace use. Based on the foregoing, in embodiments of the present invention, there is no limit to the amount of electricity that can be generated to power many homes, communities, or towns or cities. In the present invention, a large frame 500 or many frames 500 can be constructed in any size or size (e.g., as large as a football field is required or larger) with many magnet rotors 100 and many coil plates 200 as previously described, to produce and Provide electricity.

All embodiments of the present invention provide methods and apparatus for placing in motion a coil 201 of any size or shape or other electrical material, etc. or any magnet 101 of any size, shape, material, etc., by a motor 300 Electricity is generated in motion to generate a large number of volts in the electromagnetic field as described above. It is known in the art to use regional and global voltages of 110 or 220 at frequencies between 50 and 60 Hertz. In an embodiment of the invention, from 5 RPM to 10,000 RPM or higher revolutions per minute depending on RPM, coil and magnet configuration and size and if necessary to reduce high voltage transformers for residential and commercial use and other uses Or rotation will support household appliances as well as commercial appliances and motor Hertz frequency. Based on the coil 201 and magnet 101 configuration and size, from 5 RPM to 10,000 RPM driven by the mechanical device or motor 300 or gear ratio 303 described herein, the embodiments will generate a frequency range of 50 Hz (non-US standard) and 60 Hz (US standard) between 110 or 220 volts to support household or commercial appliances and motors at a specific rated speed or rotation and torque. Additionally, as previously stated in the Electromagnetic Fields section above, there is no limit to the current, voltage, and wattage that embodiments of the present invention can produce, as embodiments can be easily upgraded or redesigned to add more centrifuges or Magnets 101 and/or more powerful magnets 101 and more and/or larger coils 201 of any gauge wire. Furthermore, the frame 500 can be made in any size (eg, the size of a 10×10×10 football field) to accommodate hundreds of thousands of coils 201 or coil plates 200 and magnets 101 or magnet rotors 100 . In one embodiment, frame 500 is 2 feet wide and 4 feet long, and is rectangular in shape.

Mechanical equipment power:

As noted above, embodiments of the present invention provide methods and apparatus for moving a coil 201 of any size or shape, or other electrical material, etc., or any size, shape, material, etc. The magnet 101 is in motion to generate electricity. Increasing RPM using the mechanical device or motor 300 can generate torque power; however, decreasing RPM can also generate even more torque power, depending on the needs or requirements of a particular embodiment. The power of mechanical equipment can be measured in horsepower (HP) or foot pounds (FP) combined with RPM ranging from five (5) to over one hundred thousand (100,000) RPM or more. Hand gear or motors of any size are sufficient when producing large quantities of volts, amps and watts, but when a set of gear ratios is applied to proportionally increase the applied torque, even more volts, amps and watts are produced.

In one illustrative embodiment, the mechanical device or motor 300 is set at 1750 RPM and is used to generate from 5 RPM to 10,000 RPM by using a 2:1 gear ratio 303 or set of gear ratios and idler gear 303 . In this illustrative example, using a gear ratio 303 of 2:1, over 10,000 RPM can now be produced using the motor 300 set at a low RPM. Furthermore, in this illustrative embodiment, using three small 14 gauge wire coils 201 and gear ratios, it is possible to generate over one thousand (1000) volts. Furthermore, using one or more coils 201 and also using 8 coils 201 or 16 coils 201 respectively, the motor 300 can also be used to generate current at 50 or 60 Hz at 350-900 RPM with gear ratios of idler gears It is 2:1. As previously mentioned, a sequence of centrifuge units such as the one in Figure 6 can generate power continuously (24x7) as needed or required. By applying gear ratio sets and idler gears 303 to sequential centrifuge units such as the one in FIG. 6 , the electrical production power of such sequential units is greatly increased.

It is known in the art that current or wattage is required to power or run or support loads in electrical circuits such as light bulbs, various appliances (eg, for motors or households) and commercial appliances, and other utilities load. Embodiments of the present invention can generate 110 volts single phase or 220 volts two phase to support household or commercial or public appliances and motors, and can generate from 1 amp to 200 amps to several amps that convert to millions of watts or hundreds of thousands of KVA. thousand amperes. Further, embodiments may be configured to continuously generate current and voltage. Additionally, embodiments are easily upgraded or easily redesigned to add more magnets 101 of any size and wires of any gauge by increasing the generation of volts, amps, and watts according to the specific needs and requirements of a residential, commercial, or industrial setting. More centrifuges of various sizes of coils 201 to produce hundreds or thousands of volts, hundreds or thousands of amps, and thus hundreds of thousands of watts.

In embodiments of the present invention, more than one magnet rotor 100 and more than one coil plate 200 may be added to the power generating centrifuge apparatus of the present invention in order to add more magnet rotors 100 and more coils board 200 (called a centrifuge) to generate more current, voltage and wattage.

In FIG. 7 , the magnet rotor 100 and the coil plates 200 are arranged such that two coil plates 200 are on both sides of one magnet rotor 100 . Likewise, many such clamping arrangements of coil plates 200 or coils 201 through the magnet rotor or many such clamping arrangements of coil plates and magnet rotors are arranged in rows so that there may be dozens of clamping arrangements arranged on one or more shafts 400 magnet rotor 100 and coil plate 200 to produce the desired amount of volts, amps and watts.

Electromagnetic Field and Torque Power Conversion

As described above, embodiments of the present invention provide methods and apparatus for setting a coil 201 of any size or shape or other electrical material or the like in motion while the magnet 101 is at rest, or while the coil 201 is at rest Power is generated by putting any magnet 101 of any size, shape, material, etc. in motion, the device is rotated by a mechanical device or motor 300 to overcome the magnet(s) 101 or(s) during any current generation and work load The electromagnetic torque of the coil 201. As used herein, workload shall mean that a household appliance or other commercial appliance or motor or machine is using the electricity generated by the device of the present invention.

It has been shown in the laboratory that between the magnet(s) 101 and the coil(s) 201 when using current or wattage from the coil 201 or when generating electricity to do work or for a current or wattage workload There is a strong electromagnetic torque. In an embodiment and as found in the laboratory, the electromagnetic torque between the magnet(s) 101 and the coil(s) 201 is proportional to its charge and the product of attractive and repulsive forces, and is proportional to a device arrangement such as , is inversely proportional to the square of the distance between the magnet rotor 100 and the coil plate 200). The closer the proximity of the magnet rotor 100 and the coil plate 200, the stronger the electromagnetic torque or power. This means that the electromagnetic torque of the magnetic field and electric field of the magnet 101 and coil 201 or the magnet rotor 100 and coil plate 200 creates a strong attraction and Repulsive torque. Thus, as in an embodiment, a strong mechanical force from a mechanical device (eg, applied by motor 300) with a certain gear ratio (eg, gear ratio 303) can be used for higher RPM or torque to generate even more electrical current to do work or power a home or business or for residential and commercial use.

Mechanical device 300 and gear ratio 303 with idler gear 303 can be used to drive higher FT PD or HP. As used in an embodiment of the present invention, the HP for the motor 300 may be a minimum of 0.5HP to 50HP or 1FT PD to 330,000FT PD to 1,650,000FT PD to self-generate voltage, current and wattage (hereinafter "Minimum HP or FT PD"). The larger the mechanical device HP or FT PD, the greater the torque to generate more voltage, current and wattage. The more current or wattage used, the more electromagnetic torque is required to stabilize volts and RPM. With the desired mechanical device or motor 300 and gear ratio 303 with idler gears, hundreds or thousands of HP can be used in embodiments to even power a marine or aerospace vehicle. In general, by increasing the HP and FT PD via the mechanical device or motor 300 and increasing the number of gear ratios and the idler gear reducer 303 , a higher HP or FT PD than specified above can be produced.

In the laboratory, it was found that the motor 300 and gear 303 could be used to generate and sustain sufficient voltage, current and wattage to power motors, appliances, residential and commercial buildings. Motor 300HP or FT PD can be amplified by gear ratio 303 with idler gear 303 or idler gear reducer 303 to produce more or desired power or energy. This can be used to generate or self-generate desired amounts of sustainable voltage, current and wattage to charge batteries or for direct (without using one or more batteries or outlets) residential and commercial use, or without using one or more a battery or receptacle to power a residential or commercial appliance or motor directly, or a commercial enterprise without the use of one or more batteries or receptacles, and to overcome the use of voltage, current and wattage to light a light bulb or to such a residential or When commercial appliances and motors are powered, the electromagnetic torque in the magnetic field and electric field exists between the coil 201 and the magnet 201 . Due to the power or current or work load used, the magnetic and electric domains become very powerful force fields with very strong electromagnetic torque forces, so a HP or FT PD is required to overcome these force fields to generate or self-generate electricity to apply to the load or device power.

Electromagnetic torque to generate and use wattage workload or voltage or current is obtained by mechanical means such as a mechanical crank arrangement 300A for manual use, or a motor 300 with a gear ratio 303 that drives FT PD or HP. In one example, a gear ratio 303 of 2:17 using a minimum of two gears 303 may be used to increase or decrease revolutions per minute or revolutions per minute (RPM) for speed. Conversely, if stronger torque is desired, a gear ratio with idler gear reducer 303 can be added. Idling gear reducer 303 is also used to increase or decrease RPM, and increase or decrease torque power, for example, to light a light bulb or to power a residential or commercial home and its appliances and motors, such as vacuum cleaners up to 14 amps each, and by Add the chainsaws that each draw 12 amps and 9 amps, and also add the 300 watt bulbs that draw 17 amps at 110 volts single phase. Embodiments can use single-phase to three-phase residential and commercial buildings as desired. The desired RPM is based on the coil 201 winding and wire gauge and the number of turns of the coil(s) 201 and the number and power of the magnet(s 101) used with the coil(s) 201 or magnet rotor 100 and coil plate 200 or Surface Gaussian.

In an example, a gear ratio of 2:17 can generate electromagnetic torque to generate voltage, current, and wattage from one ampere to more than one hundred amperes, and utilizing a gear ratio with an idler gear reducer, by increasing the HP or FT PD, which can generate hundreds or thousands of volts, amps and watts.

The wire gauge and number of turns of the coil(s) 201 and the number and/or size of the magnet(s) 101 and coil(s 201 ) can be configured as desired. Dimensions shall mean for the coil(s) 201 the gauge of the wire chosen and for the magnet(s) 101 the power or surface Gauss of the magnet(s) 101 . In general, lower gauge wire has lower resistance and therefore draws more current. Likewise, more powerful magnets based on surface Gauss provide more power to the coil(s) 201 to generate more current. Furthermore, a coil 201 with more windings produces more voltage and current. In embodiments of the invention, higher gauge wire (eg, 14 gauge and above) can more than quadruple the amount of volts produced.

With higher volts above 120/240, step-down transformers and circuit breakers can be used to match the required voltage as needed to the amps and watts needed for a home, building, motor, appliance, appliance or other application. To achieve rotational and torque power to generate wattage and current, the gear ratio 303 can be 2:1 or 2:2; or 3:3; or any of 4:4 or 4.1, and the arrangement of gear ratios 303 may be unlimited. A larger gear ratio 303 for speed with a drive and driven gear 303 with an idler gear 303 in between, or conversely a larger gear reducer 303 for higher torques, produces The more current, voltage and wattage available to the workload the greater the speed or torque. Further, there is no limit to the number of gear ratios 303 and idler gears 303 that can be used. In an illustrative embodiment, for example, to produce 800 amps, a 2:2 gear ratio 303 is used at a maximum of 150HP; to produce 1600 amps, a 4:4 gear ratio 303 is used at a maximum of 200HP. HP and the more gear ratio(s) 303 with idler gear 303 added, the stronger the gear 303 for speed and/or more torque to produce unlimited volts, unlimited current or unlimited wattage . Also, the more HP or FT PD added through the gear ratio(s) 303, the more torque is added to produce unlimited volts, current or amps or wattage.

In another embodiment of the present invention, 16 coils 201 and 16 magnets 101 may be used in coil plate 200 or magnet rotor 100 respectively, using 10 gauge wire (each The resistance of the coil 201 is less than 0.3 ohms) to generate 120/220/240 volts to over 2000 volts, 100 amps or thousands of watts to power a house, for example. When each coil 201 is made to a 0.02 ohm resistance, with all coils 201 equal to 0.0026 ohm resistance, thousands of amps are available when the motor 300 and gear ratio 303 provide torque propulsion for the centrifuge. Coils can have lower or higher resistance; the difference is that the higher the resistance, the lower the current, and the lower the resistance, the higher the current. Coils used in embodiments of the present invention have resistances as low as 0.001 ohms, resulting in high voltages and much higher amperages.

Embodiments of the present invention provide methods and apparatus for generating electrical power by setting the coil 201 in motion or the magnet 101 in motion against an electromagnetic torque. In general, a minimum of 5 RPM is required to generate current. In prior art it is generally known that 3400 to 3600 RPM at 50 or 60 Hz is magnetic switching, while the number of coils and their windings can result in much lower or higher RPMs to produce voltage, current or wattage, but At 50 or 60 Hz, a much higher RPM will target a much higher volts. Note that as shown in the embodiment of the present invention, when the magnet rotor 100 or coil plate 200 as specified above rotates while the other magnet rotor 100 or coil plate 200 remains stationary, a higher RPM will produce more torque power to Current is produced, but again, a lower RPM will produce even more torque power, and thus more current. Higher RPMs beyond 600 or 900 and up to 4000RPM will produce higher voltages which may have to be stepped down by a transformer or volt regulator for residential and business use. RPMs above 4000 and up to 100,000 RPM will generate voltage for non-commercial, non-residential use where higher frequencies or Hertz are not a barrier to using the current from the centrifuge.

All embodiments of the present invention provide methods and apparatus for setting a coil 201 of any size or shape or other electrical material, etc., in motion or any magnet of any size, shape, material, etc., by overcoming an electromagnetic torque 101 is in motion to generate electricity to generate voltage, current and wattage. If a motor 300 or mechanical device is used as part of the primary power source for an embodiment, then utilize the battery 800 and inverter 700 (in the case of a DC battery) without using an AC battery, or with the The 2 to 10 amp power requirements of the embodiment's initial start-up time of a few seconds, the gear ratio 303 and the magnet rotor 100 can be powered by the motor 300 to initially generate or self-generate 2 to 30 amps and power the motor 300 such that the embodiment The power generating centrifuge device becomes its own self-generated or self-generated power source to power itself without the need to use batteries or wall outlets for electrical current. Note that when the motor 300 is powered by the self-generated power of the power generating centrifuge device of the embodiment, the amperage used by the motor 300 is equal to or lower than the amperage of the motor 300 at its rating, and this embodiment produces enough current to power the motor 300 and power receiving devices such as residences or commercial enterprises.

Scenario 1:

In the present invention, and as found in the laboratory, many gear ratio tests producing voltage, current and wattage have been successfully done with a motor 300 rated at 1750 RPM and gear ratio 303 with idler gear 303 maximized Generation of FT PD. FT PD or torque is the magnitude of force that multiplies or increases the distance traveled from the center of rotation or center of gravity. (force x distance = torque). Torque can be measured in units such as inch pounds in newton meters or force time distance in FT PD per minute or FT PD per second. Finally, torque is the force acting on another force or mass. In an embodiment of the present invention, the initial motor 300 used to shift to FT PD at 165,000 FT PD per minute with a gear ratio 303 having an idler gear 303 has a gear ratio of 1.9. The motor's 1750RPM times a gear ratio of 1.9 yields 3325RPM. The RPM is more than dual voltage, current and wattage. FT PD also increased significantly from the initial HP or FT PD 0.8, then 16 ten gauge wire coils 201 (0.06 ohms each) in the coil plate 200 were wound for a total resistance of 0.96 ohms. Each coil 201 produces 25 volts for a total of 400 volts, resulting in 416 amps at 50 or 60 Hz.

The present invention can also increase FT PD and/or torque by reducing the RPM from 3,325RPM to 900RPM, such that the gear ratio to convert 3,325RPM to 900RPM uses the same combination of magnets 100 and coils 200 with the same gauge wire and resistor configuration. The actual amperage used in the test was 30 amps. More amperage is available out of the box, but was not attempted during testing. In this case one, it is shown that an embodiment of the present invention generates voltage and amperage at 3325 RPM using a higher speed or rate, and generates voltage and amperage at 900 RPM using a lower speed or rate. A minimum of one or two coils 201 can also be used at 50 or 60 Hz at 3325 RPM.

Scenario 2:

In an embodiment, another gear ratio test was performed using a different gear ratio 303 configuration with idler gear 303 having a gear ratio of 0.625. In this configuration, each coil 201 in the coil plate 200 is 0.021 ohms at a coil wire gauge of 10 for eight coils 201 at a total of 0.0026 ohms across all coils at 125 volts. (tested higher RPM speeds up to 3900RPM and always produced significantly higher volts and amps). This configuration also contains magnet 101 and magnet rotor 100 at 900 RPM, where 125 volts are generated at 900 RPM using motor 300 with a gear ratio with idler gear reducer and FT PD at 825,000 at a gear ratio of 0.6, thus generating 125 volts at 900 RPM for the coil plate Eight (8) coils 201 in 200 produce 20 amps at a minimum of 160 amps with the magnet rotor 100 and magnets 101 at a minimum of 20,000 amps.

Embodiments of the present invention provide methods and apparatus for activating a coil 201 of any size or shape or other electrical material, etc., or any magnet 101 of any size, shape, material, etc., in motion. Electricity is generated using a minimum of less than 137,000FT PDs to overcome electromagnetic torque to self-generate electricity. In this embodiment of the invention, the motor 300 provides 33,000 foot pounds, or uses half the HP to produce 500 volts using a gear ratio with idle gear ratio 303 at gear ratio 2.17.

Embodiments provide methods and apparatus for generating electrical power by putting in motion a coil 201 of any size or shape or other electrical material, etc. or by putting in motion any magnet 101 of any size, shape, material, etc., Any motor 300 wherein any motor 300 used with a gear ratio 303 having an idler gear 303 self-generates or generates more HP or FT in RPM or speed than any mechanical device that any motor 300 is rated for or used as an initial mechanical power source using the gear ratio 303 PD more HP or FT PD. In one embodiment of the invention, a 3 HP (approximately 99,000 FT PD) motor 300 uses a gear ratio of 2.1303 to produce 750,000 FT PD. Thus, using less than 99,000FT PDs to generate or autogenously generate 750,000FT PDs equivalent to 25HP, using starting at 3HP and ending at the equivalent of 24HP or starting at 99,000FT PDs and achieving 750,000FT PDs, autogenously larger amounts have also been achieved electricity. From the foregoing, using a gear ratio 303 of 2.1 with an idler gear reducer 303, if one HP is required to produce or self-generate 6.2 amps, twenty (24) HP produces 148 to 186 amps. Additionally, in an embodiment, a three (3) RPM motor 300 producing 800 amps at a gear ratio 303 of 2.2; and a motor 300 producing 1600 amps at a gear ratio 303 of 4.4 may be used. The greater the gear ratio 303 with the addition of the idler gear reducer 303, the stronger the gear 303 for speed and/or the greater the torque to produce unlimited voltage, unlimited current or unlimited wattage. Furthermore, the more HP or FT PD that is added through the gear ratio(s) 303 using the configuration, the more torque the embodiments of the present invention generate to generate unlimited voltage, current or wattage.

In other embodiments, a motor 300 may be used. The motor 300 can be attached to the battery 800 and inverter 700, or plugged into an outlet, providing microseconds to seconds of start-up and run-time to drive the magnet rotor 100 from five (5) RPM to Nine hundred (900) RPM. In an example, a power generating centrifuge device may be configured with sixteen coils 201 in the coil plate 200 and sixteen magnets 101 in the magnet rotor 100 and generate 320 volts from a 10 gauge copper wire coil at 0.7 ohms, Thus producing 320 volts at a potential 333 or more amps. The motor 300 can draw approximately nine (9) amps, including the starting amps for the motor 300 from the battery 800 or an outlet. In some embodiments, there may also be a start-transfer cut-off switch to deliver about 9 amps to the motor 300 while cutting off current from the battery 800 and inverter 700 or outlet to the motor 300, so that the practice of the present invention now The power generating centrifuge device of the example supplies power to the motor 300 itself for self-generation of its own power.

In other embodiments of the invention, the motor 300 is attached to the battery 800 or plugged into an outlet, providing microsecond to short start-up and run times to enable, for example, eight (8) or sixteen (16) magnets Rotor Magnets The rotor 100 with eg eight (8) or sixteen (16) coils 201 in the coil plate 200 achieves the necessary RPM through the gear ratio 303 . 320 volts can be generated from a coil of 10 gauge copper wire at a total of 0.7 ohms, resulting in 320 volts and amps at a potential of 333. The motor 300 uses approximately 2 to 15 amps from the battery 80 and inverter 700 or outlet, including starting amps for the motor 300 to operate at rated amps, speed and torque. There is an activation transfer cutoff switch to transfer 2 to 15 synchronous (via battery/inverter or wall outlet transformer additional synchronous power compatibility) amperes of current from self-generated its own power source to the motor 300 while cutting off the transfer from the battery to the motor 300 amps, so the power generating centrifuge device of an embodiment of the present invention powers itself while providing additional and sufficient voltage, current and wattage to power a residence and/or commercial building with an appliance, motor or machine .

battery/inverter

In one embodiment, the volts, amperage, and watts are provided to the motor 300 via or as a pass-through current from a single AC or 48 VDC battery 800 or from an AC or VDC battery pack to the motor 300 . In one aspect of the invention, 23 amps are supplied via a 48VDC battery 800 and inverter 700 to one or more motors 300 requiring higher voltage and amperage to power the magnet rotor 100 at 100 The amps generate 120/240 volts and/or more to charge the battery 800, or as current passed from the battery 800 to the motor 300 to power the motor 300, where additional amps/wattage and immediately available amps are useful to the other The device is powered.

In another embodiment, the volts, amperage, and watts are provided to the motor 300 via or as a pass current by the 48VDC battery 800 and inverter 700 which pass 23 amps to power the motor 300, Or as needed and rated, pass through more than 23 amps for larger motors to power the magnet rotor 100 to produce over 700 volts which is stepped down by a transformer to 120/ 240 volts, for example, for residential and commercial use, or to self-charge the battery 800 . Embodiments can generate volts and tens, hundreds, thousands, or millions of amperes as desired, and can operate 24 hours a day, 7 days a week while passing current to power the motor 300 with additional Amps/wattage immediately available to power, for example, a residential, commercial or other type of property with all its appliances including motors, heaters, and other appliances that use electricity from a residential or commercial property or other type of building, for For residential, commercial or industrial use. In this aspect of the invention hundreds of amps or hundreds of KVA are generated by using transformer step down or step up as applicable depending on volts, amps, watts requirements, to commercial and industrial in 2 phase and 3 phase respectively Enterprise power supply. In this aspect of the invention, the use of an additional centrifuge and/or higher gauge wire from 10 gauge to 20 gauge results in thousands of volts which are stepped down by a transformer to digital Hundred Amps or hundreds of KVA, but equally, other gauge wires from 10 gauge to 1 gauge can be used to generate electricity for any type of residential, commercial, industrial and motorized use.

In any of the embodiments described above, the battery 800 and inverter 700 provide voltage, amperage and wattage to the motor 300 via or as pass current through a single AC or 48VDC battery or through a bank of AC or VDC batteries to the motor 300 . Embodiments also provide for a battery charger as an internal or external component of the system, or to otherwise recharge the battery 800 , batteries or battery pack that powers the motor 300 . In one aspect of the invention, 23 amps are provided via a 48VDC battery 800 and inverter 700 to a motor 300 or more requiring higher voltage and amperage to power the magnet rotor 100 at 100 120/240 volts and/or more are generated under amps to charge the battery 800, or as current passed from the battery 800 to the motor 300 to power the motor 300, where the additional amps/wattage and immediately available amps are useful to the other A load (such as a residence) is powered.

A battery charger as an internal or external component of an embodiment of the present invention provides the required or nominal required volts, amperes, watts for charging a battery or batteries or batteries as needed and as has been demonstrated in the laboratory group recharges. The charger may be used to otherwise recharge a battery, batteries, or battery pack that is powering the motor 300 at the desired or nominally required volts, amperes, or watts. Embodiments of the invention may use any motor 300 of any size to rotate magnet(s) 101 or magnet rotor(s 100 or rotate coil(s) 201 depending on whether it is rotating coil or coil plate or rotating magnet or magnet rotor Or coil plate 200, note that only the coil(s) can rotate while the magnet(s) remain stationary, or only the magnet(s) can rotate while the coil(s) remain stationary, and the( ) coil and magnet(s) cannot rotate simultaneously to generate electricity following Faraday's law of electrical and magnetic conversion to generate electricity.

In yet another embodiment of the present invention, the volts, amps and watts are provided directly from two (2) sources to power a residential, commercial, industrial property or building: (1) provide the required or rated levels of volts, amps , centrifuge(s) (i.e., magnet rotor 100 and coil plate 200 assembly) of an embodiment of the invention of Watts and (2) an inverter 700 providing volts, amperes, or watts from a battery 800 or batteries , the battery 800 or batteries are under load while being recharged by the inverter system according to an embodiment of the present invention.

Capacitor-rectifier drive(s)

In an embodiment of the invention, the capacitor rectifier drive 900 (defined herein as storing or holding power for at least 0.2 seconds of the controller tool for immediate reuse) may be used as (in addition to the battery 800 or battery pack) A transfer device for voltage. In embodiments with a capacitor-rectifier 900, the battery 800 or batteries is not required, but may be in place as a precaution in the event the capacitor(s) 900 fail to activate. In an embodiment, the capacitor-rectifier drive 900 may be used as a transfer device for the voltage to the motor 300, which also allows for a cleaner and more stable voltage for 0.2 seconds, and is also used to transfer current (e.g., from a wall outlet or a battery or batteries 800) to the motor 300 that powers or rotates the magnet rotor 300 to generate electricity, and after the volts, amperes and watts are generated by the embodiment, the volts, amperes and watts are passed through ( capacitors are moved to the motor 300 to power the motor 300 rotating the magnet(s) 101 or magnet rotor 100 .

In another embodiment, the motor 300, capacitor(s) or capacitor drive device 900 (e.g., having means to connect the capacitor(s) and a rectifier) are used as single-phase, two-phase or three-phase electrical power to the motor 300 transmission, and also sits between the power generated in the power generating device to power the device, where the power transfer switch is attached to one or more batteries 800 or linked wall outlets or utility company power, and the power is generated by the device itself. Once the device is generating power, the transfer switch is operated to stop the current from one or more batteries 800 or the wall outlet or utility company and simultaneously switch power via capacitor(s) 900 to generate electrical power from the device that is switched on. The motor 300 supplies power, or switches generated power to the motor 300 very quickly (eg, in milliseconds). Thus, embodiments of the present invention power themselves in a manner similar to the battery 800 and inverter 700 embodiments.

Embodiments of the present invention provide methods and apparatus for activating a coil 201 of any size or shape or other electrical material, etc. in motion, or any magnet 201 of any size, shape, material, etc. Self-generated electricity, thereby producing volts, current, or amps or watts. In other embodiments of the invention, one coil 201 or a thousand coils 201 or larger coils 201 with matching or mismatched numbers of magnets 101 and larger magnets 101 with more powerful surface Gauss can be used to generate or Self-generated hundreds or thousands of volts, hundreds or thousands of amps or currents, or hundreds or thousands of watts. Accordingly, embodiments of the present invention can be converted for use in powering any variety of devices including, but not limited to, motor vehicles, instead of using fossil fuels (gasoline, oil, gas, chemicals, etc.), and thus can be used to power devices such as Motor vehicles such as cars, trucks, buses, and ships, ships, and also power aerospace machines or motors or aircraft.

Embodiments of the present invention provide methods and apparatus for activating a coil 201 of any size or shape or other electrical material, etc., or any magnet 101 of any size, shape, material, etc., in motion. Generate electricity that overcomes electromagnetic torque to self-generate electricity using the motor 300, gear ratio 303 to use the gear ratio 303 to self-generate or generate ratios for running the motor 300 or what the motor 300 is rated for or for any other mechanical device at initial energy or RPM Or speed start HP or FT PD more HP or FT PD. In one illustrative embodiment, about 80 amps and 50 volts at about 6 HP are required to power the transmission and gearbox of a motor vehicle in order to power or electrically drive the motor vehicle without resorting to a Or multiple batteries or fossil fuels or chemicals. In an embodiment of the invention, the power generating centrifuge device may be configured to power a car directly (ie, without the aid of one or more batteries or fossil fuels or chemicals) based on the amps generated. Further, a motor vehicle can accelerate this change or configuration of the coils 201 and magnets 101 or the magnet rotor 100 and coil plate 200 of the magnets or coils, thereby adding to the gearbox and gearbox of a motor vehicle self-powered by an embodiment of the present invention of electric power. In all embodiments, by increasing the coil 201 and magnet 101 configuration and the RPM of the magnet rotor 100, the power generating centrifuge apparatus can also be configured to power large motor vehicles such as trucks and buses. With embodiments of the present invention, all motor vehicles will run non-stop or can run or be driven for days, weeks or years without needing to be stopped.

In an embodiment, all motor vehicles that use one or more batteries as their electrical power may be configured with an electrical power generating centrifuge device. Approximately 15 amps are required to charge one or more batteries that power motor vehicles, and to charge or recharge one or more batteries used for residential and commercial motors. In an embodiment, the motor vehicle may operate or may be powered by the power generating centrifuge device uninterrupted since one or more batteries may or will be charged continuously (i.e. seven days a week and twenty-four hours a day). Drive for days, weeks or years without stopping to recharge one or more batteries.

In an embodiment, the gear ratio 303 configuration with idler gear 303 may be presented at a gear ratio 303 with idler gear 303 at a gear ratio of 0.625. The coils 201 may be configured such that each coil 201 in the coil plate 200 has a resistance of 0.021 ohms at a coil wire gauge 10 of sixteen (16) coils 201 . Each coil 201 produces 0.021 ohms, and a total of 0.0026 ohms at 125 volts per coil 201 equals 125 volts, with coils 201 arranged in parallel, producing 110 volts and 320 amps, or sixteen (16) coils 201 producing 20,000 volts , where a series arrangement of sixteen (16) coils 201 with sixteen (16) magnets 101 in magnet rotor 100 produces thousands of potential amperes. (A 54HP motor 300 at 1750RPM could be used to power this embodiment). This embodiment of the invention uses 10,000 RPM for the sixteen coils 201 in the coil plate 200 and the sixteen (16) magnets 101 and magnet rotor 100 at the previously described Gauss at 10,000 RPM with the motor 300 and The gear ratio of the idler gear reducer produces 20,00 volts at a minimum of 3,200 amperes at 10,675 RPM at a gear ratio of 6.1 for sixteen (16) of the coil plates 200 arranged in parallel with the magnet 101 and magnet rotor 100 A coil 201. In the coils 201 of the coil board 200 arranged in parallel or in series, thousands of volts or even more thousands of amperes and watts can be stepped down by a transformer to allow the use of household appliances or motors or electronic instruments utilizing frequencies of 50 to 60 Hz. Furthermore, the coils 201 can be arranged in many phases to allow the use of a smaller number of volts, amperes or wattages by partitioning, for example, with a breaker box in a home, creating many zones or breakers so that the current is used for Powering individual and distinct groups of heavy duty motors or appliances or equipment. For example, an energy generating centrifuge facility could be used to power 50 different single-family homes by placing circuit breakers for each home.

In an embodiment, the gear ratio 303 configuration with idler gear 303 may be presented at a gear ratio 303 with idler gear 303 at a gear ratio of 0.625. The coils 201 may be configured such that each coil 201 in the coil plate 200 has a resistance of 0.021 ohms at a coil wire gauge 10 of one hundred (100) coils 201 . Each coil 201 produces 0.021 ohms at 1,250 volts for each coil 201 with the coils 201 arranged in series producing thousands of potential amps for one hundred (100) coils 201 at 3400 to 10,000 RPM. In this embodiment, the power generating centrifuge may be configured with one hundred (100) magnets 101 and magnet rotor 100 at 10,000 RPM at Gauss as previously described with motor 300 and gears with an idler gear reducer The ratio produces 1,250 volts 201 at a gear ratio of 0.6 at 10,000 RPM in coil plates 200 arranged in series or with one hundred (100) magnets 101 and magnet rotor 100 . In the coils 201 of the coil board 200 arranged in series, thousands of volts, even more thousands of volts or amperes/watts can be stepped down by a transformer to allow the use of electronics utilizing frequencies of 50 to 60 Hz. Furthermore, the coils 201 can be arranged in many phases to allow the use of smaller amounts of voltage, amperage and wattage. For example, an embodiment of the invention can be partitioned like a breaker box, creating many zones or breakers, so that volts, amps and watts are used to power separate and distinct things. For example, one embodiment could be used to power 50 different single-family homes. In some further embodiments, to generate 1000 amps, using gear ratio 303 and idler gear 300 would require 162 HP, and utilizing gear ratio 303 and idler gear 300 would require 324 HP to generate 2008 amps. Using gear ratio 303 and idle gear 300 would require 500HP to produce 3100 amps. Some embodiments of the invention may be used to power aircraft and large industrial equipment.

The foregoing description of various aspects of the invention has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed, and obviously many modifications and variations are possible. It is obvious to those skilled in the art that such modifications and changes are intended to be included within the protection scope of the present invention as defined by the appended claims.

Claims (20)

1. An electrical generator device comprising: a rotating device having an axis of rotation and a mass; at least one metal coil provided on said rotating device; at least one stationary magnet whose magnetic flux field is in contact with the metal coil; a shaft fixed to said rotating device along said axis of rotation; a mechanical motion conveying device in mechanical contact with the shaft; and a gear set having more than one gear ratio in mechanical contact with said rotating device and said mechanical motion conveying device via said shaft, wherein energy is generated when the metal coil passes through the magnetic flux field of the magnet. 2. The electrical energy generator arrangement of claim 1, wherein the rotating device rotates through the magnetic flux field. 3. The electrical energy generator arrangement of claim 2, wherein the rotation is responsive to mechanical or electrical force applied to the mechanical motion delivery device. 4. The electrical energy generator device of claim 1, wherein said at least one stationary magnet is a rare earth magnet. 5. The electrical energy generator device of claim 1, further comprising: A stationary holding device on which the magnet is disposed, the stationary holding device has a central axis, and the central axis is aligned with the rotational axis of the rotating plate apparatus. 6. The electrical energy generator apparatus of claim 1, further comprising a receiving load. 7. The electrical energy generator apparatus of claim 6, further comprising: a positive lead, attached along the shaft, having a distal lead brush end in electrical contact with the coil and a proximal end in electrical contact with the load; and A negative lead, attached along the shaft, has a distal lead brush end in electrical contact with the coil and a proximal end in electrical contact with the load. 8. The electrical energy generator apparatus of claim 1, said mechanical motion delivery device comprising a motor and at least one of the following configured to deliver an initial power supply to said motor: a crank, a battery, an electrical plug, and a capacitor bank . 9. The electrical energy generator apparatus of claim 8, wherein said motor rotates said shaft and said rotating device at a speed to generate sufficient momentum for substantially continuous rotation, and wherein said motor Receive some of the energy generated. 10. The electrical energy generator device of claim 1, wherein said at least one metal coil is a plurality of metal coils, wherein a voltage is generated when said plurality of metal coils pass through said magnetic flux field of said magnet, and The generated voltage is proportional to the number of metal coils. 11. A power generator comprising: a rotating device having an axis of rotation; at least one magnet disposed on said rotating device; at least one stationary metal coil with the magnetic flux field of the magnet in contact with the metal coil; a shaft fixed to said rotating device along said axis of rotation; a mechanical motion conveying device in mechanical contact with the shaft; and a gear set having more than one gear ratio in mechanical contact with said rotating device and said mechanical motion conveying device via said shaft, wherein energy is generated when the magnetic flux field of the magnet passes through the metal coil. 12. The power generator of claim 11, wherein the magnet comprises one of: a rare earth magnet, a neodymium magnet, and a samarium cobalt magnet. 13. The power generator of claim 11, wherein the rotating plate device is rotated in response to mechanical force or electrical power applied to the mechanical motion delivery device. 14. The power generator of claim 11, further comprising: A stationary holding device on which the coil is disposed, the stationary holding device has a central axis, and the central axis is aligned with the rotational axis of the rotating plate apparatus. 15. The power generator of claim 11, further comprising: receiving load; a positive lead wire having an end in electrical contact with the coil and a proximal end in electrical contact with the load; and A negative lead wire having an end in electrical contact with the coil and a proximal end in electrical contact with the load. 16. The power generator of claim 11, the mechanical motion delivery device comprising a motor and at least one of: a crank, a battery, an electrical plug, and a capacitor bank configured to deliver an initial power supply to the motor. 17. The electrical power generator of claim 16, wherein said motor rotates said shaft and said rotating device at a speed to generate sufficient momentum for substantially continuous rotation, and wherein said motor Receive some of the energy generated. 18. The power generator of claim 11, wherein the magnet is a plurality of magnets, wherein a voltage is generated when a magnetic flux field of the plurality of magnets passes through the metal coil, and an output voltage is amplified according to an input voltage. 19. A method of operating an electrical generator comprising: Using an external source to power a motor in mechanical contact with a rotatable device embedded with one of a metal coil or magnet; rotating said rotatable device at least 5 revolutions per minute (RPM); passing a metal coil through a magnetic field by said rotational movement of said rotatable device; generating a current based on the metal coil passing through the magnetic field; disconnect from said external source; The motor is powered with the generated current. 20. A method of operating an electrical generator as claimed in claim 19, wherein at least one receiving device is powered by said generated electrical current.