Joe Flynn’s Magnetic Amplifier - The Hidden Science of Free Energy
The motor invented by Joe Flynn can spin its rotor at an incredible speed using only a small DC power source - a 6V to 12V battery. The input power for this motor ranges from about 5 watts to a few dozen watts, yet the output - expressed as the kinetic energy stored in the flywheel - can reach the equivalent of 10 kilowatts when converted back into electricity. Flynn’s invention, if fully developed, could make the oil and fossil fuel industries obsolete. That may be one reason why his technology has never been embraced or expanded upon by mainstream engineering universities.
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| Induction Motor with Built-in Alternator Coil - Flynn Free Energy Generator |
On the other hand, this abundant kinetic energy from Flynn’s motor could easily replace traditional energy sources such as wind or hydroelectric power. Some believe that major power plants around the world use alternative technologies to generate electricity. Massive hydro or nuclear power stations might merely serve as façades, hiding the real mechanisms within. It’s been suggested by several independent energy researchers that large-scale plants in China, the U.S., and Europe could already be using free-energy transformer systems to supply power to the public. They’ve even presented block diagrams and sample circuits to support this idea - but that’s a long story for another day.
Overview of the Flynn Motor
Charles J. Flynn is the inventor and developer of this remarkable motor. One of his key patents, Methods for Controlling the Path of Magnetic Flux from a Permanent Magnet and Devices Incorporating the Same (US6246561B1), forms the theoretical backbone of its operation.
In 2006, the STAIF conference - one of the most respected scientific forums in the United States - confirmed that Flynn’s motor indeed performed as described in the patent. In essence, its output mechanical power exceeded its electrical input.
A final note is often repeated among researchers: Why didn’t Joe Flynn openly claim this as an “over-unity” device? The answer lies in pragmatism. First, his invention merely leverages and redirects existing field energy; it doesn’t create energy ex nihilo. Second, one can imagine how impossible it would be to market a motor that produces 2.5 times the torque that a power company supplies. The scientific orthodoxy would never tolerate it. Flynn may have chosen to stay within conventional parameters - say, 99.9% efficiency - just to keep the “physics police” off his back. Even that level of performance is extraordinary.
Fundamental Principle of the Flynn Motor
What Flynn called “magnetic amplification” is the essential mechanism behind the torque-generating force of his motor.
In simple terms, it intensifies magnetic attraction on one side and magnetic repulsion on the other side of the rotor, producing high-speed rotational motion.
A key point to remember is that the stator coils are powered only by a direct current (DC) source, such as a battery.
The measured electrical input - based on voltage and current - is very small, typically between 5 and several dozen watts.
Yet the resulting push and pull forces from the permanent magnets are enormous due to the configuration known as the Parallel Path Magnetic Amplifier or Parallel Path Magnetic Technology (PPMT).
PPMT is an advanced field-control method applicable to motors, rotary and linear actuators, magnetic latches, and electrical generators.
It employs permanent magnets whose magnetic flux is directed and amplified by control coils within parallel magnetic circuits.
This concept, both revolutionary and practical, has been successfully demonstrated across various devices.
Flynn Research Inc. holds both the general and specific patents covering PPMT designs.
The laminated transformer-type steel plates positioned on the left and right sides (in the original diagram) act as magnetic flux intensifiers, focusing and channeling the amplified field used in the motor’s operation.
The rotor contains five poles, each fitted with permanent magnets, designed to produce torque efficiently when DC voltage is applied.
The stator has one active pair of poles - one attractive and one repulsive - each composed of two sub-poles, totaling four minor poles but functionally one magnetic pair.
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| EXPERIMENTAL DATA & ANALYSIS |
The five-lobed rotor, with magnets mounted on each pole, develops a torque once the DC source is applied.
Here’s why: an attracting pole on the rotor undergoes different phases - initially being drawn toward the stator’s field center, then being pulled back after passing through the neutral plane.
Ordinarily, a simple magnet would not continue rotating, as it would “lock” when attraction reverses at the center of the strongest pull.
However, according to Flynn’s design, when one of the five rotor poles reaches its peak attraction (aligned with the yellow stator magnet in the diagram), the opposite poles simultaneously experience peak repulsion.
The result is a continuous torque - one side pulls, the other pushes - establishing steady rotational momentum.
The full process is more complex than this simplified description, and no university or published study has yet provided a mathematical model that accurately describes these sequential phases of magnetic attraction and repulsion.
Analyzing these dynamic field transitions remains an open challenge for experimenters and field theorists alike.
Another remarkable principle of the Flynn Motor is that its input current does not increase under mechanical load.
Even when the rotor’s motion is resisted, and kinetic output power approaches 10 kilowatts, the coil current remains essentially constant.
This feature is both an advantage (from the free-energy perspective) and a limitation (for applications requiring sustained torque such as grinders or saws).
Thus, the Flynn Motor is best suited for generating steady mechanical energy or driving electrical generators under constant load.
A final note: the coil winding direction (clockwise or counterclockwise) and the polarity of the electrical terminals must be correct.
As shown in the diagram, the red side of the coil connects to the positive terminal of the battery.
If only one coil pair is used, the leads should be cross-connected in series to maintain proper magnetic orientation.
Applications of the Flynn Motor
1. Stable-Load Drive Systems
The Flynn Motor performs best in systems operating under steady mechanical resistance.
It is not suitable for tools such as grinders, saws, or mechanical machines that experience irregular or variable loads.
Where the torque demand remains constant, the Flynn configuration delivers outstanding stability and efficiency.
2. Motor-Generator Hybrid for Battery Charging
The motor can also function as part of a pulse-charging generator system.
Once steady rotation is achieved, the mechanical motion can be transferred to a secondary flywheel.
Attach several permanent magnets around the flywheel’s rim, and position pickup coils around it to capture the induced high-voltage pulses.
These pulses can be used to charge a series of batteries (a battery bank).
The stored energy from the batteries is then supplied to an inverter, which produces AC power.
This configuration is conceptually similar to John Bedini’s pulse battery-charging technology - proven to be simple, inexpensive, and more efficient than traditional solar systems.
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| Bedini Motor |
Many independent developers have demonstrated that Bedini-style systems provide greater energy return for far lower cost compared to expensive photovoltaic installations.
3. Direct Mechanical Drive for Existing Generators
Another straightforward application is to connect the Flynn Motor’s mechanical output directly to a commercial AC generator via a shaft coupling.
Such generators are widely available on the market, designed for industrial or private use.
As long as the motor delivers a steady rotational speed, the generator will produce a constant output voltage, since most models include an internal voltage regulator.
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| Induction Motor Connected to AC Generator |
The image above shows that the connection of induction motor to AC generator has been going on and promoted in the market for many years, but only retail and little known. Image link: 20KW Low Speed Permanent Magnet Generator 110V 220V 380V OR: Motor Drive
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| Low RPM Electric Power Generator |
Recommended generator to connect to Flynn motor: 20KW Permanent Magnet Generator 220V 380V 110V 72V 30KW 10KW Low RPM Electric Power Generator Free Energy 3 Phase AC Output Home
Even if the rotational speed increases, the output voltage remains fixed (110V or 220V), while the current - and therefore total power - increases.
This is precisely the kind of workload that the Flynn Motor excels at.
If you do not use a separate generator to connect, you can ask the manufacturer to always integrate the generator coil on the Stator as shown in the original drawing of the article when the Overunity motor is actually running. The Flynn motor is an Overunity (free energy) motor, but it must first be successfully created before considering connecting to a generator or installing an integrated generator coil. So see the instructions below.
Constructing a Flynn Motor
To build a working prototype, approach a professional Motor Design & Development Company and explain your concept.
You should understand your schematic well enough to communicate clearly with their engineers.
Even if your drawing consists only of a front or side elevation, they can generate complete CAD models and production-ready blueprints.
When describing your design, make sure to specify that:
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The stator core (the yellow magnetic region in the diagram) should be made of laminated soft magnetic steel, not ferrite.
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The rotor should include five magnetic poles, each embedded with a permanent magnet, as shown in the illustration.
With that information, the engineers will understand the intent and prepare manufacturing drawings for fabrication.
They will also help design the housing, supports, and mechanical fittings.
It is advisable to let them handle the entire assembly so you receive a fully operational motor ready for testing or use.
Although the Flynn Motor has been known to researchers for years, few have advanced or commercialized it.
Some cite technical limitations, others point to legal and institutional barriers within the so-called New World Order (NWO) structure of global energy control.
For that reason, if you commission a prototype for private or small-scale production, you need not worry about patent exposure or competition.
Small workshops can legally produce and sell these units as custom, hand-built devices, much like other experimental machines or personal energy systems.
This remains an open opportunity for independent engineers or inventors interested in bringing the Flynn Motor concept into small retail circulation — not as mass production, but as custom-built, personal devices.
Note. Some other nouns that indicate where you can create a Flynn engine on demand: Machine shop, Prototype workshop, Prototyping lab, Electromechanical lab, Motor design company, Engineering consultancy, Design bureau, FabLab, Makerspace, Hackerspace, Contract manufacturer, Custom manufacturing shop, R&D workshop, Magnetics research center, Applied physics lab, Rapid fabrication lab, Experimental engineering lab, Technical fabrication shop, Motor prototyping facility, Precision machining center
A Practical Approach to Free Energy for Your Home
Constructing a Flynn Motor and coupling it with an AC generator to produce a continuous 10-kilowatt electrical supply for your home is technically feasible.
However, the total cost can range anywhere from a few hundred to several thousand dollars, depending on your materials, fabrication, and design precision.
For this reason, I propose a step-by-step instructional framework - a progressive guide that moves from simple modifications to advanced energy independence.
The goal is to help you reduce your power bill first, then work toward full off-grid autonomy.
At the basic level, you can make minor interventions in your home’s electrical distribution board:
installing additional inductive coils, capacitive filters, or reactive feedback components to improve phase balance and reduce apparent power draw.
Such optimizations alone can lower your monthly energy cost significantly.
At a higher level, the guide would walk you through the process of constructing your own low-cost generator - a system that uses mechanical, magnetic, or hybrid energy conversion principles similar to the Flynn concept - enabling you to power your home independently, without reliance on external utilities.
Summary at a higher level:
※ Transistorized snap-off tech harnesses energy from dielectric inertia.
