hello to all I am happy to be on this forum, I have a small concern, I am looking for a solution to create small solar lighting units, anyone with a solution or who can help me will be welcome. best regards

Here is a concept I want to share:

https://youtu.be/mMcVGb_Lahg

In this post, I want to share with you a simple yet effective way to experiment with the back EMF radiant voltage spike, a concept John Bedini spoke of. With a big air core single coil and low voltage zero current pulsing, we can reproduce the same effects.

The idea behind this method is to trigger the high voltage back EMF voltage while holding back and gating the current. By keeping the spike sharp, we aim to use just pure voltage to save on energy usage or requiring very little input drive to produce this back EMF. We take this high voltage zero current radiant sharp spike and send it to two charging batteries hooked up in parallel.

To control the switching pulse width modulation, I use a simple tablet with software waveform generator, an analog sound card port output, and a control NPN switching transistor. The sound output from the tablet, set to a fast frequency of 2 kHz and tight duty cycle of 6 percent, triggers the base of the transistor to rapidly switch an input 9-volt battery, which is sent to a coil to collect the back EMF 30 plus high voltage radiant spike. The input battery doesn't "feel" it much, as we are limiting much of the current from leaving the input source.

This method allows us to achieve John Bedini's "get two for the price of one" trick without needing the wheel part. Even if you don't have a machine shop at the moment, you can still experiment with the Bedini process with this simple and effective method.

Here I show you the concept:

https://youtu.be/QYpwTJJ3lh8

I want to share with you my recent success in improving my Radiant Cap Dump Device. With the use of short and thick wires instead of high impedance test lead clips, I was able to achieve a stable and efficient setup that can maintain a 100 watts load while charging the battery with high voltage cap dump pulses.

The input requirement for this setup is only 9 volts DC and 60 mA from a wall transformer power supply. The rest of the energy, as Bedini would say, comes from the Vacuum or Negative Energy. The battery reacts to the steady high voltage discharges and transduces this pulse into real steady current of 100s of watts while maintaining a v/i curve or charging curve instead of a decline curve as one would expect from a 100 watt load. This is a kind of negative resistor.

In a previous video, I was able to run and maintain a 15-20 watt load from the charging battery without the v/i curve going down. With this improved setup, I am now able to do the same thing with holding a real 100 watts load on the battery while charging it with the radiant cap dump device at the same time. The v/i curve remains stable, and in fact, it starts to raise steadily after 2 minutes of operation.

The video demonstration of this setup is about 15 minutes long, but I wanted to show you start to finish what goes on. At first start, the battery shows a slight voltage drop, but after 2 minutes, the v/i curve stabilizes and soon starts to raise steadily as long as the battery keeps getting that high voltage cap dump pulse 2 times a second. I can hear a kind of boil sound when I put my ear next to the battery, so it must be doing something!

After about 15 minutes of run time in this video, you can see a significant increase in voltage by many points in comparison to the start of this demonstration as the v/i curve goes up. This is an awesome COP value - 9 volts 60mA input and 110 volts 100 watts 60 hertz output.

I hope this information is valuable to fellow experimenters. Please let me know your thoughts and questions in the comments section.

Here i show you the concept:

https://youtu.be/df89mwfPzTI

In this forum post, I would like to share my ideas and experiments with an electromagnetic induction concept that utilizes a huge 1000 feet LMR-400 coax spool to generate back emf spikes. The goal is to transduce this power back into a storage/charging system and achieve free energy.

First Circuit:

The first circuit involves a loop antenna that picks up nearby RF energies. The loop can be made as large as possible, and adding an L/C tank circuit for tuning can enhance its performance. The signal is then rectified by D1 to generate a few volts of DC power. The LMR-400 coax spool is a low loss, thick conductor with low resistance, and a 100 feet coil, which makes it ideal for back emf amps. A small capacitor can be added at D1 and earth ground to further improve the circuit's performance.

The trigger power comes from the ambient energy, and a transistor is used to turn it on and off sharply in the huge coil. The power is extracted from the environment and transduced into the battery as a charge from free energy. The goal is to use around 100mA or less for the controller.

Second Circuit:

The second circuit involves an earth battery that provides a few volts DC of input trigger power. This power is switched into coil L1, which is powered by a low current control circuit that is isolated from the 12-volt battery. The battery charges from the strong back emf pulse of the LMR-400 coil. The idea is to use as little input power as possible into the switching controller to pulse this external power obtained from the earth currents. The power is then transduced back to amps into the battery for free energy charging.

Here I show you the concept:

https://youtu.be/MsG3xQHQIW8

My invention  is a simple, low-cost, self-oscillating system that harnesses the back EMF of two coils to produce a sharp spike of energy that can be used to power devices or charge batteries.
The system uses only a few components to trigger the feedback loop, including a low voltage zener diode and an SCR (silicon-controlled rectifier) to dump the charge of a flash capacitor into one of the coils.


In details, The system is powered by three dry cells, with two of them being integrated into the coils themselves. The coils are wound around magnetic cores, with a thin paper layer in between to act as a dry cell. This setup creates a total of three dry cells, which, when run in series, produce a few volts of power that can be fed back into the system for a back EMF feedback loop. and an SCR diode is used to dump the charge from the capacitor into one of the coils, causing a back emf spike that triggers the system to oscillate. The dry cell acts as a power source, while the coils generate a back electromotive force (emf) due to their magnetic fields. The system is designed to operate as a self-triggering feedback loop, with the triggering voltage of the SCR adjusted based on the output voltage of the coils. The dry cell properties of the coils also create an internal capacitance, which helps the system during "off" times

The addition of a metal core to each coil, with a thin paper insulator between the core and the coil, creates a dry cell effect within the system, effectively doubling the power output of the generator. This is due to the metal cores acting as an anode and cathode, with the thin paper insulator acting as the electrolyte. The voltage generated by the coils and dry cell effect can be added together to create a larger voltage for the flash capacitor to discharge. By using the magnetic cores as dry cells in addition to the paper, the voltage difference between the two coils can be increased, creating a larger voltage output.

It's important to clarify that the "dry cell" in this invention is not a traditional dry cell battery that we commonly use in electronics. Instead, it refers to the phenomenon of creating a voltage potential using a metal core and a thin paper insulator as an electrolyte.

This phenomenon occurs due to the presence of moisture in the air. The thin paper insulator, which is typically made of cellulose, is hygroscopic, meaning it readily absorbs moisture from the air. When this moisture comes into contact with the insulator, it creates a conductive path between the metal core and the coil, allowing for the flow of electrical current.

As the generator operates and produces back emf, the dry cells become charged, providing additional power to the system. This helps to ensure that the generator can continue to operate, even when the dry cell battery runs low or is depleted. When an alternating current flows through one coil, it generates a magnetic field that fluctuates in strength and direction. This fluctuating magnetic field induces an alternating current in the second coil, which is placed in close proximity to the first coil. This phenomenon is known as mutual induction.

The back emf feedback loop is an essential part of the generator, as it allows the system to continue generating power without the need for an external power source. By carefully tuning the values of the components involved, a stable and efficient feedback loop can be established, resulting in a steady stream of electrical power.

To ensure a stable oscillation, a compensator voltage system can is implemented to adjust the triggering voltage of the SCR based on the output voltage of the coils. This helps maintain a consistent feedback loop, allowing the system to operate continuously.

this system is a promising approach to harnessing the energy of back EMF for practical applications. The use of dry cells integrated into the coils themselves, along with the addition of the paper layer, provides a simple and effective way to generate power and trigger the back EMF spikes. With further development and optimization, this system could have a wide range of potential applications in areas such as renewable energy, wireless power transmission, and more. This is why I feel like I must share my research as I go along.

It is possible to modify this dual coil invention to use a small voltage from a dead rechargeable 12-volt battery to start the trigger pulse. Once the feedback starts and maintains in amplitude, you can send the extra energy back into the source battery by inducing the voltage from a third coil and rectifying it back into the dead trigger battery.

In this loop, the source trigger battery would charge up quickly, and the SCR cap dump and voltage compensator stage would adjust accordingly to keep the feedback trigger going from the cap dump into the coil for back EMF spike to maintain feedback. However, it is important to note that the success of this modification will depend on several factors.

Replacing the thin paper electrolyte with a more durable and long-lasting material would be a crucial step for large-scale production and use as a power plant. Some possible alternative materials could be polymer or ceramic-based electrolytes, which are known for their durability and resistance to environmental factors. However, further research and development would be necessary to determine the most suitable material for this specific application.

The wearable version of my invention involves using the human body as an electrolyte in between two wearable coils that trigger a back EMF spike. This works similarly to how original idea works, but instead of using a thin paper in between the two coils, the body would be used as the electrolyte.

To make this work, we need to modify the coils and make them wearable in some way. The wearable coils generate back EMF and work in a feedback loop with two coils to trigger the back EMF spike. This would wirelessly charge devices such as cell phones, tablets, and small laptops in pockets and bags near the body where the wireless radiates.

The human body would not be the power source, but rather used as a low voltage trigger pulse to start the back EMF spike feedback loop. As long as the frequency is kept safe for humans and the current is not too high, it could be explored as an alternative option to wireless charging.

Wireless power transmission using electromagnetic fields has the potential to revolutionize the way we power and charge our devices, and my invention offers a breakthrough in this field. By utilizing the back electromotive force (back emf) generated by the coils, an oscillating magnetic field can be created and received by a resonant coil tuned to the same frequency. This enables multiple devices to be wirelessly powered or charged simultaneously, without the need for cumbersome cords or charging pads.


Moreover, the excess energy generated by the back emf can be harnessed for wireless power transmission to nearby devices. This is achieved by employing a resonant coil in the transmitting device to create an oscillating magnetic field that can be received by a resonant coil in the receiving device. This energy can then be converted into electrical power, offering a seamless and efficient way to power our devices.

As such, my invention offers tremendous potential to be a key component in making wireless power transmission a reality. With the ability to wirelessly transmit power to multiple devices at once and the potential to harness excess energy for further power transmission, the possibilities for this technology are endless. This breakthrough has the potential to significantly impact our daily lives and offers a sustainable and efficient solution to powering our devices.

Here is the method in details:

https://youtu.be/uxGdLtpGmSY

Here's an overview of how such a system could work:

A piezoelectric material is placed inside an audio chamber or resonator, which is designed to amplify and sustain a specific frequency of sound wave. The size and shape of the chamber, as well as the material properties of the piezoelectric material, would be carefully chosen to maximize the acoustoelectric effect.

The electrical signal generated by the piezoelectric material is then used to trigger a back EMF coil loop,The feedback loop created by the back EMF coil loop will help sustain the sound wave within the chamber, and thus the acoustoelectric effect.

the system is first triggered by an external force, like a tap on the audio chamber or a burst of sound. This causes the audio chamber to resonate and the piezoelectric material to vibrate, generating a voltage spike that is fed into one of the coils (let's call it the "trigger coil") of the back EMF loop. The back EMF loop consists of two speaker coils, which are also used as part of the audio feedback loop. As the back EMF loop generates a voltage spike, it causes the speaker coils to vibrate, which in turn keeps the audio feedback amplitude strong in the audio chamber, sustaining the vibrations of the piezoelectric material.

The audio tone generated by the speaker is then fed back into the audio chamber, where it reinforces the original trigger, causing the speaker to continue vibrating and generating a sustained feedback loop. This sustained feedback loop keeps the back EMF and audio tone going, allowing the system to continue generating electricity.

So in summary, the speaker has two jobs in this system: (1) to generate the initial voltage spike and (2) to vibrate and generate an audio tone that sustains the feedback loop. By using the speaker in this way, we can create a self-sustaining system that generates electricity without the need for an external power source.

The sustained sound wave within the chamber will continue to cause the piezoelectric material to vibrate and generate electrical signals, which can be used as triggers for the back EMF coil loop. As long as the feedback loop is maintained, the system should be able to sustain itself without any external power input.

The output of the back EMF coil loop could be used to power a load, such as a battery or electronic device.

Overall, the key to making this system work would be careful design and optimization of the audio chamber, the piezoelectric material, and the back EMF coil loop. The system would also need to be carefully tuned to the resonant frequency of the audio chamber to maximize the acoustoelectric effect. The audio chamber needs to be designed to resonate at the same frequency as the speaker coils' optimal frequency, which is also the frequency of the audio tone that triggers the back EMF loop. This resonance will amplify the audio tone and maintain the feedback loop, which allows for the back EMF to bounce back and forth between the coils and generate power that can be tapped into. The resonance can be controlled and maintained by adjusting the size and shape of the audio chamber and the frequency of the audio tone.

One advantage of this approach is that it doesn't require any external power source or battery, making it self-sustaining. Another advantage is that it could potentially be made from low-cost materials, such as piezoelectric ceramics and simple audio speakers.

it's true that traditional loudspeakers can suffer from significant energy losses, and piezoelectric transducers can have relatively low efficiencies, the proposed system is not based solely on either of these components. Instead, it combines the unique properties of piezoelectric materials and audio chambers to create a system that is designed to maximize the acoustoelectric effect and minimize losses.  In addition, the system utilizes a back EMF feedback loop to sustain the sound wave within the audio chamber, which further increases efficiency. While it's true that no system can be 100% efficient, this approach has the potential to generate usable amounts of electricity without an external power source.

Here I explain the concept:

https://youtu.be/6TvkTgjHn2M

Here I explain how this system can be self sustained, some details on the background of my existing inventions and experiments. Since people are interested, this is a big message and could change the way we all live our regular lives and help the planet if this message happens to not fall on all deaf ears, I'm talking about those who can make the changes like the law makers and our politicians. We may have a chance!!!!!  I'm open for discussion so tell me what your thoughts are in the comments!

In a typical electrical system, when a current flows through a coil, it generates a magnetic field around it. When the current is turned off, the magnetic field collapses, which generates a voltage spike known as a back electromotive force (EMF) in the opposite direction of the original current. This voltage spike is often seen as a nuisance and is usually suppressed using diodes or other techniques.

However, in this system, we are using this back EMF spike to our advantage by redirecting it back into the system to provide additional power. The back EMF spike is essentially a burst of electrical energy that can be captured and redirected to charge the capacitor, which is then used to trigger the induction coils again. This feedback loop allows for a continuous flow of energy, amplifying the original energy input.

When the back EMF spike is redirected back into the system, it is essentially converting energy that would have been lost as heat or other forms of energy into a usable form. This allows you to take advantage of the higher amplified amplitude energy that would otherwise be wasted. By using this feedback loop, you are essentially increasing the efficiency of the system and allowing it to output more power than what was originally put in.

It's important to note that this doesn't violate the laws of thermodynamics, as the system is not creating energy out of nothing. Instead, it is redirecting and amplifying the energy that is already present in the system.

Here I show you the Tuned L/C Feedback Method.

https://youtu.be/IHW5G-u6u2I

Tuned L/C Feedback Method

In the pursuit of creating more efficient energy systems, we often overlook the importance of feedback mechanisms. Feedback is essentially a process where a portion of the output of a system is returned to its input, creating a loop that can enhance or stabilize the performance of the system. In energy systems, feedback can be used to recycle lost energy and improve the overall efficiency of the system. In this forum post, we will explore some feedback methods using a pure AC trigger and L/C oscillation feedback.

First, let's take a look at the pure AC trigger feedback method. This method involves using an AC signal to trigger a switch that controls the flow of current in a circuit. The switch is connected to an inductor and a capacitor, which form an LC circuit that can oscillate at a resonant frequency.

When the switch is closed, current flows through the inductor and charges the capacitor. As the capacitor charges, the voltage across it increases until it reaches a threshold level, at which point the switch opens and the capacitor discharges through the inductor. This causes the inductor to generate a magnetic field, which induces a voltage in the capacitor and completes the feedback loop.

The oscillation frequency of the LC circuit is determined by the values of the inductor and capacitor, and can be adjusted to match the frequency of the AC trigger signal. This ensures that the switch is triggered at the optimal time to maximize the energy transfer between the AC signal and the LC circuit.

Next, let's look at the L/C oscillation feedback method. This method involves using an LC circuit to generate an oscillating current that can be fed back into the input of the system. The LC circuit consists of an inductor and a capacitor, which are connected in series and form a resonant circuit that can store and release energy.

When a current is applied to the LC circuit, the capacitor charges and the inductor stores energy in its magnetic field. As the capacitor discharges, the inductor releases its stored energy and generates a magnetic field that induces a voltage in the capacitor. This causes the cycle to repeat, creating an oscillating current in the LC circuit.

By connecting the output of the LC circuit back into the input of the system, we can create a feedback loop that can recycle lost energy and improve the efficiency of the system. This is because the oscillating current generated by the LC circuit can amplify the input signal and help to overcome losses due to resistance and other factors.

In conclusion, these two feedback methods using a pure AC trigger and L/C oscillation feedback are just a few examples of how feedback can be used to improve the efficiency of energy systems. By creating a loop that recycles lost energy, we can tap into energy sources that would normally be wasted and make our energy systems more sustainable and efficient. However, it's important to note that these methods are not 100% efficient and there will still be losses due to various factors such as resistance in the circuit and the limitations of the components used.

It would be best to use the mains positive cycle AC as the input trigger and diode both coils with their own "isolated" trigger. This way each L/C will behave electrically independent. It is important to note that there is reason for the imbalance in the system, as it allows for the resonance effect to increase the amplitudes of each L/C circuit. As a result, you will most likely need to calculate two separate values for the capacitor.

While at first glance it may seem like you are just shorting the + of one circuit with another + doing nothing, both L/C circuits are actually working independently and raising amplitudes. The imbalance creates a difference potential between the two separate L/C circuits, which can be 100 volts or more depending on the coil setup. This effect takes advantage of the closest equivalent we have of running a coil as a "superconductor" within the system.

The neon in this example keeps the path closed between the plus input trigger side of both L/C circuits until a voltage buildup difference between the two positives reaches the neon voltage trigger of around 80 volts. At this point, the neon briefly creates a path in the 3rd coil (flash spike) and dissipates the extra energy as a load into this coil, preventing the oscillations from building up to high voltage and current breakpoints.

This process is often referred to as "Splitting The Positive" within the free energy community, as it involves switching the potential difference of two raising voltages rather than switching a typical system traditionally. The "energy" in this system comes from the voltage difference between the two coils that is switched into a load (the 3rd coil). By using this method, we are able to extract much more energy from the system that would normally be lost and convert it back to watts.

Here is the Caduceus coil back EMF method.

https://youtu.be/N3Xy-tEQV4E

The caduceus coil is an intriguing concept that has the potential to revolutionize the field of energy production. This type of coil consists of two parallel conductors wound in opposite directions and twisted together, which results in canceling out the magnetic fields they generate. While this may seem like a disadvantage at first glance, it actually presents some unique opportunities.

One of the key benefits of the caduceus coil is that it reduces losses due to the magnetic field. In a conventional coil, a significant amount of energy is lost due to the magnetic field generated by the current flowing through the conductor. However, with the caduceus coil, the energy is still present but in a less useful form - heat. By capturing the back electromotive force (EMF) generated when the current is turned off, it is possible to recover some of this energy that would otherwise be lost as heat.

This makes the caduceus coil a potentially more efficient option for energy production. By reducing losses due to the magnetic field and recovering some of the energy that would otherwise be lost as heat, it may be possible to achieve a net gain in usable energy that could be used to charge batteries or power other devices.

However, it's important to note that this method is not 100% efficient and there will still be some losses due to various factors such as resistance in the circuit and the limitations of the components used. Increasing the mass of the coil can help to increase the amplitude of the back EMF spike, but it can also increase the overall impedance of the coil, leading to more losses in the system. Finding the right balance is key.

It's also important to be aware that the caduceus coil is considered a powerful "scalar" wave generator, and as such, there is still much we don't understand about the quantum physics of such "Zero" waves. Proceed with caution and be mindful of the potential risks associated with working with this technology.

In conclusion, the caduceus coil presents a unique opportunity for more efficient energy production. By reducing losses due to the magnetic field and capturing back EMF, it may be possible to achieve a net gain in usable energy. However, this method is not without its limitations, and further research and experimentation are needed to fully understand the potential of the caduceus coil.

Good day folks here is my youtube video demonstrating this concept:

https://youtu.be/hBM6Bw35dbk

In this forum post, we will explore the concept of energy transfer and manipulation using a resonating flat coil and an induction loop. The resonating flat coil is capable of storing and releasing energy in sync with the input signal, resulting in a stronger output signal. Additionally, the resonating flat coil can induce a larger current in the induction loop when placed at a certain distance from the coil, due to the stronger magnetic field generated by the oscillating coil.

It is essential to understand that the energy transfer between the flat coil and the induction loop is a separate process from the input signal that triggers the resonating flat coil. While the input signal sets up the resonant frequency of the coil and causes it to oscillate, the energy transfer between the coil and the induction loop is a result of the amplified magnetic field generated by the oscillating coil.

However, the strength of the output signal will depend on various factors, including the resonant frequency of the flat coil and the distance between the flat coil and the induction coil.

One of the exciting possibilities of this energy transfer is that it can be used to power devices such as a rectifier and battery charger, making the system self-sustainable. By taking advantage of multiple existing energies available to the system for usage that would otherwise be wasted, we can create innovative and sustainable devices.

However, it is crucial to note that the statement that energy cannot be created or destroyed can be misleading. While it is true that energy cannot be created or destroyed, it can be manipulated and converted into other forms. By working together, multiple energy systems can be used to make up for losses from another energy system, and a net gain of electricity energy can be observed. This does not violate any laws of thermodynamics and merely requires us to think a little outside the box.

In conclusion, the resonating flat coil and induction loop provide an excellent example of how we can manipulate and transfer energy to create sustainable and innovative devices. By understanding the principles behind energy transfer and taking advantage of existing energies, we can create new possibilities for energy use and production without violating the laws of thermodynamics.