Here I explain the concept:

https://youtu.be/AjdURCTv4Mk

The process of generating an AC source from a phone line might sound like an impossible feat, but with the right equipment and knowledge, it is actually quite feasible. By utilizing a simple and efficient process of pulsing the phone line with a positive voltage, it is possible to create a 60Hz compatible AC source.

The process involves the use of a NPN transistor as a switch, which rapidly opens and closes the circuit to produce the desired frequency. The speed of the switching can be fine-tuned to produce a stable and reliable AC output. By using this method, it is possible to power small current devices such as LED bulbs.

To generate a higher voltage, an AC step-up transformer is employed. This device boosts the voltage from the phone line to a much higher level, typically around 110 volts AC. This voltage is more than enough to power small current devices and provide adequate lighting for a small space.

In conclusion, by pulsing the phone line with a positive voltage and utilizing a NPN transistor switch, it is possible to generate a stable and reliable AC source. By using an AC step-up transformer, this voltage can be boosted to power small current devices, making this a practical and cost-effective solution for lighting in certain situations.

Here I show the concept:

https://youtu.be/2GTu-Z811zI

In this video, I demonstrate a water-powered battery oscillator that I created using copper oxide and water. I discovered that by placing copper oxide in individual cups of water, I could generate enough voltage to power an AM broadcast transmitter. To take the project a step further, I separated the batteries into two packs, with the primary water battery running a simple flyback-type NPN-based oscillator.

To control the switching of the isolated water battery 2, I filtered the DC pulses generated by the oscillator with an on-board diode and sent them into the base of a PNP transistor. These pulses were then rectified back to DC and sent back into the primary oscillator circuit as feedback. What I observed with this type of "battery" is that it is capable of maintaining a charge indefinitely, as long as it is pulsed and given a short break to build up another charge of current through the chemical reaction.

This device also charges a single regular rechargeable AA 1.5 volt battery in about a day. As for the water battery, I found that it needed to have its water changed every few days due to a build-up of corrosion. Nevertheless, this is an interesting concept with potential for further experimentation and development.

Here I show the concept:

https://youtu.be/4ubmNVDp-oU


This project involves the use of a copper oxide layer and water to create a functional water "battery" that can power an AM broadcast transmitter. Taking the project one step further, the batteries were separated into two packs, with the primary water battery running a simple flyback type NPN based oscillator.

To enhance the performance of the circuit, DC pulses are filtered with one of the electronic lab's on-board diodes before being fed into the base of a PNP transistor, which controls the switching of the isolated water battery 2. The pulses generated by PNP Q2 connected to water battery 2 are rectified back to DC and sent back into the primary oscillator circuits, resulting in a kind of feedback that balances the power supply of the other circuit and keeps the device running for an extended period.

This type of "battery" seems to be able to maintain a charge indefinitely as long as it is pulsed with a short break in between to allow for the chemical reaction to occur. With a week-long runtime, the only maintenance required is the periodic changing of water due to corrosion buildup. Additionally, the device can also charge a single regular rechargeable AA 1.5-volt battery in about a day. This innovative concept has significant potential for various applications in the future.

Here I show the concept:

https://youtu.be/2fPa_yUwivM

To implement this circuit, I have designed a primary and secondary coil as a Tesla coil recipient, which are both grounded genuinely. Additionally, there is an optional coil connected to a variable capacitor, framing an average tunable L/C circuit. This circuit is then connected to a Full bridge diode rectifier power supply, which is arranged as a Split rail DC power supply, thereby acting as a voltage multiplier. This enhancement improves the performance and makes the circuit sensitive even in calm conditions.

The circuit is highly sensitive and can easily generate 3 volts DC or more in calm local conditions, and much more in built-up areas near high power radio frequencies. It is driven by nearby RF sources, such as electrical cables, motors, and anything that may emit RF. While this circuit is not new, it is working effectively as a proof of concept. In fact, it could even charge your mobile phone for free.

Here I explain the concept:

https://youtu.be/gmumOs9Lrn0

In this demonstration, I present a simple and inexpensive method to produce hydrogen using everyday items, without the need for a source voltage power. The process involves the use of some common kitchen items, and I will explain how I arrived at this discovery.

To showcase the effectiveness of this method, I employ a hydrogen fuel cell stack that outputs 10 volts. This output is used to power an SSG type motor that is highly efficient. To utilize the high voltage back EMF spikes from the Bedini motor, an additional isolated electrolysis chamber is used. Although the gas produced by this method is not connected, it is utilized for proof of concept for this demonstration.

The resulting magnesium hydrogen gas is inexpensive and can be used to power regular devices, provided that a hydrogen fuel cell is used. In my demonstration, I choose to power the SSG motor using this hydrogen gas. The high voltage back EMF output spikes from the SSG motor are then used to produce even more hydrogen, including through the use of the electric method.

This method is highly efficient and has the potential to produce enough hydrogen to sustain itself for an extended period. As such, it could be used as a self-sustaining method for powering devices in the future.

Here I show you the method:

https://youtu.be/XhZRrqV8OMs

This generator is powered by a modified 6-volt DC motor that operates at a slow speed of around 10 percent on a speed controller circuit, using only 25 mA. Despite this, it generates high-frequency AC at over 100 volts, which is limited to 110 volts by a protective lamp. The generator's output is rectified and stored in a 1 UF high-voltage microwave capacitor that charges very quickly to approximately 84 volts.

To discharge the capacitor and charge the batteries, a transistor capacitor dump circuit called the Tesla Switched is used. This circuit releases low-duty-cycle sharp timing pulses of 84 volts into the batteries, charging them in a few hours without traditional current-based charging. Remarkably, the batteries charge up cold and function better than before, running regular loads for longer periods.

This method is not only useful for charging batteries but also for restoring the memory of rechargeable batteries to their original state without using current-based charging. Essentially, this system provides $100 worth of energy in return for only $2 worth of trigger voltage, resulting in over-unity. With the world becoming more expensive, this system is an effective way to save money.

Here I show the concept:

https://youtu.be/Xr9QSD889ZA

Have you ever wondered if there was a way to charge your batteries for free? Well, there is, and the electric company doesn't want you to know about it! As long as your battery has a plus and a negative, it can be charged, whether it's new or used, consumer or boat or car battery. And the best part? This method not only charges your batteries for free, but it also rejuvenates them and erases any "memory" they may have.

The method starts with using AC voltage. However, instead of using the typical 120 volts AC that most homes receive, we start with only 2.3 volts and 60 hertz. This voltage is sent to an X reactance "box," which has capacitor values that bring down the current to around 17 milliamps at 2.3 volts AC. The next step is to rectify this without using a filter cap. This is important because we want to generate pulsed voltage with zero or near-zero current. Voltage is provided by the electric company for free, while we pay for current. So, if we can find a way to utilize mostly only voltage, we are in big business.

The pulsed voltage is then used to feed a cap dump circuit that oscillates a higher voltage capacitor dump of around 35 volts into the charging battery. This generates a chemical reaction in the battery due to the real high voltage Joule or amps a second current dumping into it. It's important to note that this method only charges the battery and doesn't discharge it.

This is a cold charge, which means the batteries don't get hot and won't explode due to the quick pulse. This is in part thanks to Bedini's cap dump trick, which generates a current charge into the battery for later usage.

Using this method to charge something big like a car battery means you get to use that 600 amps for basically free. And, you used the electric company's voltage for free to do it by gating the current without creating a load.

It's important to note that this method isn't stealing from the electric company, cheating the battery industry, or even hacking. It's just science!

Here I explain the concept:

https://youtu.be/NuKK2ItjqoI

This project is based on the Tesla magnifying transmitter, which was a wireless power transmission system developed by Nikola Tesla in the early 20th century. In this specific project, a flat coil is used with a scalar wave generator. Scalar waves are a type of electromagnetic wave that is different from the conventional electromagnetic waves that we are more familiar with, such as radio waves or microwaves. Scalar waves are believed to exist in higher dimensions and have special properties, such as the ability to transmit energy without losing power over long distances.

The scalar wave generator produces scalar waves that resonate with the scalar coil. This resonance converts the scalar waves back into an electromagnetic field, which can then be rectified back into pulse DC using a rectifier circuit. The resulting pulse DC is used to charge a battery pack.

The battery pack consists of three AAA batteries that are charged using this system. The batteries can be rechargeable or non-rechargeable. The pack is housed in an old gamepad, which has been converted into a battery holder. The battery pack has four bars that indicate the battery level, which hardly takes any input current because the current is not much.

Underneath the battery pack is the scalar generator, and next to it is the scalar coil that picks up the electromagnetic field and converts it back into an electromagnetic wave. The induction light is placed near the coil and reacts to the scalar coil's field. Without the coil, there is no light, so the coil must be present to produce the field.

The system takes an input, and the output is more than the input due to the magnifying properties of the scalar waves and resonance. The power source can be turned off, and the battery pack will continue to hold the charge. The process doesn't take much power out of the input source, making it an efficient way of charging batteries.

Overall, this project demonstrates the concept of using Tesla's magnifying properties with scalar waves and resonance to charge batteries. Although Tesla was working on a much greater scale, this project showcases the potential of this technology on a smaller scale.

Here I show you the concept:

https://youtu.be/fVMpQQugA-0

The circuit takes advantage of the fact that voltage is free and current usage is what we pay for. The objective is to limit the current usage to zero or as close to zero as possible so that we can use the trigger voltage for free or at a very low cost.

The circuit starts by connecting a wire directly to the AC socket. We use the 60Hz AC cycle at 110 volts, which enters a diode bridge rectifier to filter out the negative part of the AC cycle. The circuit does not include a DC filtering cap as we want to keep the AC 60 cycle pulse.

On the other side of the AC wire entering the rectifier, we add a reactance X factor high voltage 1uf capacitor to limit the current usage to approximately 40ma using the formula I=v/x. It's crucial to use a high voltage X capacitor or a microwave high voltage capacitor as anything else could lead to an explosion. It is essential to exercise caution while operating this circuit as it can be dangerous to human or animal life due to the high voltage.

The X capacitor is the critical component of the circuit as it limits and gates the current usage to almost zero, ensuring that we never use more than 40ma of current.

The bridge rectifier charges a 400-volt 10uf capacitor at around 100 volts quickly with "zero" current 60-hertz positive pulsed DC. The voltage charge is limited to around 100 volts because the neon fires at 100 volts and triggers the SCR diode to dump a charged 100-volt capacitor as a real joule or amps a second current discharge into a battery.

The battery undergoes a negative resistance chemical effect due to the capacitive high voltage pulsed discharges, which occur around four times per second. The battery responds by having its ions move around, causing it to resonate and recharge in the process, thus producing real current for future use.

This circuit is a proof-of-concept device that will charge a battery slowly in a couple of days if the battery is in bad condition and as fast as a few hours if the battery is in good condition.

To take this concept seriously, one could remove the X current limiting capacitor stage and increase the 10uf capacitor's value drastically, paying for a few "amps." This way, the capacitor will charge with the current it needs from the mains line, allowing for a discharge at 100 volts with the neon dump or similar method. This will produce a much greater joule or amps per second discharge into a bank of massive batteries. This is where one would be converting amps to kilowatts. However, it is crucial to exercise extreme caution while operating this circuit.

Here I show you the concept:

https://youtu.be/pr4t4JKPkYM

I wanted to share my process for creating an energy-efficient lamp driver. While we can't make energy out of nothing, we can find ways to use very little input source and save money and effort.

Firstly, I use a current reactance limiter on the mains 60 hertz power line or any other source of 60 hertz 110 volts power, such as a generator or windmill. The current limiter uses Ohm's Law to limit the current to around 40 mA with 60 hertz and 1uf.

Then, I use the mostly pure voltage to quickly charge a 10uf or more capacitor with very little current input. The capacitor has an SCR diode that is triggered to dump this cap into an additional super capacitor bank a few times a second, resulting in a pure 100-volt capacitive joule or amps per second discharge. This pumping also has an electret-like effect while being pulsed.

An additional advantage of using a super capacitor bank is the elimination of the high impedance battery charging stage that needs more current. The 12-volt super capacitor bank takes the form of converted negative energy from the reactance box and capacitor high voltage pulses back into a form of regular low voltage higher current DC positive energy that is able to drive a very small and efficient high frequency AC inverter.

This inverter can drive a 15-watt lamp without any problems because of its high frequency. The 15-watt lamp operates at full spec lumens, usually requiring an input of 15 watts. However, we are driving it with only an input that we need to pay for of 40mA. The rest of the needed input is being provided by the local vacuum and clever circuitry. It is not a trick or a cheat for free energy bypass of the electric "smart" meter. The whole circuit except, respectfully, the super capacitor stage operates as an open-looped system, so it can re-gauge itself.

Not only does the lamp operate at full capacity in this fashion, but the voltage keeps rising on the super capacitor bank as it keeps getting many discharges of 100 volts a second from that 10+ uf capacitor dump simultaneously. The charge holds and even goes up instead of down as the super caps do a super job at converting this kind of power back into something useful!

I must point out that this lamp would not operate directly connected to the reactance X output of only 40mA. It requires 15 watts of input current at 60 hertz. We are not providing anything close to this level with this intentional current limiter stage. But at the end, we are able to light the lamp brightly and sustain the system with very little input drive from the operator, work-wise or money-wise. There is no free lunch, just efficiency.

I hope this information is helpful to you all. Please feel free to share your thoughts and opinions on this topic.