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Ambient Powered High Voltage Generator

#1


In this fascinating demonstration, we witness the creation of a high-voltage generator that operates entirely on ambient energy. The circuit self-sustains by accumulating charge from the environment until it reaches a threshold that triggers a spark gap, resulting in a consistent output of 1,000 volts. This experiment showcases the potential of harnessing ambient energy to power high-voltage systems without a conventional power source, pushing the boundaries of what's possible with alternative energy concepts.

The Setup and Operation
This experiment revolves around a cleverly designed circuit that taps into ambient energy and converts it into high-voltage output. Here's a breakdown of how it works:
  1. Ambient Energy Collection: The circuit starts by gathering energy from the environment, which is stored in a primary charging capacitor. This capacitor accumulates charge over time from various ambient sources, such as electromagnetic fields, static electricity, or even stray RF signals.
  2. Spark Gap Trigger: Once the primary capacitor has accumulated enough charge, it triggers a spark gap circuit. This spark gap is the heart of the system, acting as a switch that releases the stored energy in a controlled burst. The spark gap also helps to initiate the generator’s full drive, sustaining the high-voltage output.
  3. High-Frequency Transformer and Rectification: The released energy from the spark gap is fed into a high-frequency transformer setup, which steps up the voltage even further. The transformer is connected to a rectifier circuit that converts the high-frequency AC output into a stable DC voltage, which is then stored in additional capacitors.
  4. Grounding and Stability: Proper grounding is essential for this setup. The circuit uses two separate ground points spaced about 40 feet apart, which helps stabilize the system and ensures reliable operation. This grounding setup is critical for managing the high-voltage output and maintaining the circuit’s self-sustaining nature.
  5. Intermittent Adjustments: The experimenter notes that occasional adjustments are needed to maintain the circuit's operation. If the system is disrupted—such as by accidentally turning it off—it takes some time for the ambient energy to rebuild the charge necessary to restart the spark gap. However, once the charge is sufficient, the system resumes generating high voltage autonomously.

Key Observations and Insights
This experiment is a powerful example of how ambient energy can be harnessed to generate high voltage without a traditional power source. The ability of the circuit to self-sustain and produce a consistent 1,000 volts is a testament to the potential of ambient energy in high-voltage applications.

Self-Sustaining Operation: The circuit’s ability to operate indefinitely on ambient energy, with only occasional intervention, highlights its efficiency and the effectiveness of the energy collection and storage process. This self-sustaining operation could be useful in applications where a continuous power supply is needed, but access to conventional energy sources is limited.

High-Voltage Output: Achieving a high-voltage output of 1,000 volts from ambient energy is no small feat. This level of voltage is sufficient for a variety of applications, from powering specialized electronic equipment to serving as a component in larger energy systems. The use of a high-frequency transformer and rectifier circuit ensures that the voltage is both stable and usable.

Potential for Further Exploration: The experiment raises intriguing possibilities for further research and development. By refining the circuit design, experimenting with different ambient energy sources, or optimizing the transformer and rectifier components, it may be possible to increase the output voltage or improve the efficiency of energy collection.

Applications and Future Exploration
The ambient-powered high-voltage generator demonstrated in this experiment has several potential applications:
  • Remote Power Systems: The ability to generate high voltage from ambient energy could be invaluable in remote or off-grid locations where conventional power sources are unavailable.
  • Sustainable Energy Solutions: This system could serve as a model for developing sustainable energy solutions that rely on environmental energy sources, reducing the need for fossil fuels or grid power.
  • Educational and Experimental Use: The circuit provides an excellent platform for educational purposes, allowing students and hobbyists to explore the principles of high-voltage generation, energy harvesting, and circuit design.
Further experimentation could involve scaling the system, integrating it with other energy-harvesting technologies, or adapting it for specific practical applications. Understanding the nuances of how the circuit interacts with different ambient energy sources could lead to significant advancements in the field of alternative energy.

Conclusion
The ambient-powered high-voltage generator showcased in this video is a remarkable achievement in the field of alternative energy. By harnessing ambient energy and converting it into a consistent high-voltage output, this experiment demonstrates the untapped potential of our environment as a source of power.
For those interested in DIY electronics, alternative energy research, or the principles of high-voltage circuits, this experiment is both inspiring and educational. It opens the door to new possibilities in energy generation and challenges conventional notions of how we can power our devices and systems. As the experimenter continues to refine and explore this technology, the potential for groundbreaking applications in sustainable energy is clear.
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#2
Would be interesting to find out if 3 phase AC can be achieved with such setup ? regardless of output frequency
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#3
(09-01-2024, 10:15 AM)Mozart Wrote: Would be interesting to find out if 3 phase AC can be achieved with such setup ? regardless of output frequency

In RF we use power splitters and RF dividers. (more old fashioned magnetics) Driving pairs of different value L/C usually built with coax coils as well to take advantage of velocity factor and better time the phase variant.  circuits taking note of the phase with additional capacitors and some mixer could combine it all back together. 

It's all just out of my hat at the moment and I have not had my coffee yet i'm not awake. so don't hold me to it  Big Grin
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#4
I think you are well aware this setup can be used with your PEG cell … it really doesn’t matter how we obtain the gradient as long as it can have a constant reliable output.

“We only need a spark !” ?? to start the self resonance provided that oscillations will not draw more than replenishing capabilities of the gradient used. I mean “the charge pump” must match the input.

By analogy, a water ram pump works because of this little gradient artificially created and its reliability depend on the component with highest stress.
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