Capacitive Reactive Power
Good day folks, Here I explain the potentials of using a very specific kind of power supply to operate your Bedini like devices with. It offers much more efficient charging of multiple batteries. Without having to spend more money for it.
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Self Looping Cap Dump Bedini Motor
Today, I'm introducing an avant-garde configuration reminiscent of the Bedini motor, utilizing asymmetrical re-gauging and magnetic dipoles. This arrangement, friends, will inspire the inquisitive mind to tap into the infinite potential of the Dirac sea.
In our first stage, the inductance on the primary side of the transformer plays a crucial role, coupling to the negative side anterior to the battery. Considering the Bedini system's inherent switching capabilities, it's only logical to exploit this feature. Here, the inducer acts as an efficient governor, constraining the pulse with which the Bedini motor interacts. This is no small accomplishment, as our prime objective lies in diminishing the trigger input.
Moving to the secondary effect, we find an opportunity to rectify this oscillation and employ it as a pulse switch transistor controller, pulsing a capacitive discharge. This is where the spirit of Tesla's resonant magic breathes life into the system! A rapid synchronization ensues, harmonizing with the resonant frequency. The challenge – and joy – is in discovering the capacitor value that yields the zenith of spike amplitude, as witnessed through the looking glass of my oscilloscope.
This charge is then channeled into an isolation transformer, rectified, and reintegrated into the battery supply. By shorting a tuned L/C circuit, we unleash a substantial "bang" of energy. Yet, dear reader, heed this: selecting the correct value for the capacitor is paramount, for resonance is the cornerstone of this mechanism. It's a delicate dance with nature, one where resonance reigns supreme.
I believe this unique approach to a Bedini-like setup, embracing the curvature of spacetime and Maxwell's original 20 variables, is a fresh and invigorating contribution to our collective journey. A new path to explore, a connection forged in the crucible of creativity and understanding.
Thank you, dear friends, for your unwavering support and shared enthusiasm in this grand adventure. Together, we continue to push the boundaries and light the way.
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Radio Crystals
Just some ideas about the relation to some quartz crystals used in old radio equipment and clocks and how it may have piezoelectric properties and asking the community what they think we can do to tap into this potential source if even possible. Are they all built with the right material we need?
Yeah sometimes it's just a video of me asking the community for enlightenment! :) Thanks all.
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I'm not working backwards
Just another follow up and some hints along the way.
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Opto-Isolator Cap Dump
Following my recent video regarding the peculiar behavior of capacitors, I've discovered further information from Tom Bearden and Bedini. This new information aligns with my previous findings and sheds light on the potential blueprint and functioning of what is known as their "secret" opto-isolator capacitor discharge unit. I share a clip at the end of Tom Bearden supporting this idea. What do you think? Let me know!
Design the Circuit:
Identify the source coil where you will pulse the current and capture the back EMF.
Select one small capacitor (for instance, 10μF) to smooth the back EMF and two larger capacitors (e.g., 50μF each) that can handle the expected peak back EMF voltage in reverse polarity ( experimentation needed) and a desirable level of stored charge. Ex 24 V.
Choose four diodes for each full-bridge rectifier, one additional diode for the isolation of the small capacitor, and two additional diodes for the isolation of the larger capacitors - all capable of handling the expected peak voltage and current.
Choose two comparator ICs that can handle the voltages you are working with and that can sink or source enough current to drive your opto-isolators.
Choose two opto-isolators compatible with the comparator's current and voltage, capable of switching a relay to control the charging/discharging of the larger capacitors.
Choose two relays with contacts rated for the current and voltage you expect to switch. The coil voltage of the relay should match the output of the opto-isolator.
Additionally, choose four resistors and two capacitors to create an RC circuit for each relay, preventing both relays from being engaged simultaneously.
Create the Circuit:
Connect the coil to a suitable pulse generator. Ex: Bedini Motor Device
Connect the small high voltage polarized capacitor to the coil in reverse through an isolation diode. This will capture and convert the back EMF into a steady DC in negative voltage.
Connect the output of the small capacitor to a rectifier the input of two additional full-bridge rectifiers, each with its own isolation diode. Connect the positive output of each rectifier (and the cathode of the isolation diode) to one of the larger capacitors, ensuring that current can flow from the small capacitor to the larger capacitors but not in reverse.
Connect the positive input of each comparator to the positive terminal of the corresponding large capacitor and the negative input to the positive terminal of the battery.
Connect the output of each comparator to the input of the corresponding opto-isolator.
Connect the output of each opto-isolator to an RC circuit, and then to the coil of the corresponding relay. This will create a delay that prevents both relays from being engaged simultaneously.
Connect the normally open contacts of each relay to the load, so that when the relay is engaged, the corresponding large capacitor will discharge into the load.
Test and Operate the Circuit:
Apply pulses to the coil and monitor the voltage across the load and on the capacitors. The small capacitor should capture and smooth the back EMF into a steady negative DC, and the two larger capacitors should alternately charge from the small capacitor and discharge into the battery, maintaining a nearly constant voltage across the load.
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Dipole Resonance Energy System
Good day folks, I'd like to talk to you about the latest concept i'm experimenting with. It's a dipole resonance energy system.
Maxwell's original equations and 20 variables provides a vest playground for creative experiments. So let's get creative!
This device could be a stepping stone towards harvesting or manipulating magnetic potential differences in novel ways as originally envisioned in Maxwell's equations.
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Maxwell Wiki
Good day folks, I'm happy to announce that my private server is back up and running live. My apologies on the delays.
To make things more interesting in informative I included "Joel's Maxwell Wiki" It's jam packed with great information! I hope you all can make good usage and understanding of it. You can visit the Wiki at my root domain at http://typeright.social and you can also visit the community forums at http://typeright.social/forum Where some members have shared some great insights and even schematics that are not talked about or posted on my youtube channel.
Looking forward to reading your comments!
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Extra Bedini Energy Tap
Good day to all fellow explorers of the unseen and misunderstood realms of energy! Today, I am excited to reveal to you an innovative approach to operating your Bedini motors. This method, though somewhat concealed, is a significant discovery that I believe is worth sharing with all of you.
By engaging the back EMF side of the Bedini motor and connecting a substantial capacitor in reverse polarity, we can further explore the electret-like effect that John Bedini and I have often discussed. This approach seems to align with one of Bedini's capacitor dump methods, something I've hinted at in one of my video presentations.
Now, allow me to explain the underlying concept with more precision. You must utilize a high voltage capacitor capable of handling the difference in reverse voltage without breaking down. As Bedini himself often reminds us, experimentation with devices outside their parameters is possible, especially if the spike is sharp and the current is zero. By exploiting this principle, we can tap into the electret effect more efficiently, using it to interact with the magnetic dipole and the ever-pervasive vacuum energy.
But the innovation doesn't end there. Considering the pulsing nature of the Bedini motor, one can place an inducer in the negative side of the battery to minimize current drag. The goal here is to trigger a small disturbance in fields to create a sort of asymmetrical re-gauging within the system. In this way, we reduce current without resorting to a lossy high impedance resistor, which otherwise would dissipate most of the energy as heat.
Even though I noticed some heat in the inducer coil, I found a solution: implementing a regular AC transformer in line with it. By converting that lost heat back into input and rectifying it, I sent it back into the battery as a high voltage pulse. In essence, we pulse the pulse, generating consecutive interference waves that induce a negative resistance-like effect within the battery.
The initial results are promising. A battery that was at 12.40 volts 24 hours ago now reads 12.42 volts. While the progress may appear slow, it serves as a proof of concept. There are traditional circuit losses to consider, of course, but the fact that we can achieve this performance indicates not only that perpetual motion is conceivable but also that real physical work can be accomplished. The fan blows genuine air, all while utilizing zero energy, directly harnessed from the vacuum itself.
In closing, I encourage all interested parties to continue probing, questioning, and experimenting. The world of free energy is rich and complex, and our journey has only just begun. Let us embrace the infinite possibilities lying beyond the constraints of conventional wisdom.
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The Hidden Variables in Quantum Physics
In quantum mechanics, hidden variable theories are a set of attempts to provide a more classical understanding of quantum phenomena. These theories suggest that quantum mechanics is incomplete and that there are hidden variables which, if known, could help us predict the outcome of a quantum mechanical experiment without any randomness.
The "hidden order hidden variable theory" seems to be an attempt to refine these theories.
In quantum mechanics, one of the most puzzling aspects is the inherent uncertainty and indeterminacy. This comes from the famous Heisenberg uncertainty principle, which states that you can't know both the position and the momentum of a particle with complete certainty at the same time. This is quite different from classical physics where you can know both precisely.
Hidden variable theories propose that these uncertainties are not inherent in nature, but instead, are due to our lack of knowledge about some hidden variables. If we knew these variables, we would be able to predict the outcomes precisely, just like in classical physics.
The two types of hidden variable theories are local and non-local theories. Local theories respect the principle of locality, which essentially states that an object is directly influenced only by its immediate surroundings. Non-local theories, on the other hand, allow for instant influences across vast distances, which is counter-intuitive in the realm of classical physics.
However, hidden variable theories have been challenged by what's known as Bell's theorem. In 1964, physicist John Bell showed that if local hidden variable theories were true, then certain experimental results would follow. Experiments have shown these results do not occur, leading many physicists to conclude that local hidden variable theories cannot be correct.
It's worth noting that quantum mechanics is a very complex field, and while it can be described in simpler terms, a full understanding does require a good deal of knowledge in physics and mathematics.
I propose there is a way to apply the work of historical physicists such as Stony, Whitaker, Nisbet, Dubai, and Dirac to create an engineerable hidden variable theory in quantum mechanics.
we should briefly touch upon the contributions of these physicists:
George Johnstone Stoney: He was known for introducing the concept of the 'electron' as a fundamental unit of charge.
Edmund Taylor Whittaker: Whittaker made significant contributions in applied mathematics and mathematical physics, including the Fourier series and the Whittaker function.
Paul Dirac: A significant figure in the early development of quantum mechanics and quantum electrodynamics. He's known for the Dirac equation, which describes the behavior of fermions, and predicted the existence of antimatter.
these historical works could potentially be applied to develop an engineerable hidden variable theory that is consistent with all experiments and solves problems in quantum mechanics, this would indeed be a major advancement.
our current understanding of electrodynamics is significantly flawed, and a re-examination of foundational principles, taking into account the perspectives of historical scientists and their work, could provide us with new insights, even potentially revealing a more accurate model.
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Back EMF Powered Cap Dump
Here, I present to you an innovative method with schematic example designed for a high voltage pulse generator that repurposes the usually wasted parasitic back electromotive force (EMF). This repurposed energy is employed to manage a more sophisticated capacitor dump stage, circumventing the expense of utilizing additional traditional current at the primary power input stage.
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Capacitor Anomaly
Hello everyone. Today, I'm going to discuss a potential irregularity associated with polarized capacitors when they are pulse-charged in reverse at lower voltages.
In my upcoming experiments, I'm planning to push the boundaries by subjecting a capacitor to high voltage "zero" current sharp pulses in reverse, despite the risk of causing damage. I'm curious to see if the same phenomena will be observed.
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Energy Research Pointers
Just an open discussion and general pointers on alternative energy research.
A talk about the Bedini process, Homemade galvanic Cells, High voltage modules and SCR cap dump pointers.
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Follow Up Back EMF Project
Here I share my thoughts on latest project video here of using a HV module.
What I think are the next step and my findings and opinion.
What are your thoughts?
Original experiment here: https://youtu.be/tP7nRtTfKGM
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Energy Project Warning
Good day folks just some general info regarding the rise of availability of kits based on my schematics and concepts. And I discuss your chances of success with those.
Again I know my circuits and devices work, It has been replicated as is, Time and time again validated by my own work of course and that of emails thanking me that I receive from others that have successfully replicated the very circuits the trolls tell me don't work and turn around to sell lol.
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Flyback Driver For Bedini Output
Currently, I'm working on a fascinating project involving a fan-style Bedini motor. The aim is to harness the low-level back electromotive force (back emf) generated by the motor and use it to charge a capacitor. This capacitor will then provide a low-level DC power supply for my custom-built tiny flyback high-voltage 25kv oscillator.
The next stage in this endeavor involves constructing the voltage diode capacitor multiplier stage. Interestingly, this concept bears similarities to those black high-voltage pulse modules available on eBay for a low cost. However, I've chosen to build my own version to have better control over the input current requirements. My primary goal is to explore innovative approaches that consume minimal to no current.
I thought it'd be great to share my progress with you. So far, the oscillator is functioning well. It comprises a basic setup with a single transistor, the 2n2222a, and a variable base resistor to finely tune and control its performance.
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Self looped HV Module
Here, I demonstrate the utility of my highly efficient, low current controller that requires less than 45mA to function at 12 volts. It operates at a minimal duty cycle to induce a back electromotive force (EMF) spike in my large, low-loss 2-ohm coil. This back EMF is rectified and accumulated in a mid-sized capacitor, powering a separate high-voltage pulse module.
Not only does this module emit an approximately 80-volt DC output pulse, it also serves as an isolator in the circuit. This arrangement saves me from needing external power supplies or inverters that can lead to power losses of several watts. The back EMF generated drives the high-voltage pulse module, enabling a gradual charge of the battery.
I began at 10 am with a battery voltage of 12.55 volts, and by 3:30 pm, the voltage has been oscillating between 12.56 and 12.57 volts. This appears to be a very promising result.
If you want to see a longer running version, I share similar concepts in my channel library where I run for nearly half an hour with a load and you see an increase as well. Look for those videos on my channel if it interests you as well.
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Hydrogen Battery Charging
Just an update on my ongoing research. Previously, I had obtained a self looped setup using similar method. I have a video of this on my channel if self loop interests you, This time I focus on using similar methods to use old junk half dead batteries to use them as trigger to charge much bigger car 12 volt batteries with the help of the hydrogen and back emf stages.
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Update On Energy Research
Just an update on things. I'm still alive :)
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Inductive Kickback Power Hydrogen Generator
In this video, I demonstrate the use of a low-power back EMF generator that operates at 5 volts, drawing milliamps (40)ma of current from a 12-volt battery. By employing a voltage regulator,(not rectifier that's a tongue twister my video!!) the current is intentionally limited to maintain a low trigger current. This setup generates a high voltage back EMF of approximately 48 volts through the coil. Using a diode, I convert the negative spike of the back EMF into a positive spike, which is then directed to an electrolyzer for hydrogen generation.
The hydrogen gas produced is fed into a 9-volt fuel cell, where I only tap into the three-volt cell because it provides sufficient power for my pulse-driven oscillator. The oscillator generates a sharp pulsed DC similar to the back EMF spike, reaching high voltages of over 60 volts. This output is ideal for charging batteries, capacitors, or other projects. And is totally isolated avoiding traditional isolation loss.
One notable aspect of this setup is that the high voltage pulse generator(black block) and the hydrogen fuel cell operate with a minimal current requirement of around 1 milliamp. This approach eliminates the need for an isolation transformer or inverter to recycle power back into the battery, effectively addressing any power losses. With these separate systems working together, the issue of isolation is no longer a concern, allowing the direct feeding of this voltage back into the battery without any loss.
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Hybrid Galvanic Capacitor
Building a Self-Powered Hybrid Galvanic Cell Capacitor
Introduction:
In this video, I show the process of building a self-powered hybrid galvanic cell capacitor from scratch. The hybrid galvanic cell capacitor combines various systems and theories to create a unique feature of continuously raising voltage. We'll discuss the components and the theory behind the project and explore how the galvanic cell triggers the oscillator box and causes the capacitor to self-oscillate. This will charge a 12 volt car battery in a few days!
Components:
The hybrid galvanic cell capacitor comprises several components, including a galvanic cell, an oscillator box, a built-in capacitor, and an additional induction coil. The galvanic cell offers about two volts DC that the oscillator box uses to self-oscillate. The built-in capacitor is in line with the oscillator, causing it to self-oscillate at around 20 Hertz at around 30 plus volts. The capacitor continuously charges at this rate.
Theory:
The unique feature of the hybrid galvanic cell capacitor is the continuously raising voltage. The galvanic cell triggers the oscillator box, causing the capacitor to self-oscillate. The capacitor then charges and builds up in amplitudes, increasing instead of decreasing every few minutes. The capacitor continually raises the voltage until it reaches its maximum voltage capacity, less it's loaded down.
The addition of an induction coil around the capacitor taps into that extra energy and potentially powers other loads. The hybrid galvanic cell capacitor continuously raises the voltage and is completely self-powered.
Conclusion:
Building a self-powered hybrid galvanic cell capacitor is a fascinating project that combines various systems and theories. The capacitor's unique feature of continuously raising voltage is achieved by triggering the oscillator box and allowing the capacitor to self-oscillate. The addition of an induction coil around the capacitor provides an extra source of energy that can potentially power other loads. This project shows how experimentation and exploration can lead to exciting and innovative discoveries.
Based on my analysis, it seems that the slow gain in voltage is primarily due to a strict slow electron flow within the system. The electron flow through the water conductance from one of the capacitor plates jumps into the galvanic cell plate and appears to change the electron count, thereby acting as a hybrid capacitor and a passive electron accumulator This explains the slow movement of electrons as single units in a circuit, supporting the idea that the galvanic cell acts as an electron accumulator, capturing electrons built up from the capacitor plate.
While direct induction or capacitance may not be the dominant factors in this feedback process, the concept remains fascinating. Further study and research in this area could help shed more light on the underlying mechanisms and potentially lead to enhanced developments in the field.
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Self Charging Capacitor
A self-charging capacitor system is a device that can charge itself without the need for an "external" power source. This technology has great potential for creating low-cost and sustainable energy solutions. In this video, we will discuss the basic concepts of how to build a self-charging capacitor system that takes advantage of a piezoelectric plate and hybrid solid-state membrane electrolyte/dielectric material, and a dissimilar metal to work as a capacitor and a galvanic air cell.
The first component of this system is the capacitor, which is made of a piezoelectric plate and a copper coil. The piezoelectric plate is a material that can convert mechanical pressure or electrical changes into an electrical charge, and the copper plate acts as a dissimilar metal conductor. By placing these two plates together, we can create a capacitor that can store electrical energy.
The second component is the galvanic air cell, which is essentially an air cell that generates an electrical current through a chemical reaction. As long as there is oxygen in the air, the galvanic air cell will be able to feed a low-level power into the system. This adds an additional source of energy to the system.
The third component is the piezoelectric pulse. This works by reacting to the electrical charge pulse generated by the capacitor 2 volt SCR dump to trigger a short that pulses and self-oscillates the capacitor. The rebound effect of the capacitor is "amplified" by the galvanic air cell and the piezoelectric plate, creating a self-charging cycle loop.
To initiate this cycle, we use an SCR (silicon-controlled rectifier) cab dump circuit. This circuit acts as a switch that allows a short pulse of electrical energy to be sent to the capacitor. When the capacitor is charged to a certain point, the SCR will "dump" the charge, initiating the self-oscillation cycle.
To take advantage of the self-charging effect, we can add an additional back EMF (electromotive force) collector as a hybrid in our capacitor and as back EMF dump collector. This allows us to use the back EMF and its increased amplitudes from another stage and take advantage of that to power our trigger devices. By not directly loading onto the capacitor self-oscillation, we can reduce stress on the system and potentially make it more efficient.
In conclusion, a self-charging capacitor system can be built using a combination of a piezoelectric plate, a hybrid solid-state membrane electrolyte/dielectric material, a dissimilar metal, and galvanic air cell properties. By using an SCR cab dump circuit and an additional back EMF coil, we can initiate and amplify the self-charging effect, potentially creating a sustainable and low-cost energy solution.
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Self Looped Bedini Motor
No batteries!
In this video, I demonstrate a method for sending the back EMF of a bedini style fan motor without using a full-blown inverter and separate power supply for DC isolation. Instead, we built our own isolation transformer with a one-to-one ratio and ten turns on each side. After rectifying the isolated side, we send the resulting charge back into the capacitors which powers the pulse for the Bedini switching. As shown in the video, after about 15 minutes, the capacitor's charge remains stable instead of decreasing, demonstrating the effectiveness of our setup. We also show the back EMF spike on the oscilloscope, with reversed poles for better viewing. By eliminating all batteries in the system, we address accusations of exploiting the VI curve of lead-acid batteries. Our LC circuitry recycles its own power and interacts with magnetic fields at every event in the pulse, resulting in increased amplified amplitudes due to the coils of the Bedini motor "energizer" during the inductive kickback time.
I'm not saying this simple setup will run "for ever" but instead perhaps for hours without eventual drop of perhaps 0.01mv along the way. I want to simply draw attention on efficiency of such a system and why in such a configuration we could include an additional system of energy such as electrostatic disks dumping into a pulse cap. Sending/introducing an additional energy input to our system for "free" It don't cost us any more "loading" current to drive a electrostatic plate instead of a fan blade. Because of how the mechanical spin of such device is not really a motor in a traditional sense.
It's also worth noting that the usage of super capacitors instead of using normal batteries, helps us reduce the internal resistance of our storage device. Bedini knew this was a key to his system's efficiently so he used big commercial high voltage backup batteries, Industrial grade, instead. We can mimic similar circuit characteristics, by replacing the battery setup with capacitors. Much lower resistance to work with! And no messy lead acid "anomalies".
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High Voltage Pulse Galvanic Cell
Introduction:
In this description, we will delve into the details of building a modified galvanic cell with two dissimilar metals, which can generate close to 1 Volt of electricity. The primary objective behind creating this special kind of cell is to conserve the metal from breaking down too fast by slowing down the electron flow and the reaction of the cell.
This cell can be used to drive a high voltage step-up oscillator that can create a back EMF very similar to the Bedini motor. We will explain the inner workings of this homemade battery and how it can be used to quickly charge a capacitor at high voltage.
Building the Modified Galvanic Cell:
To build this modified galvanic cell, we need two dissimilar metals, a simple water and flower paste, and some basic electronic components like a high voltage step-up oscillator and a capacitor. In this case, the metals used were magnesium and carbon, respectively. Still, one can use any kind of dissimilar metal, and even tinfoil can be used instead of magnesium.
The first step is to create a gooey paste by mixing flour and water. Then, we insert the two dissimilar metals into the paste, making sure they are not touching each other. The paste acts as the electrolyte that enables the chemical reaction between the two metals to create an electric potential. The logic behind using the paste is to slow down the electron flow and the reaction of the cell, which helps conserve the metal from breaking down too fast.
Generating Electricity:
The chemical reaction between the two dissimilar metals generates close to 1 Volt of electricity, which can be used to drive a high voltage step-up oscillator. The oscillator is a flyback circuit that creates a back EMF similar to the Bedini motor. When the oscillator is activated, it produces a very quick high voltage pulse, a sharp spike, that can be used to quickly charge a capacitor at high voltage.
Charging a Capacitor:
To charge the capacitor, we use a trigger system like a neon or an SCR, which is activated when the voltage reaches around 80 volts. The capacitor is a small 10 UF capacitor that converts the high voltage pulse to amps. When the capacitor discharges, it creates real amps that can be used to charge a storage device like a super capacitor or a car battery.
Conclusion:
In conclusion, this homemade battery is an excellent example of how we can use simple materials and basic electronic components to generate electricity. By using a modified galvanic cell with two dissimilar metals, we can create a high voltage pulse that can be used to charge a capacitor quickly. This pulse can be used to charge a variety of storage devices, including super capacitors and car batteries, making it a versatile and cost-effective solution. With some tinkering and experimentation, it's possible to improve the efficiency of the system and achieve better results.
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The Infinite Spectrum
Good day folks, waves with different properties can have the same frequency. For example, radio waves, microwaves, and light waves can all have a frequency of 1 GHz, but they have different properties, such as wavelength, amplitude, and polarization. Similarly, sound waves and seismic waves can have the same frequency, but they are different types of waves with different properties. It's important to keep in mind the context and the type of wave when discussing frequency and other properties of waves.
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