I'm wondering if Joel or anyone else is aware of this channel and the work this guy is doing.

I have been following him for a short time and never really put 2 and 2 together until now.

Definitely worth at least taking a look at. I'd love to hear your thoughts because this looks promising even if it is not a solid state solution like we all so desire.  Link Below.

sidster64 - YouTube

Here is a patent that's similar and simpler than the MEG

https://patents.google.com/patent/US20050156702A1/en

Just thinking over how would one power this transformer, would a 3 phase motor driver work? 

Gonna try this 3 phase transformer and 3 phase BLDC driver, this is probably the trick to get the dynamo flowing in a transformer


https://www.amazon.com/gp/product/B0D1KZ8M2S/

https://www.amazon.com/3-Phase-Brushless...B078T8YPGG

Novel 3 transformer setup, no information on current output

https://youtu.be/yuG9oKw48g8?feature=shared

The static generator has no rotating parts and no stator and rotor. It is constructed with 3 transformer which was made by permanent magnets

Good day folks here is the circuit diagram of the reactive solid state "Moray" generator!

   

A memo on fine tuning: 


Given that both the inductance and capacitance are 70.48 µH and 70.48 µF respectively, the LC circuit is indeed resonant at 60 Hz. To fine-tune this circuit, You can optionally incorporate a parallel vacuum capacitor for small adjustments and a series capacitor for potential impedance matching.

### Verify Resonance Frequency


- **Inductance**:  (L = 70.48 
- **Capacitance**:  (C = 70.48
- **Resonance Frequency**: (60 
- **Parallel Vacuum Capacitor**: (C should range from 0 to 3.524 µF for fine-tuning.
- **Series Capacitor for Impedance Matching**:  approx 53.05 uF

*This configuration allows for fine-tuning of the LC circuit to maintain resonance at 60 Hz and achieve impedance matching if needed.

Concept

1. LC Resonant Circuit: Utilize the high circulating reactive power at resonance.
   
2. Direct Battery Integration: Connect batteries in a manner that allows them to charge without disrupting the reactive power oscillations significantly.
   
3. Resistive and Inductive Loads: Use light bulbs and other inductive components to balance the load and manage current flow during different parts of the AC cycle.
   

1. Resonant LC Circuit:
   • L: Inductor
     
   • C: Capacitor
     
2. Direct Battery Charging:
   • Connect batteries directly into the LC circuit at points where they can charge during the positive half of the AC cycle and be protected from reverse current during the negative half.
     
3. Light Bulbs as Loads:
   • Use light bulbs as resistive/inductive loads to absorb power during the negative half of the cycle, thus protecting the batteries.
     

1. Voltage Levels:
   • Ensure the voltage levels in the LC circuit match the charging requirements of the batteries.
     
2. Current Flow Management:
   • The light bulbs will naturally limit the current during the negative half-cycle, preventing reverse currents from damaging the batteries.
     
3. Tuning:
   • Fine-tune the circuit to ensure that the LC circuit remains in resonance while effectively charging the batteries.
     
4. Testing and Safety:
   • Start with lower power levels to test the setup.
     
   • Monitor the temperature and performance of the batteries and light bulbs to ensure they are operating within safe limits.
     

• Balance: Achieving the right balance between the reactive power accumulation and the load distribution is crucial.
  
• Fine-Tuning: You may need to experiment with different configurations and component values to achieve optimal performance.
  
• Monitoring: Continuously monitor the circuit's behavior to avoid overcharging or damaging the batteries.
  

Just saw this information on Nonlinear Resonance Circuit For Wireless Power Transmission And Wireless Power Harvesting, if one could make a Tesla coil using this method, it'll probably be the cheapest yet most powerful over unity system

The only special component the circuit needs seems to be just a ferroelectric capacitor, in the video, the person seems to be using a variable capacitor and something else that couldn't make out

https://youtu.be/paIcyBurQLs?feature=shared

https://patents.google.com/patent/US20160336810A1/en

https://www.semanticscholar.org/paper/No...763ccf7e43

Here is an interesting way to get current from capacitor

Dump the cap through an SCR
From the SCR to a transformer 

https://youtu.be/thRANyTWLHA?feature=shared

One of the most promising easy to build circuit

https://youtu.be/5_ineJpR52s?feature=shared
https://youtu.be/DQHemB16zbI?feature=shared

https://youtu.be/MCkTn-yhitY?feature=shared

https://youtu.be/7_PonxcDudQ?feature=shared

Why did you delete the video here: https://youtu.be/MJdd_1bon5E

"Title: Looping Energy
Here i'm just testing another looping method that seems to work fine. Trying to find some possible configurations for using the power cells I been making to run  it all down the..."

I have a 100AH 12V (LiFePO4) battery and I'm wondering what is considered safe voltage when dumping a capacitor into a battery? 

The battery has the following ratings

Standard Charging Voltage 14.6 (+-) 0.2V
Standard Continuous Charging 20A
Max Continuous Charging 100A

Now this ratings are for DC, but when dumping using pulsed DC capacitor, the effect is different right? 

What would be the max voltage that's safe to dump into a 12v battery from a capacitor? 
How much does amp matter when dumping from capacitor to battery? 
Does the frequency of the dump matter?

Thanks!