Kapanadze Cousin - DALLY FREE ENERGY

[Belfior]

Everybody talks about AC reactance but the real deal is how capacitor reacts to DC pulses. Could somebody help in that area?

This would be a great interest to me also. Not many sources that have this information. Just Tesla's disruptive discharges that are supposed to do magic when under 100us pulses

[lancaIV]

100us is fast= in rush and it is a wall : thermal resistance/ scattering/ noise
   https://en.m.wikipedia.org/wiki/Microsecond     " lifetime of particles"
   Nyquist and https://en.m.wikipedia.org/wiki/Junction_temperature

[forest]

Belfior if you have tools like digital scope for example you can start doing experiments which i i feel are important. For example how the charge on capacitor affect its reactance.

[F6FLT]

Everybody talks about AC reactance but the real deal is how capacitor reacts to DC pulses. Could somebody help in that area?

This would be a great interest to me also. Not many sources that have this information. Just Tesla's disruptive discharges that are supposed to do magic when under 100us pulses

All you have to do is apply the math to a real capacitor. A real capacitor is not only a capacitor. It has a series resistance, a series inductance and a parallel resistance. With pulses, or at very high frequencies, only the last one remains negligible, so you are left with an RLC circuit.
- charge : d²Q/dt² + (1/LC)Q + (R/L) dQ/dt = U
- current : Ld²I/dt²+RdI/dt + I/C = U

Does that bother you? Then read more  . In general, R and L of the capacitor are much lower than the resistance and inductance of the conductors that connect it to the rest of the setup. Thus the problem is less to know the behaviour of the capacitor itself than to know the whole circuit to which it is connected.

Impulse means high frequency, therefore skin effect with increased conductor resistance, conductor impedance increased because of their inductance (every conductor has an inductance), and electromagnetic radiation because the smallest conductor section acts as an antenna.

The design of the circuit must therefore be made with large conductors, the shortest possible connections, and capacitors made for high frequencies. This will greatly reduce the problems.
However, it should not be forgotten that it is not possible to instantly impose a voltage to a capacitor, which would imply an infinite current. The inductance and resistance of the circuit by which it will be charged, possibly from pulses, therefore remain essential, as these elements are the only ones to limit the charge current.

[AlienGrey]

100us is fast= in rush and it is a wall : thermal resistance/ scattering/ noise
   https://en.m.wikipedia.org/wiki/Microsecond     " lifetime of particles"
   Nyquist and https://en.m.wikipedia.org/wiki/Junction_temperature

Struth why do they make it apear so complicated ?

1.00 is 1 amp
0.100 100 ma
0.010 10 ma
0.000 1 ma

0.000,1 = 100 micro amps                 = 10-3
0.000,000, 100 nano amps                = 10-6
0.000,000,000, 1 100 pico ampos       = 10-9

somple ain it