I would like to add to the previous blog post regarding the disturbance duration equation. Not that it's much of an equation. The equation based on past experiments. To add further detail, the disturbance duration is relative to the spike quality divided by the normal electrical current. In other words, more electrical current tends to increase the disturbance effect and disturbance duration, not a good thing.
As far as spark quality, you want to keep resonance down as much as possible because that adds a lot of electrical current, which tends to decrease radiant energy. I've tried adding inductance to reduce resonance without any luck so far, but I'll keep trying different inductors. One way of decreasing resonance that's worked for me is to add high resistance to the spark. Twenty mega ohms usually works for me. Of course that adds significant losses, but I'm only focusing on the chill effect. The chill effect is where the temperature actually goes below ambient temperature. Yes, I've seen the chill effect dozens of times, but it's difficult to find and does not appear that often.
As for the chill effect, there appears to be a pattern such that higher energetic sparks tends to bring about the chill effect more often. My explanation for this is based on how my theory, which I realized from years of highly shielded and undisturbed diodes and piezos. That is, there is always subtle matter within ordinary matter, in varying amounts, subtle matter that academic science has no clue about. At extremely low levels of power as produced by passive, undisturbed, shielded diodes and piezos the amount of subtle matter must be dense enough within the diode or piezo. Achieving such dense levels of subtle matter merely takes a few weeks of placing the ordinary matter within a shielded box, usually.
The impression I get is that this subtle matter always surrounds ordinary matter. It surrounds the electrons, protons, neutrons, etc. When ordinary matter has been left undisturbed for a few weeks, the out layers of subtle matter that has slowly gathered around the subatomic particles is exceptionally easy to disturb. Once disturbed, a piezo can go from producing 7 volts DC to less than 1 milli volt. A diode can go from ~ 1/2 volt to less than 1 mV. This does not mean the diode or piezo will then produce zero volts! Micro volt meters will usually show the DC voltage produced by most disturbed diodes and piezos. This is ultra low power experiments. When we get into Tesla Impulse technology, we're dealing with voltages that are thousands of times great than the passive diodes and piezos, and therefore we can expect far greater radiant energy. Although the bad side is that the ordinary current produced by such technology is significantly higher. So the goal for Tesla Impulse technology should be high voltage and extremely low levels of ordinary electrical current.
Created on 2012-01-21 11:03:59 by Energy Probe
Misc, Science, Free energy, Free energy devices, FE Misc devices, FE piezos, FE diodes