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Has anyone come across a copy of this lecture by Nikola Tesla?
There's so much information out there, but sometimes it's hard to get to the root of it.
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I'm finally getting some practical hands on experience with this stuff. My goal is to start with the basics and see if I can produce the same conditions in which Tesla first observed radiant energy.
I have succeeded in building a high voltage power supply, I built it from a simple 555 timer and a flyback transformer from a CRT monitor. The nice thing about it, is the transformer has diodes between each layer of the secondary, so I don't need to try to rectify my HV output. The downside is I only get a half-wave, but oh well, it's a start.
From there I'm able to charge a high voltage capacitor and discharge that over a spark gap.
I've got a few HV capacitors, one is from a microwave with a pretty high capacitance, and another from the CRT logic board which has a much lower capacitance. Obviously I can get much more powerful impulses from the microwave capacitor, but I can charge the smaller one much more rapidly giving me higher frequency discharges.
However like I said my aim is to see if I can detect the radiant discharge that Tesla described in the lecture, so at least to start with, I'm not concerned with high frequencies.
So, out of curiosity, my capacitor is rated for about 2kv, and I have my spark gap set very small, a few mm at most. So I'm expecting that I'll never get a charge up to 2kv, but what I'm worried about is my HV power supply produces discharges in air about 5-7 cm. Which I figure is a lot higher than 2kv. So is the capacitor safe to be charged with voltages that high as long as it doesn't reach that voltage or am I likely to have fried capacitors soon?
Now I need to find a way to force these discharges to be unidirectional. I have a single hv diode that came from the microwave and it seems like it can handle pretty high current but I'm hesitant to discharge the cap through it, as I can imagine that the discharge might break it.
Any thoughts?
I have a site I'll be posting all of the info from my experiment soon.
Thanks,
`John
There's so much information out there, but sometimes it's hard to get to the root of it.
---
I'm finally getting some practical hands on experience with this stuff. My goal is to start with the basics and see if I can produce the same conditions in which Tesla first observed radiant energy.
I have succeeded in building a high voltage power supply, I built it from a simple 555 timer and a flyback transformer from a CRT monitor. The nice thing about it, is the transformer has diodes between each layer of the secondary, so I don't need to try to rectify my HV output. The downside is I only get a half-wave, but oh well, it's a start.
From there I'm able to charge a high voltage capacitor and discharge that over a spark gap.
I've got a few HV capacitors, one is from a microwave with a pretty high capacitance, and another from the CRT logic board which has a much lower capacitance. Obviously I can get much more powerful impulses from the microwave capacitor, but I can charge the smaller one much more rapidly giving me higher frequency discharges.
However like I said my aim is to see if I can detect the radiant discharge that Tesla described in the lecture, so at least to start with, I'm not concerned with high frequencies.
So, out of curiosity, my capacitor is rated for about 2kv, and I have my spark gap set very small, a few mm at most. So I'm expecting that I'll never get a charge up to 2kv, but what I'm worried about is my HV power supply produces discharges in air about 5-7 cm. Which I figure is a lot higher than 2kv. So is the capacitor safe to be charged with voltages that high as long as it doesn't reach that voltage or am I likely to have fried capacitors soon?
Now I need to find a way to force these discharges to be unidirectional. I have a single hv diode that came from the microwave and it seems like it can handle pretty high current but I'm hesitant to discharge the cap through it, as I can imagine that the discharge might break it.
Any thoughts?
I have a site I'll be posting all of the info from my experiment soon.
Thanks,
`John
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