We are all taught that a copper wire acts as a conduit for electric current. That current then flows in the wire just like water of a river, bordered and guided by the river banks.
Both Nikola Tesla and Walter Russell describe the perceived electric current runs AROUND the wire and not IN the wire.
Spliced electric wires
If the main stream scientific view is correct, then how does this typical technique of joining wires manage to achieve a current flow IN the wire ?
A continuous flow makes no sense yet the effect is transferred from one wire to another ! Can WRC explain this ?
Mareks
3rd January 2017Why don’t I get a shock, when the copper wire is isolated, if the current flows around the wire ?
WalRus
4th January 2017This is a great question Mareks, but rather than answering a question with a question, I would rather focus the mind on applying WRC to addressing the problem highlighted in the original post 🙂 I think your question is worthy of a more detailed response, perhaps within the body of the site itself. I will address your point in due course. At present, I would like to better understand how WRC can be applied to explain the obvious problem of simple electron flow which I flagged in the original post.
DeanB
3rd January 2017Di-electricity. Quoting Oliver Heaviside “the perfect conductor is the perfect insulator”. Copper is a very good conductor of conventional electric current and a very good insulator against di-electric current.
In comparison, di-electric materials are very good conductors of di-electricity and very good insulators against the type of electric current than can shock you. Which can sound fairly counter-intuitive, but part of the trick is four, not two :).
Two types of amperes and two types of volts in reference to Dr. Eric Dollard. Unfortunately, only a handful of people have explored this. One of those people is Dr. Nikola Tesla.
“Voltage not hertz”. Hertz are sinusoidal. Direct current has no frequency (Eric D.). And no frequency means scalar in time (outside of the dimension of time). Which is part of what di-electricity leans towards. Hope that helps somewhat :).
DeanB
3rd January 2017Forgot to add, that electrical sheathing is made from di-electric material. Di-electric material is a very good conductor of di-electric current, and very bad conductor of conventional electric current.
Johan
27th January 2017I wonderhow wr sees that
DeanB
8th February 2017The use of a coil equals alternating current? Two or more strands of copper wire wrapped around each other are enough to convert to DC to AC in my understanding. Or the filament of a light bulb, taking that you are using a straight piece of copper wire (DC) leading into the light bulb. And filament (coil) converts DC into AC by being coiled.