Partnered Output Coils - Free Energy

[EMJunkie]

...

Isn't it ironic. We had access to Electricity before we had induction... Some 184 years after Induction was discovered, we here debate its principals...

One of my favorite documentaries: Shock And Awe The Story Of Electricity - / 2:54:54 so leave plenty of time...

   Chris Sykes
       hyiq.org

[MagnaProp]

...As the flyback is captured it's sent through the coil again in the same direction the electricity was initially flowing in so it kills it's self while keeping the initial field there longer...

Not sure I understand this after all. I don't see how the diode helps if it sends current the wrong way as shown by the green arrow. We want current to keep flowing in the red arrow direction so we some how need it to follow the purple arrow path that shows it being fed back into the coil in the same direction the initial red arrow current was going.

@gotoluc- As simple as it is, can you make a schematic of your diode circuit and the direction "electron" current flows in it?

[tinman]

Not sure I understand this after all. I don't see how the diode helps if it sends current the wrong way as shown by the green arrow. We want current to keep flowing in the red arrow direction so we some how need it to follow the purple arrow path that shows it being fed back into the coil in the same direction the initial red arrow current was going.

@gotoluc- As simple as it is, can you make a schematic of your diode circuit and the direction "electron" current flows in it?

In the pic below,the red arrows show conventional current flow direction when a current is supplied by a power source to the coil. The red + and - show the voltage polarity. The blue arrows show the current flow direction when the supply current to the coil is broken,and the blue + and - show the voltage polarity. So you see,the current will continue to flow in the same direction when the current supply to the inductor(coil) is broken(disconnected),but the voltage polarity will invert.

[tinman]

A number of posts back, I asked this question:



To help with your question, perhaps you or Mags could try filling in the blank. (Also, see this post above)

"And whenever there is a changing magnetic field, there is also a corresponding changing electric field."

But an electric field alone dose not exist without a magnetic field when that electric field is changing,and visa versa. So in order for induction to take place,and an EMF produced,we must have a changing magnetic field,and thus a magnetic flux cutting the inductors windings. An electric field that dose not change has no magnetic field,and it will not induce an EMF in a conductor.

[tinman]

I was waiting for your comment on this one Brad as Jeg is using AC, switching coil connections and not showing how the input power is affected while doing these changes. So I didn't understand how it could compared to your original test suggestion?... but I'm always eager to learn something new

Hopefully Jeg can do the bulb load and show how it affects the input power

Luc

Jeg is showing something different,and indeed his power draw will go up when the secondary has a load placed on it. But i like what he showed,and i wonder who here knows why the two coils repel when hooked up one way,and yet attract when they are hooked up the other way.
here is a little hint-->note the size and shape of each coil.