Partnered Output Coils - Free Energy

[tinman]

I am not in agreeance on this one Brad.

It is the Load that determines the Phase Shift for "!off the shelf!" Transformers.

A Resistive Load - should always be zero Degrees or close to it.
An Inductive Load - Should be a Current Lag.
A Capacitive Load - Should be a Voltage Lag.

This should be true on most all circuits/Transformers but not all. Some resistors (Wire Wound mostly) can have Inductive (XL) and Capacitive (XC) Components to them. This is mostly a High Frequency thing and very rarely seen to be a major problem at low frequencies.


  Chris Sykes
       hyiq.org

Well-maybe a time for a rethink, as my loads have been the same in every test-the light bulbs, which are mostly resistive with maybe a very slight inductive traight due to the curly element. The winding configuration in this regard determonds the curret phase shift between primary and secondary coils. There is a reason for this, and we will get into that soon.

Question for you all.
Hook an AC cap to an AC current source-dose a magnetic field exist with the E field between the cap plates?.

[Magluvin]

E field or not, if current flows through the plates of a cap, then there is mag field developed accordingly by each plate.

Say if we have 2 lengths of wire laying next to each other, the will have capacitance.  Now, we connect our input to the wires at the same end of the pair. There would be a cancellation of mag field of the wires. But if the input is made at one wire at one end of the pair, and the other input to the other wire at the other end of the pair, the mag field would combine.

With the connections made at the same end, the wires would have opposite current flow directions, and the input connected at opposite ends of the pairs, the current in the wires would be in the same direction and have more inductance. So the best way to make a cap would be to connect the source to the same end of the pair of wires to cancel out induction so the cap can work as fast as possible.

Ive read about mag fields developed with a capacitor, probably designed to have input at opposite ends of the wire example.

Mags

[EMJunkie]

Well-maybe a time for a rethink, as my loads have been the same in every test-the light bulbs, which are mostly resistive with maybe a very slight inductive traight due to the curly element. The winding configuration in this regard determonds the curret phase shift between primary and secondary coils. There is a reason for this, and we will get into that soon.

Question for you all.
Hook an AC cap to an AC current source-dose a magnetic field exist with the E field between the cap plates?.

Tinman - I see where you're going. I misunderstood you in your prior posts.

Re; the question - any Charge in motion constitutes a Magnetic Field - This we already know. The Magnetic Field is Concentric around the Charges Equatorial Plane. There is a fair few that do not believe in "Displacement Current" - Its not a simple topic to understand unless one is up with the art...

Information that one could not spend a night reading: http://www.ivorcatt.com/em.htm

   Chris Sykes
       hyiq.org

[tinman]

E field or not, if current flows through the plates of a cap, then there is mag field developed accordingly by each plate.

Say if we have 2 lengths of wire laying next to each other, the will have capacitance.  Now, we connect our input to the wires at the same end of the pair. There would be a cancellation of mag field of the wires. But if the input is made at one wire at one end of the pair, and the other input to the other wire at the other end of the pair, the mag field would combine.

With the connections made at the same end, the wires would have opposite current flow directions, and the input connected at opposite ends of the pairs, the current in the wires would be in the same direction and have more inductance. So the best way to make a cap would be to connect the source to the same end of the pair of wires to cancel out induction so the cap can work as fast as possible.

Ive read about mag fields developed with a capacitor, probably designed to have input at opposite ends of the wire example.

Mags

Cool,now apply this to transformer winding configurations,and figure out what type of winding configuration would cause a magnetic coupling between the two winding's,and what type of winding configuration would cause an E field coupling(if any). Also take into consideration capacitive coupling-oh wait,that !is! electric field coupling between windings.
Mag's says-Quote:  if current flows through the plates of a cap, then there is mag field developed accordingly by each plate

So lets say it is the E field that is creating an EMF in the secondary,and E field coupling is capacitive coupling,and when we have a current flowing through a capacitor,there is(as Mags says) a magnetic field

[minnie]

 
  When dose current flow "through a capacitor"?
              John.