Rotating transformers for electrical machines

What is claimed is: 1. A wound field synchronous machine, comprising: a rotating transformer, comprising: a stator printed circuit board (PCB) arranged along a rotation axis; a rotary PCB axially separated from the stator PCB by a gap and supported for relative rotation about the rotation axis relative to the stator PCB, a coil surface of the rotary PCB axially opposing a coil surface of the stator PCB across the gap; a ferromagnetic core connected to a core surface of the stator PCB on a side of the stator PCB axially opposite the coil surface; a ferromagnetic core connected to a core surface of the rotary PCB on a side of the rotary PCB axially opposite the coil surface; and conductors fixed to the coil surfaces of the stator PCB and the rotor PCB, each conductor including, first and second spiral coils configured to transfer electrical energy between the stator PCB and the rotary PCB, the second spiral coil circumferentially offset from the first spiral coil about the rotation axis; a bridge segment extending through the PCB electrically connecting the second spiral coil with the first spiral coil, wherein the first and second spiral coils are arranged on only one side of the respective PCB such that the first and second spiral coils of rotary PCB conductor and the first and second spiral coils of the stator PCB conductor are wholly disposed within the gap; a main field rotating power converter connected to the rotary PCB of the rotating transformer; a control power module connected to the stator PCB of the rotating transformer, wherein the control power module is electromagnetically connected by the stator PCB and the rotary PCB of the rotating transformer to the main field rotating power converter. 2. The rotating transformer as recited in claim 1 , wherein the conductor includes foil adhered to the coil surface of the PCB. 3. The rotating transformer as recited in claim 1 , wherein the spiral coil traces a polygonal path over the coil surface of the PCB through an etched copper sheet conductive structure. 4. The rotating transformer as recited in claim 3 , wherein the PCB includes an insulating substrate connecting the ferromagnetic core to the first and second spiral coils, the insulating substrate axially separating the first and second spiral coils from the ferromagnetic core. 5. The rotating transformer as recited in claim 4 , wherein the isolating substrate and the ferromagnetic core are disk-shaped. 6. The rotating transformer as recited in claim 1 , wherein the first and second spiral coils are electrically connected in series. 7. The rotating transformer as recited in claim 1 , wherein the conductor includes three or more spiral coils electrically connected in series and respectively configured to form alternating poles about a circumference of the PCB. 8. The wound field synchronous machine as recited in claim 1 , wherein the rotary PCB is connected to an internal power supply disposed on a rotating part of the machine and configured to provide current to main field windings of the wound field synchronous machine. 9. The wound field synchronous machine as recited in claim 1 , wherein the rotary PCB is connected to a demodulating module disposed on a rotating part of the wound field synchronous machine and configured for modulating current flow through main field windings of the wound field synchronous machine. 10. The wound field synchronous machine as recited in claim 1 , wherein the rotating transformer is a first rotating transformer and further including a second rotating transformer connected to the control power module. 11. The wound field synchronous machine as recited in claim 10 , further including: a pulse width module connected to the stator PCB of the first rotating transformer and configured for supplying power to the main field windings; and a modulator/driver connected to the stator PCB of the second rotating transformer and configured for modulating current flowing through the main field windings. 12. A wound field synchronous machine, comprising: a rotating transformer, comprising: a stator printed circuit board (PCB) with a coil surface and a core surface arranged along a rotation axis and axially separated by an insulating substrate; a ferromagnetic core connected to the core surface of the stator PCB on a side of the stator PCB axially opposite the coil surface; a single stator coil comprising a foil body adhered to the coil surface of the stator PCB, the stator coil extending about the rotation axis arranged axially on only one side of the stator PCB; a rotary PCB axially separated from the stator PCB by a gap and supported for relative rotation about the rotation axis relative to the stator PCB, a coil surface of the rotary PCB axially opposing a coil surface of the stator PCB across the gap; a ferromagnetic core connected to a core surface of the rotary PCB on a side of the rotary PCB axially opposite the coil surface; and a single rotary coil comprising a foil body adhered to the coil surface of the rotary PCB, the rotary coil extending about the rotation axis arranged axially on only one side of the rotary PCB within the gap such that only the single stator coil and the single rotary coil are disposed within the gap, the rotary coil and the stator coil being wholly disposed within the gap a main field rotating power converter connected to the rotary PCB of the rotating transformer; A control power module connected to the stator PCB of the rotating transformer, wherein the control power module is electromagnetically connected by the stator PCB and the rotary PCB of the rotating transformer to the main field rotating power converter.