Electro-mechanical kinetic energy storage device and method of operation

What is claimed is: 1. An electro-mechanical kinetic energy storage device comprising: an input port configured to receive a first input electrical energy from a first electrical component to induce at least a first portion of mechanical energy in the electro-mechanical kinetic energy storage device; an output port configured to output a first converted electrical energy to a first load; a tertiary port electrically separate from and magnetically coupled to the input port and the output port, the tertiary port configured to: receive a second input electrical energy from a second electrical component to induce at least a second portion of the mechanical energy in the electro-mechanical kinetic energy storage device; and output a second converted electrical energy to a second load; a flywheel coupled to a shaft of an electrical machine, the flywheel configured to store the mechanical energy; a first electrical winding set coupled to the input port; a second electrical winding set coupled to the output port; and a tertiary electrical winding set coupled to the tertiary port, the tertiary electrical winding set configured to provide in-phase alternating currents relative to either the first electrical winding set or the second electrical winding set; wherein the electro-mechanical kinetic energy storage device is configured to generate the first converted electrical energy and the second converted electrical energy from the induced mechanical energy. 2. The electro-mechanical kinetic energy storage device of claim 1 , wherein the tertiary electrical winding set is further configured to provide time quadrature alternating currents relative to either the first electrical winding set or the second electrical winding set in order to provide reactive power control for at least one of the first electrical winding set or the second electrical winding set. 3. The electro-mechanical kinetic energy storage device of claim 1 , wherein the electrical machine comprises a wound-field synchronous machine with multiple port stator windings and at least one rotor port. 4. The electro-mechanical kinetic energy storage device of claim 1 , wherein the electrical machine comprises an induction machine. 5. The electro-mechanical kinetic energy storage device of claim 1 , wherein the tertiary port is configured to receive the second input electrical energy at a frequency, a pulse duty cycle, and a nominal current level that are different from a frequency, a pulse duty cycle, and a nominal current level at which the first input electrical energy is received by the input port. 6. The electro-mechanical kinetic energy storage device of claim 1 , wherein: the first converted electrical energy comprises a short duration pulse that is configured to power the first load; and the first load comprises one or more of: a pulsed laser device; an electro-magnetic launcher; a pulsed radar device; a pulse forming network configured for pulse shaping; a device having an intermittent power input; and a device configured to intermittently provide regenerative power. 7. The electro-mechanical kinetic energy storage device of claim 1 , wherein the second electrical component comprises a frequency converter configured to convert all or a portion of the first input electrical energy into the second input electrical energy having an electrical frequency of operation different from that of the first input electrical energy. 8. The electro-mechanical kinetic energy storage device of claim 1 , wherein the first converted electrical energy comprises a short duration pulse that is configured to power the first load. 9. An electro-mechanical kinetic energy storage system comprising: a power source; and an electro-mechanical kinetic energy storage device configured to electrically couple to the power source, the electro-mechanical kinetic energy storage device comprising: an input port configured to receive a first input electrical energy from a first electrical component to induce at least a first portion of mechanical energy in the electro-mechanical kinetic energy storage device; an output port configured to output a first converted electrical energy to a first load; a tertiary port configured to: receive a second input electrical energy from a second electrical component to induce at least a second portion of the mechanical energy in the electro-mechanical kinetic energy storage device; and output a second converted electrical energy to a second load; a flywheel coupled to a shaft of an electrical machine, the flywheel configured to store the mechanical energy; a first electrical winding set coupled to the input port; a second electrical winding set coupled to the output port; and a tertiary electrical winding set coupled to the tertiary port, the tertiary electrical winding set configured to provide in-phase alternating currents relative to either the first electrical winding set or the second electrical winding set; wherein the electrical machine is configured to generate the first converted electrical energy and the second converted electrical energy from the induced mechanical energy. 10. The electro-mechanical kinetic energy storage system of claim 9 , wherein the tertiary electrical winding set is further configured to provide time quadrature alternating currents relative to either the first electrical winding set or the second electrical winding set in order to provide reactive power control for at least one of the first electrical winding set or the second electrical winding set. 11. The electro-mechanical kinetic energy storage system of claim 9 , wherein the electrical machine comprises a wound-field synchronous machine with multiple port stator windings and at least one rotor port. 12. The electro-mechanical kinetic energy storage system of claim 9 , wherein the tertiary port is configured to receive the second input electrical energy at a frequency, a pulse duty cycle, and a nominal current level that are different from a frequency, a pulse duty cycle, and a nominal current level at which the first input electrical energy is received by the input port. 13. The electro-mechanical kinetic energy storage system of claim 9 , wherein the first converted electrical energy comprises a short duration pulse that is configured to power the first load. 14. The electro-mechanical kinetic energy storage system of claim 13 , wherein the first load comprises one or more of: a pulsed laser device; an electro-magnetic launcher; a pulsed radar device; a pulse forming network configured for pulse shaping; a device having an intermittent power input; and a device configured to intermittently provide regenerative power. 15. The electro-mechanical kinetic energy storage system of claim 9 , wherein the second electrical component comprises a frequency converter configured to convert all or a portion of the first input electrical energy into the second input electrical energy having an electrical frequency of operation different from that of the first input electrical energy. 16. The electro-mechanical kinetic energy storage system of claim 9 , further comprising: a battery inductive storage module selectably coupled to the electro-mechanical kinetic energy storage device; a main link converter; an auxiliary frequency converter; and an input line circuit breaker configured to isolate the power source from the electro-mechanical kinetic energy storage device; wherein, when the power source is inactive or the input line circuit breaker is open, the battery inductive storage module is configured to be char