Electric motor with selective flux stator

The invention claimed is: 1. A poly-phase synchronous electric motor comprising: a rotor including a motor shaft delineating a rotational axis a stator concentrically disposed about the rotor, the stator including a stator core and a plurality of radially arranged stator teeth concentrically separated from each other by a plurality of stator slots disposed radially into an inner cylindrical stator surface of the stator core; a plurality of coils formed from conductive windings each wound around one or more of the plurality of stator teeth, the plurality of coils arranged in a plurality of phases each operatively associated with an electrical phase, wherein at least one phase includes one or more permanent coils and at least one bypass coil, the plurality of coils further arranged in a concentric winding pattern with a concentrically outermost coil of the concentric winding pattern is the at least one bypass coil; a primary position that electrically connects with the permanent coils and bypass coils to deliver full line power thereto during a rated flux condition, a tapped position that electrically connects with only the permanent coils to deliver full line power thereto during a high flux condition characterized by an increased magnitude of magnetic flux compared to the rated flux condition, and a switching device configured to selectively switch between communicating power to the tapped position and the primary position to bypass the bypass coils. 2. The electric motor of claim 1 , wherein the permanent coils of the phase are electrically connected in series. 3. The electric motor of claim 2 , wherein the at least one bypass coil of the phase is electrically connected to the permanent coils when not bypassed. 4. The electric motor of claim 1 , wherein the one or more permanent coils and the at least one bypass coil have different turns-per-coil with respect to the conductive windings included therein. 5. The electric motor of claim 1 , wherein the electric motor is a three-phase motor with three phases and the plurality of coils per phase is sixteen with twelve permanent coils and four bypass coils. 6. The electric motor of claim 1 , wherein the electric motor is four pole motor and the plurality of coils are further arranged in a plurality of phase groups each with three permanent coils and one bypass coil. 7. The electric motor of claim 1 , wherein the switching device is a timer configured to switch from the primary position to the tapped position after a predetermined acceleration period and to switch from the tapped position to the primary position after a predetermined synchronization period. 8. The electric motor of claim 1 , wherein the switching device is relay switch and a control parameter for switching the relay switch is selected from the group comprising motor speed and current draw. 9. The electric motor of claim 1 , wherein the rotor is a caged rotor permanent magnet type including an inductive rotor cage. 10. A method of electric motor operation comprising: coupling a motor shaft of a poly-phase synchronous electric motor to an inertia load, the electrical motor including a plurality of coils arranged in at least one phase; applying full line power to the plurality of coils during a rated flux condition from motor standstill; electrically disconnecting at least one bypass coil of the plurality of coils of the at least one phase from the full line power with a switching device; applying full line power to one or more permanent coils of the plurality of coils of the at least one phase during a high flux condition characterized by an increased magnitude of the magnetic flux compared to the rated flux condition; and electrically reconnecting the at least one bypass coil of the plurality of coils of the at least one phase with the switching device after obtaining synchronous operation of the electric motor to return to the rated flux configuration and to apply full line power to the at least one bypass coil. 11. The method of claim 10 , wherein the step of electrically disconnecting the at least one bypass coil occurs after a predetermined acceleration period. 12. The method of claim 10 , wherein the step of electrically disconnecting the at least one bypass coil occurs after detecting a control parameter that is selected from the group comprising motor speed and current draw. 13. The method of claim 10 , wherein a difference between the high flux condition and the rated flux condition determines a flux boost of the electric motor. 14. The method of claim 10 , wherein the plurality of coils is arranged on one of a lap winding pattern and a concentric winding pattern. 15. A synchronous electric motor comprising: a rotor including a motor shaft delineating a rotational axis; a stator concentrically disposed about the rotor, the stator including a stator core with a plurality of radially arranged stator teeth concentrically separated from each other by a plurality of stator slots disposed radially into an inner cylindrical stator surface of the stator core; a plurality of coils formed from conductive windings each wound around one or more of the plurality of stator teeth, the plurality of coils including one or more permanent coils and at least one bypass coil that are electrically connected in series; a primary position that electrically connects the bypass coils and the permanent coils to a power lead to deliver full line power thereto during a rated flux condition; a tapped position that electrically connects only the permeant coils to the power lead to deliver full line power thereto during a high flux condition characterized by an increased magnitude of magnetic flux compared to the rated flux condition; and a switching device configured to selectively switch between a high flux condition connecting the permanent coils to the power lead to bypass the bypass coils if the electric motor is operating below synchronous speed, and a rated flux condition reconnecting the primary position to the power after the electric motor achieves synchronous speed. 16. The electrical motor of claim 15 , wherein the plurality of coils in the phase is arranged in a lap winding pattern. 17. The electrical motor of claim 16 , wherein the plurality of coils in the phase each have the same coil pitch as determined by the number of stator teeth the coils are wound around. 18. The electrical motor of claim 17 , wherein the one or more permanent coils and the at least one bypass coil have different turns-per-coil with respect to the conductive windings included therein. 19. The synchronous electric motor of claim 15 , wherein the switching device is selected from the group comprising a timer configured to switch to the rated flux condition after a predetermined synchronization period, and a relay switch configured with a control parameter for switching the relay switch, wherein the control parameter is one of motor speed or current draw. 20. The synchronous electric motor of claim 15 , wherein the plurality of coils are arranged in a concentric winding pattern and a concentrically outermost coil of the concentric winding pattern is the at least one bypass coil.