Sealed switched reluctance motor

What is claimed is: 1 . A motor comprising: a rotor configured as a switched reluctance rotor, and having two sets of rotor poles offset by an electrical angle, configured for at least three phase excitation; and a stator configured as a brushless stator separated from the rotor by a sealed partition; wherein the switched reluctance rotor is configured so that a rotor pole, of each set of rotor poles, forms a flux path with each energized winding of the stator. 2 . The motor of claim 1 , wherein the switched reluctance rotor and stator are configured to generate an axial flux flow in the motor. 3 . The motor of claim 1 , wherein the switched reluctance rotor comprises at least one salient rotor pole comprising a set of axially displaced sub-poles. 4 . The motor of claim 1 , wherein the stator comprises independent sets of at least three phase windings. 5 . The motor of claim 1 , wherein the stator comprises a set of independent stator modules, each comprising a stator pole and an excitation coil. 6 . The motor of claim 1 , further comprising an arrangement of rotor poles and stator poles configured to apply attractive forces to the rotor. 7 . The motor of claim 1 , wherein the switched reluctance rotor comprises a non-magnetic core and includes at least one salient rotor pole that is ferromagnetic. 8 . The motor of claim 1 , wherein the stator includes at least one salient stator pole configured as a slot through which at least one salient rotor pole of the switched reluctance rotor passes to effect an axial flux flow circuit. 9 . A motor comprising: a switched reluctance rotor; and a stator comprising a plurality of independent stator modules arranged around the rotor, each stator module having salient stator poles sealed from the switched reluctance rotor. 10 . The motor of claim 9 , wherein the switched reluctance rotor comprises a non-magnetic core and ferromagnetic rotor poles. 11 . The motor of claim 10 , wherein the ferromagnetic rotor poles and the salient stator poles are arranged to effect a flux flow axial to the switched reluctance rotor. 12 . The motor of claim 9 , wherein the salient stator poles are segmented so as to form slots through which rotor poles of the switched reluctance motor pass to effect a flux flow axial to the switched reluctance rotor. 13 . The motor of claim 9 , wherein rotor poles of the switched reluctance rotor and the salient stator poles are configured with facing end members to effect a flux flow axial to the switched reluctance rotor. 14 . The motor of claim 9 , wherein at least one of the stator modules is disposed so as to interface sub-poles of at least one salient rotor pole of the switched reluctance rotor. 15 . A method comprising: providing a switched reluctance rotor that has two sets of rotor poles offset by an electrical angle and configured for at least three phase excitation; providing a brushless stator separated from the switched reluctance rotor by a sealed partition; and wherein the switched reluctance rotor is driven in rotation with but two sets of rotor poles and but two sets of independently energized windings each of which forms a flux path with each rotor pole of the but two sets of rotor poles. 16 . The method of claim 15 , wherein the switched reluctance rotor and brushless stator generate an axial flux flow in the motor. 17 . The method of claim 15 , wherein the switched reluctance rotor has at least one salient rotor pole. 18 . The method of claim 17 , wherein the at least one salient rotor pole has a set of axially displaced sub-poles. 19 . The method of claim 15 , wherein the brushless stator has independent sets of at least three phase windings. 20 . The method of claim 15 , wherein the brushless stator has a set of independent stator modules, each having a stator pole and an excitation coil. 21 . The method of claim 15 , wherein the brushless stator includes at least one salient stator pole configured as a slot wherein at least one salient rotor pole of the switched reluctance rotor passes through the slot to effect an axial flux flow circuit. 22 . The method of claim 15 , wherein at least one salient rotor pole of the switched reluctance rotor and at least one salient stator pole of the brushless stator have facing end members that effect an axial flux flow circuit. 23 . A method comprising: providing a switched reluctance rotor having a plurality of rotor poles; and arranging a plurality of independent stator modules, of a stator, around the switched reluctance rotor, where the stator modules have salient stator poles constructed as separate segments and arranged so that the salient stator poles are sealed from the switched reluctance rotor. 24 . The method of claim 23 , wherein the switched reluctance rotor has a non-magnetic core and ferromagnetic rotor poles. 25 . The method of claim 23 , wherein the rotor poles and the salient stator poles are arranged to effect a flux flow axial to the rotor.