Rotary electric machine

The invention claimed is: 1. A rotary electric machine, comprising: field windings supplied with DC power; armature windings supplied with AC power; a stator core formed into a ring-like shape including field slots and armature slots, the field slots housing the field windings, the armature slots housing the armature windings, the field slots and the armature slots alternating in a circumferential direction of the stator core; permanent magnets housed in magnet slots formed in the field slots, each magnet slot being adjacent in the radial direction to a field slot on an inner circumferential side and on an outer circumferential side of the magnet slot; and a rotor core opposite to the stator core, with a predetermined air gap being interposed between the rotor and stator, wherein each of the permanent magnets is arranged in a corresponding magnet slot such that each magnetic pole face of one the permanent magnets faces, in a circumferential direction, to a magnetic pole face of an adjacent one of the permanent magnets and a non-pole face directly faces, in the radial direction, to a field winding on an outer circumferential side and on an inner circumferential side of the magnet slots, coil ends of the armature windings straddle predetermined ones of the field slots and pass over an axial end face of the permanent magnets in the predetermined field slots, and the field windings are arranged such that coil ends of the field windings do not intersect with coil ends of the armature windings as viewed from an axial direction of the stator core. 2. The rotary electric machine of claim 1 , wherein a radial width of the armature slots is equal to or less than twice as large as a radial width of the permanent magnets. 3. The rotary electric machine of claim 1 , wherein the armature windings are made of segment coils. 4. The rotary electric machine of claim 1 , wherein a non-pole face of the permanent magnets facing a field winding is parallel to a direction in which the coil end of the armature windings passes over the axial end face of the permanent magnets. 5. A rotary electric machine, comprising: field windings supplied with DC power; armature windings supplied with AC power; a stator core formed into a ring-like shape including field slots and armature slots, the field slots housing the field windings, the armature slots housing the armature windings, the field slots and the armature slots alternating in a circumferential direction of the stator core; permanent magnets housed in magnet slots formed in the field slots, each magnet slot being adjacent in the radial direction to a field slot on an inner circumferential side and on an outer circumferential side of the magnet slot; and a rotor core opposite to the stator core, with a predetermined air gap being interposed between the rotor and stator, wherein each of the permanent magnets is arranged in a corresponding magnet slot such that each magnetic pole face of one the permanent magnets faces, in a circumferential direction, to a magnetic pole face of an adjacent one of the permanent magnets and a non-pole face directly faces, in the radial direction, to a field winding on an outer circumferential side and on an inner circumferential side of the magnet slots, coil ends of the armature windings straddle predetermined ones of the field slots and pass over an axial end face of the permanent magnets in the predetermined field slots, the stator core has an edge portion closer to an outer circumferential side of the stator than the armature slots, a coil end of the field windings arranged on an outer circumferential side of the permanent magnets passes over the axial end face of the edge portion, and a radial width of the edge portion is larger than a radial width of the field windings arranged on the outer circumferential side of the permanent magnets. 6. A rotary electric machine, comprising: field windings supplied with DC power; armature windings supplied with AC power; a stator core formed into a ring-like shape including field slots and armature slots, the field slots housing the field windings, the armature slots housing the armature windings, the field slots and the armature slots alternating in a circumferential direction of the stator core; permanent magnets housed in magnet slots formed in the field slots, each magnet slot being adjacent in the radial direction to a field slot on an inner circumferential side and on an outer circumferential side of the magnet slot; and a rotor core opposite to the stator core, with a predetermined air gap being interposed between the rotor and stator, wherein each of the permanent magnets is arranged in a corresponding magnet slot such that each magnetic pole face of one the permanent magnets faces, in a circumferential direction, to a magnetic pole face of an adjacent one of the permanent magnets and a non-pole face directly faces, in the radial direction, to a field winding on an outer circumferential side and on an inner circumferential side of the magnet slots, coil ends of the armature windings straddle predetermined ones of the field slots and pass over an axial end face of the permanent magnets in the predetermined field slots, the stator core includes teeth, between the field slots and the armature slots, around which at least one of the field windings and armature windings are wound, surfaces of the teeth facing the armature slots are provided with flanges protruding into the armature slots, and a coil end of the field windings arranged on an inner circumferential side of the permanent magnets passes over an axial end face of the flange. 7. A rotary electric machine, comprising: field windings supplied with DC power; armature windings supplied with AC power; a stator core formed into a ring-like shape including field slots and armature slots, the field slots housing the field windings, the armature slots housing the armature windings, the field slots and the armature slots alternating in a circumferential direction of the stator core; permanent magnets housed in magnet slots formed in the field slots, each magnet slot being adjacent in the radial direction to a field slot on an inner circumferential side and on an outer circumferential side of the magnet slot; and a rotor core opposite to the stator core, with a predetermined air gap being interposed between the rotor and stator, wherein each of the permanent magnets is arranged in a corresponding magnet slot such that each magnetic pole face of one the permanent magnets faces, in a circumferential direction, to a magnetic pole face of an adjacent one of the permanent magnets and a non-pole face directly faces, in the radial direction, to a field winding on an outer circumferential side and on an inner circumferential side of the magnet slots, coil ends of the armature windings straddle predetermined ones of the field slots and pass over an axial end face of the permanent magnets in the predetermined field slots, and the coil end of the field windings arranged on the inner circumferential side of the permanent magnets passes over at least one of the air gap and the axial end face of the rotor core.