Abstract: A stator assembly for a dynamoelectric machine featuring a cascaded construction includes several conductors, each having a plurality of slot segments interconnected by plurality of end loop segments. The consecutive slot segments of a first conductor forms nearly all of a radially-outermost first layer of the stator winding, with the remaining portion of the radially-outermost winding layer being defined by a slot segment of a second conductor that is then inserted into the core to form nearly all of a second layer of the stator winding radially-inwardly of the first winding layer. The second winding layer is completed with an additional single slot segment of the first conductor.

Abstract: A stator and rotor assembly of a dynamoelectric machine wherein the stator core of the stator assembly includes a plurality of stator ring slots and the rotor assembly includes a plurality of rotor ring slots. The stator assembly further includes a conductor disposed in each stator ring slot having a plurality of full revolutions around the central axis of the stator core. The rotor assembly further including a rotor conductor disposed in each rotor ring slot having a plurality of full revolutions around the central axis of the rotor assembly. The stator core and rotor assembly both include tooth portions to direct the flux produced by the rotor conductor around the stator in the proper manner to induce the desired generated voltage in each stator conductor, thereby enabling each conductor to have the desired phase angle.

Abstract: A stator for an electric machine includes a generally cylindrically-shaped stator core having a plurality of core teeth that define a plurality of core slots, the core slots extend between first and second ends of the stator core. A stator winding has a plurality of phases, N, each phase including at least one conductor having a plurality of slot segments housed in the core slots, the slot segments are alternately connected at the first and second ends by a plurality of end loop segments. At least one conductor has a slot segment that is switched with an adjacent conductor such that the conductor has an end loop segment having a pitch equal to N+1 and the end loop segment of the adjacent conductor has a pitch equal to N?1, wherein the end loop segments of the conductor and the adjacent conductor do not cross one another. The stator also reduces overall noise of an electric machine.

Abstract: A stator for an electric machine includes a generally cylindrically-shaped stator core having a plurality of circumferentially-spaced and axially-extending core teeth that define a plurality of circumferentially-spaced and axially-extending core slots extending between first and second ends of the stator core. Within the core is a stator winding having a plurality of phases, each of the phases including at least one conductor having a plurality of slot segments housed in the core slots. The slot segments are alternately connected at the first and second ends of the stator core by a plurality of end loop segments. The stator core defines an inner diameter and each of the core slots has an end. The winding only partially fills the core slots between the inner diameter and the ends such that there is empty space between the inner diameter and the end within each of the core slots.

Abstract: A method of forming a stator for an electric machine having a cascaded winding includes the steps of: providing a stator core having a plurality of circumferentially spaced and axially-extending core slots in a surface thereof, forming a plurality of A conductors and a plurality of B conductors, arranging the A and B conductors into a wire pack, rolling the wire pack into a cylindrical shape and inserting the wire pack within the stator core, and expanding the wire pack radially outward such that the wire pack is inserted within the slots of the stator core.

Abstract: A method for making a stator assembly includes forming several continuous conductors with generally-coplanar parallel-spaced straight segments interconnected by end loop segments, as by winding each of several conductors on a peg board, and then pressing the conductors to form either one, two, or three generally-orthogonal “jogs” in a given end loop segment. The conductors are interpositioned with their straight segments staggered and with a first leg of each subsequent conductor's end loop segments generally overlying a second leg of the immediately-prior conductor's end loop segments, except for the two end loop segments following the first conductor's “nth” straight segment, and multiples thereof, where the stacking order is reversed (“n” being equal to the number of stator core slots divided by the number of conductors that will form a given winding layer).

Abstract: A stator of a rotary electric machine having secured core slot insulators includes a multi-phase stator winding, having a plurality of slot segments that are adapted to be radially inserted into a plurality of circumferentially spaced axially-extending core slots in a surface of a cylindrically-shaped stator core. The stator winding includes the plurality of slot segments alternately connected at the first and second ends of the stator core by a plurality of end loop segments to form the winding. The plurality of core slots house an insulator to electrically isolate the slot segments from the core slots. The insulator is secured to the sides of the core slot prior to the process of radial inserting the plurality of slot segments into the plurality of core slots of the cylindrically-shaped stator core.

Abstract: A stator assembly for a dynamoelectric machine in accordance with the present invention includes a generally cylindrically-shaped stator core having a plurality of core slots formed along the inner surface thereof and defined by a radial depth and wherein a stator coil is disposed. The plurality of core slots defines a plurality of teeth therebetween, which have caps along the inner surface of the stator core and are connected to the stator core by a yoke portion. The plurality of core slots is lined along respective inner surfaces by a plurality of insulation slot liners. The teeth caps include projections along an inner diameter of the plurality of core slots. The slot openings are delimited by the projections along the stator inner diameter. These projections are substantially equal to a width of the slot liners, and are such that the delimited slot openings are substantially equal to a width of a conductor wire to be inserted into the lined core slots.

Abstract: A stator assembly for an alternator in accordance with the present invention includes a generally cylindrically-shaped stator core having a plurality of core slots formed along the inner surface thereof and defined by a radial depth and wherein a stator coil is disposed. The core slots thereby define a plurality of teeth therebetween, which are connected to the stator core by a yoke portion. The core slots are shaped and extend between a first and a second end of the stator core. A plurality of clips closely fit into one of said core slots for lining each respective core slot. The clips have a pair of extending leg members connected to a back end and forming an aperture therebetween. The clips are formed from a magnetically permeable material. A stator winding includes substantially straight wire segments that are received by the clips formed of substantially straight wire segments. The substantially straight wire segments of the stator winding and the clips are electrically insulated from one another.

Abstract: A stator for a dynamoelectric machine improves the cooling of the stator winding without increasing the size of the stator winding or the entire stator. The stator is of a unique construction wherein the size, and more specifically the cross sectional area or volume of the individual conductors is greatly reduced, while the total number of conductors is increased. In addition, a multiple filar construction is employed to avoid the potential for high levels of inductance and resistance in the conductors and to minimize the interference between the cascaded stator end loops and the housing that surrounds the stator.

Abstract: A stator of a rotary electric machine having secured core slot insulators includes a multi-phase stator winding, having a plurality of slot segments that are adapted to be radially inserted into a plurality of circumferentially spaced axially-extending core slots in a surface of a cylindrically-shaped stator core. The stator winding includes the plurality of slot segments alternately connected at the first and second ends of the stator core by a plurality of end loop segments to form the winding. At least one of the core teeth includes a distal end that is staked such that the distal end of the at least one core tooth is flared outward circumferentially to secure the stator winding within the core slots.

Abstract: A stator for an electric machine includes a generally cylindrically-shaped stator core having a plurality of circumferentially spaced core slots. A stator winding includes a plurality of phases, each including at least a first filar and a second filar extending circumferentially around the stator core to form a plurality of layers. Each of the filars is a conductor having a plurality of slot segments disposed in the core slots. The slot segments are alternately connected at the first and second ends of the stator core by a plurality of end loop segments that may form a cascaded winding pattern. The plurality of filars of each phase alternating radial positions with one another within at least one end loop segment at discreet locations around the stator core such that the average radial position of the slot segments of the first filar conductors is substantially equal to that of the second filar.

Abstract: A stator assembly for a dynamoelectric machine featuring a cascaded construction includes several conductors, each having a plurality of slot segments interconnected by plurality of end loop segments. The consecutive slot segments of a first conductor forms nearly all of a radially-outermost first layer of the stator winding, with the remaining portion of the radially-outermost winding layer being defined by a slot segment of a second conductor that is then inserted into the core to form nearly all of a second layer of the stator winding radially-inwardly of the first winding layer. The second winding layer is completed with an additional single slot segment of the first conductor.