A disc rotor machine for a motor vehicle drive is disclosed that includes a disc-shaped stator. The stator has a plurality of core segments, which are distributed in a circumferential direction and are rigidly connected to one another by means of at least one retaining ring, and a plurality of coil windings each extending around a core segment. The disc rotor machine also comprises a rotor which is mounted rotatably relative to the stator, the rotor having a first rotor disc arranged adjacent to the stator towards a first axial side and a second rotor disc arranged adjacent to the stator towards a second axial side opposite the first axial side, which rotor discs can be driven by a plurality of coils of the stator which are distributed in a circumferential direction and include the core segments and coil windings. The disc rotor machine further comprises a cooling device which cools the coils during operation, the stator having a carrier wheel which accommodates the coil windings and is connected to the at least one retaining ring, the carrier wheel forming a cooling channel portion of the cooling device that directly accommodates at least one of the coil windings.

A disc rotor machine for a motor vehicle drive is disclosed that includes a disc-shaped stator. The stator has a plurality of core segments, which are distributed in a circumferential direction and are rigidly connected to one another by means of at least one retaining ring, and a plurality of coil windings each extending around a core segment. The disc rotor machine also comprises a rotor which is mounted rotatably relative to the stator, the rotor having a first rotor disc arranged adjacent to the stator towards a first axial side and a second rotor disc arranged adjacent to the stator towards a second axial side opposite the first axial side, which rotor discs can be driven by a plurality of coils of the stator which are distributed in a circumferential direction and include the core segments and coil windings. The disc rotor machine further comprises a cooling device which cools the coils during operation, the stator having a carrier wheel which accommodates the coil windings and is connected to the at least one retaining ring, the carrier wheel forming a cooling channel portion of the cooling device that directly accommodates at least one of the coil windings.

A stator having a plurality of stator bars disposed circumferentially at intervals around an axis is provided. Each of the stator bars has a set of windings wound therearound for generating a magnetic field generally parallel to the axis. A plurality of radially outwardly disposed electrical interconnects for connecting two or more windings together are provided radially outwardly of the plurality of stator bars and extending circumferentially along at least a portion of the outer periphery of the stator bars. A plurality of radially inwardly disposed electrical interconnects for connecting two or more windings together are also provided radially inwardly of the stator bars and extending circumferentially along at least a portion of the inner periphery of the stator bars. The outer periphery of the stator is devoid of radially outwardly disposed interconnects along one or more portions.

A stator having a plurality of stator bars disposed circumferentially at intervals around an axis is provided. Each of the stator bars has a set of windings wound therearound for generating a magnetic field generally parallel to the axis. A plurality of radially outwardly disposed electrical interconnects for connecting two or more windings together are provided radially outwardly of the plurality of stator bars and extending circumferentially along at least a portion of the outer periphery of the stator bars. A plurality of radially inwardly disposed electrical interconnects for connecting two or more windings together are also provided radially inwardly of the stator bars and extending circumferentially along at least a portion of the inner periphery of the stator bars. The outer periphery of the stator is devoid of radially outwardly disposed interconnects along one or more portions.

An electric-to-hydraulic conversion machine includes an axial flux electric motor and a hydraulic pump. The motor includes a spindle, at least one rotor configured to rotate about the spindle, and at least one stator configured to drive rotation of the at least one rotor about the spindle. The hydraulic pump includes a piston block having a plurality of cylinders, a plurality of pistons each supported in one of the cylinders of the piston block, and a cam ring. The piston block is attached to the at least one rotor and is configured to rotate about the spindle with rotation of the at least one rotor. The cam ring is configured to radially drive the pistons during rotation of the piston block about the spindle, which drives a fluid flow.

A stator (10) for an axial flux electrical machine (100), an axial flux machine (100) that includes the stator (10), and a method (500) of manufacturing a stator (10) are provided. The conductive coils (12) which form the stator (10) provide a structure which includes spaces (131a, 131b, 131c, 132a, 132b) for flux guides (30), which improves ease of stator manufacture. It also allows for a high number of slots per pole per phase, which provides a more sinusoidal back-EMF. The stator (10) comprises a plurality of circumferentially distributed conductive coils (12), each of the plurality of conductive coils configured to be connected to a phase of a multi-phase power supply and comprising at least one pair of active sections (121a, 121b), wherein each active section (121a, 121b) extends in a generally radial direction substantially perpendicular to an axis of rotation of the electrical machine (100), wherein the generally radially extending active sections (121a, 121b) of each pair are pitched apart in a circumferential direction, and wherein circumferentially adjacent conductive coils (12) circumferentially overlap to define a space of a first type (131a, 131b, 131c) for receiving a flux guide (30), each space of the first type (131a, 131b, 131c) being a circumferential space between two adjacent active sections of two different coils.

A conductive coil 12 for a yokeless axial flux electrical machine stator 1 with distributed windings and flux guides 30, a stator 1 comprising a plurality of such coils, a yokeless axial flux electrical machine 100 comprising the stator 1, and a method 500 of manufacturing a stator 1 are provided. The conductive coil 12 comprises a first active section 121 a and a second active section 121 b, each active section 121 a, 121 b extending in a generally radial direction substantially perpendicular to an axis of rotation of the electrical machine and comprising a plurality of winding turn portions 131a, 131 b stacked parallel to the axis of rotation such that a cross-section perpendicular to the radial direction of each active section 121a, 121 b is elongate with a major dimension parallel to the axis of rotation. The second active section 121 b is pitched apart in a circumferential direction and axially offset from the first active section 121 a.

An axial field rotary energy device can include a housing having an axis with an axial direction. A stator assembly can include a plurality of stator panels that are discrete panels from each other. The stators panels can be mechanically and stationarily coupled to the housing. Each stator panel can include a printed circuit board (PCB) having coils that are electrically conductive, each stator panel consists of a single electrical phase. In addition, rotors can be rotatably mounted within the housing on opposite axial ends of the stator assembly. The rotors can be mechanically coupled together with a rotor spacer. Each rotor can include magnets. In addition, in one version, no rotor is disposed between axially adjacent ones of the stator panels.

In the present invention, junction capacitance is increased by stabilizing the junction capacitance of rotating electrodes such that a short circuit does not occur between the electrodes. Provided is a rotating electrode unit comprising a rotor electrode unit in which one or more rotor electrodes and one or more rotor spacers are alternately stacked, and a stator electrode unit in which one or more stator electrodes and one or more stator spacers are alternately stacked, wherein the rotating electrode unit is configured such that when the rotor electrodes are power transmitting electrodes, the stator electrodes are power receiving electrodes, when the rotor electrodes are power receiving electrodes, the stator electrodes are power transmitting electrodes, the rotor electrode unit and the stator electrode unit are combined in a nesting arrangement so as to be mutually rotatable, at least the outer peripheral section of the rotor electrodes is constituted by a member comprising a magnetic body, and the stator spacers have a magnet which attracts the outer peripheral section of the rotor electrodes via magnetic force.

An axial flux motor incorporates a rotor having a plurality of pockets receiving magnet assemblies. A retention device is engaged from an inactive surface of at least one magnet assembly to one or more structural elements surrounding an associate one of the plurality of pockets in the rotor.