A method of assembling a starter/generator in a gas-turbine engine, including coupling a rotor and a stator of the starter/generator such that the rotor is rotatable with respect to the stator to drive the rotor when the starter/generator is electrically powered and to produce electrical power when the rotor is rotated, securing the stator to a bearing support, coupling the starter/generator to a low pressure shaft of the engine by installing the bearing support over a bearing assembly secured to an end of the low pressure shaft, inserting the low pressure shaft through a high pressure shaft of the engine with the end of the low pressure shaft protruding therefrom and positioning the starter/generator in proximity of an end of the high pressure shaft, and drivingly engaging the rotor to the high pressure shaft.

A method of assembling a starter/generator in a gas-turbine engine, including coupling a rotor and a stator of the starter/generator such that the rotor is rotatable with respect to the stator to drive the rotor when the starter/generator is electrically powered and to produce electrical power when the rotor is rotated, securing the stator to a bearing support, coupling the starter/generator to a low pressure shaft of the engine by installing the bearing support over a bearing assembly secured to an end of the low pressure shaft, inserting the low pressure shaft through a high pressure shaft of the engine with the end of the low pressure shaft protruding therefrom and positioning the starter/generator in proximity of an end of the high pressure shaft, and drivingly engaging the rotor to the high pressure shaft.

A rotor including: a shaft; a structure comprising at least one end ring and rotor bars, wherein at least the end ring comprises a material subject to expansion or movement radially outward from the shaft upon a rotor balancing process that involves spinning of the structure; a core that at least partially encloses the rotor bars; and means for limiting the expansion or movement of the structure radially outward. A method including: providing a structure comprising at least one end ring and rotor bars, wherein at least the end ring comprises a material subject to expansion or movement radially outward from the shaft upon spinning of the structure; assembling a rotor from the structure and a core, the core at least partially enclosing the rotor bars; spinning the rotor in a rotor balancing process; and limiting the expansion or movement of the structure radially outward in the rotor balancing process.

An electric motor that enables to promote a further downsizing and performance enhancement, and a dental device that includes the electric motor. A brushless slotless electric motor 10 includes: a stator 3 that includes a stator core 301 and a plurality of coils 31 to 33 disposed inside of the stator core 301; a rotor 2 that includes a shaft 21, the rotor 2 being rotated around the shaft 21 with respect to the stator 3; and a medium pathway 40 through which a medium passes, the medium being supplied for actualizing a function of a dental handpiece 9A to which the electric motor 10 is applied. The plurality of coils 31 to 33 are adjacent to each other in a rotation direction of the rotor 2 so as not to lap mutually. The medium pathway 40 is disposed between the adjacent coils 31 to 33.

The present invention is an electrical machine comprising a stator and a rotor (10). The rotor is formed with a rotor body comprising a stack of laminations placed on a rotor shaft. The rotor includes at least one cavity with at least one arm for retaining at least one balancing weight.

The invention concerns a windmill including a rotatable transverse flux electrical machine (TFEM) comprising a stator portion; and a rotor portion rotatably located in respect with the stator portion, the rotor portion including an alternate sequence of magnets and concentrators radially disposed about a rotation axis thereof; the stator portion including at least one phase, the at least one phase including a plurality of cores cooperating with a coil disposed about the rotation axis, each core including a skewed pair of poles to progressively electromagnetically engage an electromagnetic field of respective cooperating concentrators. The invention is also concerned with a plurality of elements located in desired positions in the TFEM.

In one aspect of the invention, a motor assembly for an electric power steering assembly is provided. The motor assembly includes a motor housing, a stator, and a hollow rotor defining an inner cavity, the rotor configured for rotational movement within the motor housing. The motor assembly further includes a worm shaft having a first end and a second end, and a motor coupling positioned within the inner cavity and coupled to the rotor for rotational movement therewith. The worm shaft first end is coupled to the motor coupling for rotational movement therewith.

In one aspect of the invention, a motor assembly for an electric power steering assembly is provided. The motor assembly includes a motor housing, a stator, and a hollow rotor defining an inner cavity, the rotor configured for rotational movement within the motor housing. The motor assembly further includes a worm shaft having a first end and a second end, and a motor coupling positioned within the inner cavity and coupled to the rotor for rotational movement therewith. The worm shaft first end is coupled to the motor coupling for rotational movement therewith.

A generator assembly apparatus is provided for merging a first annular component and a second annular component of a generator. The generator assembly apparatus includes first and second component support frames, a moving device and an adjustment device. The first component support frame supports the first component securely mounted to the first component support frame. The second component support frame supports the second component securely mounted to the second component support frame. The moving device moves one component support frame relative to the other component support frame to merge the components by inserting one component at least partially into an interior region of the other component. The adjustment device adjusts a position of a support frame such that a pre-defined separation between the first component and the second component is maintained during merging.

A generator assembly apparatus is provided for merging a first annular component and a second annular component of a generator. The generator assembly apparatus includes first and second component support frames, a moving device and an adjustment device. The first component support frame supports the first component securely mounted to the first component support frame. The second component support frame supports the second component securely mounted to the second component support frame. The moving device moves one component support frame relative to the other component support frame to merge the components by inserting one component at least partially into an interior region of the other component. The adjustment device adjusts a position of a support frame such that a pre-defined separation between the first component and the second component is maintained during merging.