A rotor (10) for an axial-flux electrical machine (12) is provided. The rotor (10) comprises an annular disc-shaped central frame (20) formed of a ferromagnetic material and having first and second opposing surfaces (26, 28). Each of the first and second opposing surface (26, 28) has shaped protrusions (40) extending therefrom. The rotor (10) further comprises a first and a second outer frame (22, 24) formed of a non-ferromagnetic, electrically conducting material. Each outer frame (22, 24) has an inner periphery portion (32) and an outer periphery portion (34) and a plurality of bars (36) galvanically connecting the inner and outer periphery portions (32, 34). Gap portions (38) are defined between adjacent bars (36) and the inner and outer periphery portions (32, 34). The gap portions (38) are shaped complementary to the shaped protrusions (40) of the central frame (20).

A rotor (10) for an axial-flux electrical machine (12) is provided. The rotor (10) comprises an annular disc-shaped central frame (20) formed of a ferromagnetic material and having first and second opposing surfaces (26, 28). Each of the first and second opposing surface (26, 28) has shaped protrusions (40) extending therefrom. The rotor (10) further comprises a first and a second outer frame (22, 24) formed of a non-ferromagnetic, electrically conducting material. Each outer frame (22, 24) has an inner periphery portion (32) and an outer periphery portion (34) and a plurality of bars (36) galvanically connecting the inner and outer periphery portions (32, 34). Gap portions (38) are defined between adjacent bars (36) and the inner and outer periphery portions (32, 34). The gap portions (38) are shaped complementary to the shaped protrusions (40) of the central frame (20).

The invention relates to a method for producing a rotor (14) for a rotating electrical machine (10) in which at least one rotor winding (20) is introduced into a rotor laminated core (16) of the rotor (14) in an electrically insulated manner, wherein the rotor winding (20) is designed as an electrically insulated cage and/or as a damper loop at least partially by means of an additive production method in the rotor laminated core (16), wherein an electrical insulation layer (46) is formed at the same time as the rotor winding (20) is formed between an electrical conductor (22) of the rotor winding (20) and the rotor laminated core (16) and/or between adjacent conductors (22) of the rotor winding (20).

The invention relates to a method for producing a rotor (14) for a rotating electrical machine (10) in which at least one rotor winding (20) is introduced into a rotor laminated core (16) of the rotor (14) in an electrically insulated manner, wherein the rotor winding (20) is designed as an electrically insulated cage and/or as a damper loop at least partially by means of an additive production method in the rotor laminated core (16), wherein an electrical insulation layer (46) is formed at the same time as the rotor winding (20) is formed between an electrical conductor (22) of the rotor winding (20) and the rotor laminated core (16) and/or between adjacent conductors (22) of the rotor winding (20).

An induction motor is disclosed. The induction motor comprises a motor casing, fabricated in an irregular octagonal shape with a central open area. The motor casing is configured to house a cooling system within an outer wall and an inner wall of the motor casing. The cooling system comprises a plurality of interconnected cooling channels and a plurality of air ducts. The induction motor comprises a stator assembly housed within the central open area of the motor casing, a rotor assembly fitted inside the stator assembly and a shaft configured to be fitted to the rotor assembly. The induction motor also comprises a fan positioned on the first axial end of the induction motor. The fan is configured to assist inflow of air into the plurality of air ducts.

The invention relates to the field of electromechanics and can be used in asynchronous electric machines to improve their characteristics. The technical problem of the invention is the need to improve the traction and overload capacity and increase the starting torque of asynchronous electric machines. The rotor of an asynchronous electric machine contains a package of magnetic circuit plates with a straight, bevel-free, short-circuited rotor winding of the squirrel cage type, which contains short-circuited washers permanently mounted on both ends of it; in this case, the short-circuited winding of the rotor is made in two rows, in the form of internal and external rows, between which the magnetic core of the rotor is placed. The inner row of the short-circuited rotor winding is made in the form of a row of rods, or from a single solid sleeve of conductive non-magnetic material. The number of rods in one row of its squirrel cage-type short-circuited winding differs from the number of slots of the stator in a smaller direction by the number of pairs of poles of the electric machine. 1 n.s.p.f, 2 z.p.f, 5 FIG.

The invention relates to the field of electromechanics and can be used in asynchronous electric machines to improve their characteristics. The technical problem of the invention is the need to improve the traction and overload capacity and increase the starting torque of asynchronous electric machines. The rotor of an asynchronous electric machine contains a package of magnetic circuit plates with a straight, bevel-free, short-circuited rotor winding of the squirrel cage type, which contains short-circuited washers permanently mounted on both ends of it; in this case, the short-circuited winding of the rotor is made in two rows, in the form of internal and external rows, between which the magnetic core of the rotor is placed. The inner row of the short-circuited rotor winding is made in the form of a row of rods, or from a single solid sleeve of conductive non-magnetic material. The number of rods in one row of its squirrel cage-type short-circuited winding differs from the number of slots of the stator in a smaller direction by the number of pairs of poles of the electric machine. 1 n.s.p.f, 2 z.p.f, 5 FIG.

A rotor for an electric machine, including a laminated core with slots in which bottom bars and top bars are arranged to in an axial direction beyond the laminated core to form a winding overhang. A bottom bar of one slot is respectively connected to a top bar of another slot in the winding overhang and, in a plan view, bottom bars and top bars cross axially outside the laminated core at crossing points and gaps remain between the crossing points. A support device has a retaining body arranged radially inside the winding overhang and at least one clip having two legs and a crosspiece. The is connected to both the retaining body and to a top bar to radially support the top bar by the retaining body. To ensure a robust stabilization of the winding overhang the legs protrude through two gaps adjacent to different top bars.

A rotating electrical machine includes a rotor and a magnet unit. The rotating electrical machine also includes a cylindrical stator and a housing. The stator is equipped with a stator winding made up of a plurality of phase windings. The stator is arranged coaxially with the rotor and faces the rotor. The housing has the rotor and the stator disposed therein. The rotor includes a cylindrical magnet retainer to which the magnet unit is secured and an intermediate portion which connects between a rotating shaft of the rotor and the magnet retainer and extends in a radial direction of the rotating shaft. A first region located radially inside an inner peripheral surface of a magnetic circuit component made up of the stator and the rotor is greater in volume than a second region between the inner peripheral surface of the magnetic circuit component and the housing in the radial direction.

A canned rotodynamic flow machine (1) configured for operating with a working fluid such as molten salt of a molten salt nuclear reactor. The stator windings are formed by one or more electrically conductive solid bars (12).