An electric motor for a vapor compression system is disclosed. The electric motor is provided with a working fluid. The electric motor includes a housing forming cavity therein. The housing includes a rotor, a stator, and a shaft. The rotor is secured to the shaft and the stator surrounds at least a portion of the rotor. An airgap is formed between the rotor and the stator. An inlet of the housing receives the working fluid and is in fluid communication with the airgap. An outlet of the housing is in fluid communication with the airgap and receives the working fluid from the airgap. The electric motor further includes an impeller that induces flow of the working fluid between the inlet and the outlet.

An electric motor for a vapor compression system is disclosed. The electric motor is provided with a working fluid. The electric motor includes a housing forming cavity therein. The housing includes a rotor, a stator, and a shaft. The rotor is secured to the shaft and the stator surrounds at least a portion of the rotor. An airgap is formed between the rotor and the stator. An inlet of the housing receives the working fluid and is in fluid communication with the airgap. An outlet of the housing is in fluid communication with the airgap and receives the working fluid from the airgap. The electric motor further includes an impeller that induces flow of the working fluid between the inlet and the outlet.

A motor includes a rotor that is rotatable about a central axis and a stator that radially opposes the rotor with a gap interposed therebetween. The stator includes a stator core that includes an annular core back surrounding the central axis and a tooth extending to a radially inner side from the core back, and a coil that is wound around the tooth. The stator core includes at least one hole penetrating in an axial direction of the central axis, and a slit including a space connecting the hole and a radially outer side of the stator core. A heat pipe is held in the hole and extends in an axial direction along the hole, and an adhesive is between the hole and the heat pipe.

A motor includes a rotor that is rotatable about a central axis and a stator that radially opposes the rotor with a gap interposed therebetween. The stator includes a stator core that includes an annular core back surrounding the central axis and a tooth extending to a radially inner side from the core back, and a coil that is wound around the tooth. The stator core includes at least one hole penetrating in an axial direction of the central axis, and a slit including a space connecting the hole and a radially outer side of the stator core. A heat pipe is held in the hole and extends in an axial direction along the hole, and an adhesive is between the hole and the heat pipe.

A planar member for a stator stack comprises a stator yoke defining a central longitudinal axis, a first surface facing radially outward, and a second surface facing radially inward, a tooth extending radially inwards from the second surface, a first tooth tip extending circumferentially from a radially inward end of the tooth, a second tooth tip extending circumferentially from the radially inward end of the tooth, a first slot portion defined between the first tooth tip and the second surface, a second slot portion defined between the second tooth tip and the second surface, and a slot cooling fin extending radially from the stator yoke into the first slot portion.

A component mounting device head unit includes a head main body, a nozzle being provided on the head main body, a drive source, a cover, and a heat transfer member. The nozzle is configured to pick up a component. The drive source is configured to transfer moving power to at least one of the head main body and the nozzle. The cover covers the drive source. The heat transfer member connects the cover to the drive source or a frame of the drive source, and the heat transfer member is configured to allow heat generated by the drive source to escape to the cover.

A cooling system for a superconducting electric machine may comprise a fluid reservoir and a first fluid comprising a first mixture of hydrogen and helium configured to be stored in the fluid reservoir. A plurality of conduits may be fluidly coupled to the fluid reservoir and may form a closed loop between the fluid reservoir and the superconducting electric machine.

A cooling system for a superconducting electric machine may comprise a fluid reservoir and a first fluid comprising a first mixture of hydrogen and helium configured to be stored in the fluid reservoir. A plurality of conduits may be fluidly coupled to the fluid reservoir and may form a closed loop between the fluid reservoir and the superconducting electric machine.

An example system includes a housing configured to house a portion of an electric machine and a heat transfer material, the heat transfer material is configured to contact a conductor of the portion of the electric machine and to remove heat from the conductor and transfer heat to the housing. The system includes a coolant configured to remove heat from the housing. An inner surface of the housing comprises a plurality of structures configured to increase an inner surface area of the housing, wherein the plurality of structures are configured to contact the heat transfer material.

An example system includes a housing configured to house a portion of an electric machine and a heat transfer material, the heat transfer material is configured to contact a conductor of the portion of the electric machine and to remove heat from the conductor and transfer heat to the housing. The system includes a coolant configured to remove heat from the housing. An inner surface of the housing comprises a plurality of structures configured to increase an inner surface area of the housing, wherein the plurality of structures are configured to contact the heat transfer material.