A press-fit mounting peg (2) is described for retaining a component such as a stepped-motor on a circuit board (21). The mounting peg (2) is securable in a mounted position by a first axial displacement of a locking pin (17) along a pin channel (16) of the press-fit mounting peg (2) in a first axial direction along a longitudinal axis of the press-fit mounting peg (2) from a first axial position to a second axial position. The pin channel (16) comprises at least one pin displacement stop (13, 20) for stopping a second axial displacement of the locking pin (17) out of the second axial position.

An assembly for generating electricity includes a circular track configured to rotate about a first axis of rotation, the circular track comprising a first magnet having a face that is at an angle with respect to the first axis of rotation, a second magnet positioned at a center of the circular track, wherein a face of the second magnet is an opposite polarity to the face of the first magnet such that the second magnet repels the first magnet to rotate the circular track, and a device for converting rotational motion from the circular track into electricity.

It is provided an actuated machine having a main frame 100, a machine shaft 200 mounted on the main frame 100 by means of a bearing module 300, a gearless torque motor 400 coupled to the machine shaft 200 for driving a rotation of the machine shaft 200, a torque arm 500 coupled to the gearless torque motor 400, and a catching structure. The gearless torque motor 400 is coupled to the machine shaft 200 such that the gearless torque motor 400 is capable of following a translational movement of the machine shaft 200. The torque arm 500 is coupled to the gearless torque motor 400 for inhibiting a rotational motion of the gearless torque motor 400, relative to the main frame 100, about a central axis of the gearless torque motor. The catching structure is arranged underneath the gearless torque motor 400 for catching and holding the gearless torque motor 400 in case of a failure causing the gearless torque motor's weight to be no longer carried by the machine shaft 200.

It is provided an actuated machine having a main frame 100, a machine shaft 200 mounted on the main frame 100 by means of a bearing module 300, a gearless torque motor 400 coupled to the machine shaft 200 for driving a rotation of the machine shaft 200, a torque arm 500 coupled to the gearless torque motor 400, and a catching structure. The gearless torque motor 400 is coupled to the machine shaft 200 such that the gearless torque motor 400 is capable of following a translational movement of the machine shaft 200. The torque arm 500 is coupled to the gearless torque motor 400 for inhibiting a rotational motion of the gearless torque motor 400, relative to the main frame 100, about a central axis of the gearless torque motor. The catching structure is arranged underneath the gearless torque motor 400 for catching and holding the gearless torque motor 400 in case of a failure causing the gearless torque motor's weight to be no longer carried by the machine shaft 200.

An object of the present invention is to improve the fixing force of a stator core at low cost. The rotating electric machine includes a stator 300 in which a plurality of stator cores 400 are annularly arranged, a rotor to be arranged on the inner circumferential side of the stator 300, and a housing 500 having a cylindrical shape for fixing each of the plurality of stator cores 400. The stator core 400 has outer circumferential surfaces 410 and 420 arranged to face the inner circumferential surface 510 of the housing 500, and the outer circumferential surfaces 410 and 420 of the stator core 400 are slanted with respect to the inner circumferential surface 510 of the housing 500.

According to one aspect of the present disclosure, an electric motor for a laundry appliance includes a first stator having a central axis. A first rotor is in electromagnetic communication with the first stator and is rotationally operable about the central axis. A second stator is aligned with the central axis. A second rotor is in electromagnetic communication with the second stator and is rotationally operable about the central axis. The first and second stators are positioned within a common motor cavity of an outer housing. A controller regulates a first electrical current to the first stator and a second electrical current to the second stator. The controller includes a torque discrimination module for monitoring an output torque of at least the first rotor.

A stator core for an electric motor may include a main body part formed by a plurality of stacked electromagnetic steel sheets, the main body part being provided with at least a first through hole extending axially with a first pin located in the first through hole. A first end cover is located at a first end of the main body part and connected to a first pin end of the first pin. A second end cover is located at a second end of the main body part and connected to a second pin end of the first pin. The connections of the first end cover and the second end cover to the first pin generate tensile stresses in the main body part to reduce core losses.

A fluid transfer pump assembly that includes a motor enclosure assembly that forms a motor cavity sized to receive a motor. The motor enclosure includes a flame path that extends from an interior joint to an exterior joint. The interior joint faces the motor cavity and the exterior joint faces exterior of the motor enclosure assembly. A heat sink is located in the motor cavity of the motor enclosure assembly. A portion of the heat sink abuts the interior joint.

The present disclosure describes a drive circuit for an actuator of an actuator device. The drive circuit includes an interference suppression branch for reducing interferences. The interference suppression branch includes two conductor branches extending along a longitudinal axis and each comprising at least one conductor body. The two conductor branches extend through at least two imaginary conductor alignment sections of the interference suppression branch that are lined up in a row in an axial direction of the longitudinal axis. The two conductor branches have a first portion arranged inside a first conductor alignment section that run obliquely towards one another.

The present disclosure describes a drive circuit for an actuator of an actuator device. The drive circuit includes an interference suppression branch for reducing interferences. The interference suppression branch includes two conductor branches extending along a longitudinal axis and each comprising at least one conductor body. The two conductor branches extend through at least two imaginary conductor alignment sections of the interference suppression branch that are lined up in a row in an axial direction of the longitudinal axis. The two conductor branches have a first portion arranged inside a first conductor alignment section that run obliquely towards one another.