A motor and a torque transducer box, an end cover front panel is installed at a front portion of the motor, the torque transducer box is installed at a front portion of the end cover front panel, a transmission pole is installed in the an extrusion rotating wheel, thermal dissipation and explosion proof boxes are installed on a surface of the motor, a sealing and thermal insulation module is installed at a front portion of the transmission pole, two sets of cable wrapping posts are symmetrically provided at the surface of the motor, and two sets of correction boxes are symmetrically provided at a surface of a rotor assembly.

A motor and a torque transducer box, an end cover front panel is installed at a front portion of the motor, the torque transducer box is installed at a front portion of the end cover front panel, a transmission pole is installed in the an extrusion rotating wheel, thermal dissipation and explosion proof boxes are installed on a surface of the motor, a sealing and thermal insulation module is installed at a front portion of the transmission pole, two sets of cable wrapping posts are symmetrically provided at the surface of the motor, and two sets of correction boxes are symmetrically provided at a surface of a rotor assembly.

An electromechanical tool including a casing, a shaft driving a tip in rotation and a rotary transformer. The rotating shaft integrates an electronic circuit configured to measure a physical parameter of the shaft, and the rotary transformer includes a stator fixedly attached to the casing and a rotor affixed to the rotating shaft. The stator integrates a first coil and a first support of this first coil, and the rotor integrates a second coil and a second support of this second coil. The supports are made out of plasto-ferrite material.

An electromechanical tool including a casing, a shaft driving a tip in rotation and a rotary transformer. The rotating shaft integrates an electronic circuit configured to measure a physical parameter of the shaft, and the rotary transformer includes a stator fixedly attached to the casing and a rotor affixed to the rotating shaft. The stator integrates a first coil and a first support of this first coil, and the rotor integrates a second coil and a second support of this second coil. The supports are made out of plasto-ferrite material.

An object is to improve estimation accuracy of the internal distribution state of a rotating electric machine. The rotating electric machine includes a stator; a rotor rotatably provided on a radially inner side of the stator; a shaft provided as a rotary shaft of the rotor; a bracket supporting the shaft rotatably relative to the stator via a bearing; and a sensor provided to the shaft between the rotor and the bearing.

An embodiment may provide a motor comprising: a stator including stator teeth; and a rotor including a magnet, wherein the stator teeth include a first stator tooth and a second stator tooth disposed within the first stator tooth, wherein the first stator tooth includes a plurality of first teeth, the second stator tooth includes a plurality of second teeth, wherein the first teeth radially overlap the second teeth at the center of the stator in a radial direction, the motor further comprising: a sensor and a collector disposed between the first stator tooth and the second stator tooth in the radial direction, and the motor further comprising: a circuit board on which the sensor is disposed; and a housing accommodating the circuit board, wherein the collector includes a first collector and a second collector disposed within the first collector, the sensor is disposed, in the radial direction, between the first collector and the second collector, and the housing includes a first protrusion, wherein the first protrusion comprises: a body disposed, in the radial direction, between the first collector and the second collector; a head disposed at an upper end of the body; and a first groove, wherein the head includes a first surface and a second surface disposed so as to face each other, wherein the first surface is in contact with an upper end of the first collector and an upper end of the second collector, the first groove is disposed so as to be concave on the second surface, and a portion of the first groove is disposed to overlap the first and second collectors in the radial direction.

An embodiment may provide a motor comprising: a stator including stator teeth; and a rotor including a magnet, wherein the stator teeth include a first stator tooth and a second stator tooth disposed within the first stator tooth, wherein the first stator tooth includes a plurality of first teeth, the second stator tooth includes a plurality of second teeth, wherein the first teeth radially overlap the second teeth at the center of the stator in a radial direction, the motor further comprising: a sensor and a collector disposed between the first stator tooth and the second stator tooth in the radial direction, and the motor further comprising: a circuit board on which the sensor is disposed; and a housing accommodating the circuit board, wherein the collector includes a first collector and a second collector disposed within the first collector, the sensor is disposed, in the radial direction, between the first collector and the second collector, and the housing includes a first protrusion, wherein the first protrusion comprises: a body disposed, in the radial direction, between the first collector and the second collector; a head disposed at an upper end of the body; and a first groove, wherein the head includes a first surface and a second surface disposed so as to face each other, wherein the first surface is in contact with an upper end of the first collector and an upper end of the second collector, the first groove is disposed so as to be concave on the second surface, and a portion of the first groove is disposed to overlap the first and second collectors in the radial direction.

An example electronic device includes a housing including a first housing member and a second housing member pivotably coupled to one another via a hinge. In addition, the electronic device includes a motor positioned in the second housing member comprising an output shaft. Further, the electronic device includes an actuatable member positioned in the first housing member, wherein the motor is to actuate the actuatable member via a plurality of gears coupled across the hinge. Still further, the electronic device includes a controller coupled to the motor. The controller is to actuate the motor to reduce a force applied to the output shaft in response to detecting a torque on the hinge.

An example electronic device includes a housing including a first housing member and a second housing member pivotably coupled to one another via a hinge. In addition, the electronic device includes a motor positioned in the second housing member comprising an output shaft. Further, the electronic device includes an actuatable member positioned in the first housing member, wherein the motor is to actuate the actuatable member via a plurality of gears coupled across the hinge. Still further, the electronic device includes a controller coupled to the motor. The controller is to actuate the motor to reduce a force applied to the output shaft in response to detecting a torque on the hinge.

A method of monitoring a power drive unit installed on an aircraft is provided. The method includes causing, by a controller, sensors to measure an angular position at corresponding locations along at least one wing of the aircraft. The controller, as part of the method, receives the angular position from the one or more sensors and analyzes the angular position to generate feedback information to implement the monitoring of the power drive unit.