Abstract: According to one aspect of the present disclosure, a rotor includes a plurality of permanent magnets and a support supporting the permanent magnet. The support includes at least one of an outside support fixed to a radial outside of the outer cores to circumferentially support an end face of the permanent magnet from both sides and an inside support fixed to a radial inside of the outer cores to circumferentially support the end face of the permanent magnet from both sides. Each of the outer cores includes an opposite face parallelly opposed to the end face of the permanent magnet in the circumferential direction. The outside support and the inside support each includes a support face circumferentially supporting the end face. The support face is disposed on a side closer to a center line of the permanent magnet than the opposite face in the circumferential direction.

Abstract: According to one aspect of the present disclosure, a rotor includes a shaft, a rotor core including an inner core and a plurality of outer cores, a mold resin unit covering, the mold resin unit, and a plurality of permanent magnets. The mold resin unit includes a gate mark in a region between the outer cores adjacent to each other in the circumferential direction, and the gate mark is provided in all regions between the adjacent outer cores or in a region between the outer cores, the region being adjacent to a region between the even-numbered adjacent outer cores in which the gate mark is not disposed in all the regions between the adjacent outer cores.

Abstract: There is provided a method for manufacturing a nozzle diaphragm which can be assembled with high accuracy. The method for manufacturing a nozzle diaphragm includes a preparation step S1 of preparing an inner ring, a plurality of nozzles, an outer shroud ring, and an outer ring, a ring installation step S2 of installing the outer shroud ring, a nozzle installation step S3 of installing the nozzles while an outer peripheral end portion of a nozzle main body is inserted into a through-hole formed in the outer shroud ring, an inner ring installation step S4 of installing the inner ring, an outer ring installation step S5 of installing the outer ring outside the outer shroud ring, and a welding step S6 of welding the outer ring and the outer shroud ring to each other, and welding the inner ring and the inner shroud to each other in a circumferential direction.

Abstract: An inline axial flow fan includes a first fan including a first impeller, a first motor portion, and a first case, and a second fan including a second impeller, a second motor portion, and a second case, the first fan and the second fan being positioned in sequence from one axial side to another axial side. The first case and the second case are accommodated in a housing, and only one of the first case and the second case includes multiple slits that connect the inside and the outside of the first case and the second case in the radial direction.

Abstract: An inline axial flow fan includes a first fan including a first impeller, a first motor portion, and a first case, and a second fan including a second impeller, a second motor portion, and a second case, the first fan and the second fan being positioned in sequence from one axial side to another axial side. The first case includes multiple first slits, and the second case includes multiple second slits. The inline axial flow fan includes a flange extending radially outward from an outer peripheral surface of the first case or the second case located between the first slit and the second slit in the axial direction.

Abstract: A motor includes a stationary structure, and a rotor rotatable about a central axis with respect to the stationary structure. The stationary structure includes a stator including a coil, a bracket that supports the stator, and a circuit board disposed between the stator and the bracket. The bracket includes a board support that holds the circuit board between the bracket and the stator in an axial direction. The board support includes a wiring through hole that penetrates the board support in the axial direction and through which a wire extending from the circuit board passes, a lid that partially covers the wiring through hole, and a guide bridge that is located inside the wiring through hole when viewed in the axial direction and holds the wire between the lid and the guide bridge.

Abstract: A motor includes a stationary portion, a rotating portion that includes a shaft rotating about a vertically extending central axis, and a bearing portion that rotatably supports the shaft with respect to the stationary portion. The stationary portion includes a cylindrical bearing housing portion that holds the bearing portion, a stator that is radially outward of the bearing housing portion, a circuit board that is below the stator, and an annular spacer that is between the stator and the bearing housing portion. The stator includes a stator core that includes an annular core back and multiple teeth that extend radially outward from the core back and are arranged in a circumferential direction, an insulating film that covers a surface of the teeth, extends radially inward from a lower surface of the teeth, and covers a lower outer edge portion of the core back, and a coil provided on the teeth.

Abstract: A motor includes a stationary portion, a rotating portion that includes a shaft rotating about a vertically extending central axis, and a bearing portion that rotatably supports the shaft with respect to the stationary portion. The stationary portion includes a cylindrical bearing housing portion that holds the bearing portion, a stator that is radially outward of the bearing housing portion and includes a stator core, a circuit board that is below the stator core, and an annular spacer that is between the stator core and the bearing housing portion. The spacer includes multiple side wall portions that contact a radially inner surface of the stator core and a flange portion that protrudes radially outward more than the side wall portion and contacts a lower surface of the stator core.

Abstract: A rotatable about a center axis includes a rotor core including an annular inner core portion extending along a circumferential direction, and outer core portions spaced apart along the circumferential direction on an outer side in a radial direction of the inner core portion, magnets each positioned between the outer core portions adjacent to each other in the circumferential direction, and a support that supports the rotor core and the magnet. The support includes an inner support portion that supports the magnet on an inner side in a radial direction of the magnet, an outer support portion that supports the magnet on an outer side in a radial direction of the magnet, and a bridge portion that extends in the radial direction to connect the inner support portion and the outer support portion. The outer core portion includes a penetrating portion that penetrates the outer core portion in the radial direction. At least a portion of the bridge portion is positioned inside the penetrating portion.

Abstract: A drive device includes a hollow hub rotatable about hub shafts extending parallel to a center axis, a motor housed in the hub and fixed to the hub shafts, and a speed reducer connected to the motor and the hub. The motor includes a rotor including a motor shaft extending parallel to the hub shafts, a stator disposed outside the rotor in a radial direction, and a motor housing holding the stator therein. The drive device includes thermal grease thermally connecting the hub and the motor housing to each other.

Abstract: A planetary gear mechanism includes a sun gear, planetary gears, an annular internal gear, a carrier that is fixed to a bracket and includes a second lid, and a support shaft. An output unit is supported to be rotatable by a first bearing attached to the support shaft and a second bearing attached to the bracket, and fixed to the internal gear. The bracket includes a protrusion protruding from a first lid to one side in the axial direction. A radially inside surface of the protrusion includes a first curved surface extending in a circumferential direction as viewed along the axial direction. The carrier includes a second curved surface located radially inside the first curved surface. The second curved surface extends in the circumferential direction as viewed along the axial direction, and contacts with the first curved surface.

Abstract: A transmission includes a first rotating portion, an eccentric body, a bearing, an external gear, an internal gear, carrier pins, and a second rotating portion. The first rotating portion rotates about a central axis. The eccentric body rotates therewith and a distance from the central axis to an outer surface thereof varies circumferentially. The bearing is provided on the eccentric body. The external gear includes through holes and is provided on the bearing. The internal gear is cylindrical, surrounds the central axis, and is disposed radially outside the external gear. The carrier pins are columnar and inserted into the through holes. The second rotating portion, to which upper portions of the carrier pins are fixed, rotates about the central axis. The external and internal gears have different numbers of teeth. The tooth of the external gear farthest from the central axis meshes with the internal gear. The diameters of the carrier pins decrease upward.

Abstract: A motor includes a circuit board, a rotation sensor attached to the circuit board, a connector protruding from the circuit board to a second side in an axial direction, and a cable electrically connected to the rotation sensor. A housing includes a protruding cylinder and a bearing holder located radially inside of the protruding cylinder. The circuit board is located on a first side in the axial direction of the protruding cylinder. The protruding cylinder includes an extraction hole radially penetrating a wall of the protruding cylinder. The connector is located radially inside of a stator. An end on the second side in the axial direction of the connector is located in the protruding cylinder. The cable is extracted from the end on the second side in the axial direction of the connector to a radial outside of the protruding cylinder through the extraction hole.

Abstract: A drive device that rotates a wheel includes a motor including a motor shaft disposed along a center axis, a speed reduction mechanism connected to one side in an axial direction of the motor shaft, and an output unit to which rotation of the motor shaft is transmitted through the speed reduction mechanism. The motor includes a rotor including the motor shaft, a stator opposed to the rotor in a radial direction with a gap interposed therebetween, and a housing accommodating the rotor and the stator. The housing includes a first fixing unit fixed to a chassis of a traveling body on which the drive device is mounted. The stator includes a stator core and coils mounted on the stator core. The stator core contacts directly with the housing.

Abstract: A planetary gear mechanism includes a sun gear, planetary gears, an annular internal gear, a carrier that is fixed to a bracket and includes a second lid, and a support shaft. An output unit is supported to be rotatable by a first bearing attached to the support shaft and a second bearing attached to the bracket, and fixed to the internal gear. The bracket includes a protrusion protruding from a first lid to one side in the axial direction. A radially inside surface of the protrusion includes a first curved surface extending in a circumferential direction as viewed along the axial direction. The carrier includes a second curved surface located radially inside the first curved surface. The second curved surface extends in the circumferential direction as viewed along the axial direction, and contacts with the first curved surface.

Abstract: An object is to avoid the situation in which the power cannot be turned off. A control system is provided in which the first and second control units are connected. At least one of the first and second control units include: a stop control section for, if a condition for ending a predetermined operation mode is satisfied in that operation mode, performing stop control for having the control system in a low-power-consumption state while communicating with the other control unit; and a mode control section for having a mode undefined state in which the operation mode is instable at restoration from a reset state and for allowing, if a predetermined transition condition for allowing transition into the operation mode is satisfied in the mode undefined state, transition into the operation mode whose transition condition has been satisfied.

Abstract: A dryer includes a centrifugal impeller, a motor configured to rotate the impeller about a rotation axis which crosses a plane including a blowing axis, and a heater. The impeller is accommodated in a portion including a pair of side surfaces, each of which crosses the rotation axis, and an air inlet defined in at least one of the side surfaces. The impeller includes blades that are annular with the rotation axis as a center. The heater is supported on plate-shaped portions extending in a plurality of directions from the blowing axis in a cross-section perpendicular or substantially perpendicular to the blowing axis. A rear edge of each of the plate-shaped portions with respect to the blowing axis extends in a direction which crosses radially outer edges of the blades with respect to the rotation axis when viewed along the blowing axis.

Abstract: A first video signal having a first frame rate optionally settable is generated by an image pickup device, and the first video signal is memorized in a memory and outputted from the memory. A write control device controls the write of the first video signal with respect to the memory, and a read control device controls the read of the video signal with respect to the memory. The write control device writes respective first frame data constituting the first video signal in the memory in each cycle determined by the first frame rate of the first video signal. The read control device reads the first frame data as a second video signal. The second video signal is formed from sequentially arranging the first frame data in a partially duplicating manner in a standard video signal having a standard frame rate based on a determined arrangement rule.

Abstract: An object is to avoid the situation in which the power cannot be turned off. A control system is provided in which the first and second control units are connected. At least one of the first and second control units include: a stop control section for, if a condition for ending a predetermined operation mode is satisfied in that operation mode, performing stop control for having the control system in a low-power-consumption state while communicating with the other control unit; and a mode control section for having a mode undefined state in which the operation mode is instable at restoration from a reset state and for allowing, if a predetermined transition condition for allowing transition into the operation mode is satisfied in the mode undefined state, transition into the operation mode whose transition condition has been satisfied.

Abstract: A first video signal having a first frame rate optionally settable is generated by an image pickup device, and the first video signal is memorized in a memory and outputted from the memory. A write control device controls the write of the first video signal with respect to the memory, and a read control device controls the read of the video signal with respect to the memory. The write control device writes respective first frame data constituting the first video signal in the memory in each cycle determined by the first frame rate of the first video signal. The read control device reads the first frame data as a second video signal. The second video signal is formed from sequentially arranging the first frame data in a partially duplicating manner in a standard video signal having a standard frame rate based on a determined arrangement rule.