Abstract: An automotive accessory drive system for a motor vehicle connects to an internal combustion engine crankshaft during at least one mode of operation. The system includes an accessory drive pulley, a starter motor/generator, and an endless loop power transmission member connecting at least the starter motor/generator and the accessory drive pulley. A planetary gear set includes a sun gear, a ring gear integrally associated with the accessory drive pulley, and a planetary carrier connected to the engine crankshaft. First and second one way clutches connect the engine crankshaft to the ring gear, and the sun gear to a grounding member, respectively, to define a normal drive mode and an engine start mode, respectively. An electromagnetic disconnect includes a normally closed friction clutch connecting the grounding member to ground to define a third mode of operation corresponding to a free wheel function with the grounding member disengaged from connection to ground.

Abstract: A transmission for a hybrid electric vehicle, may include an input element where rotation power may be inputted and an output element from which the rotation power may be outputted, a first motor generator and a second motor generator, a first planetary gear set that may be a multiple planetary gear set having at least four or more rotary elements with which the input element, the output element, and the first motor generator may be connected, a second planetary gear set with which the output element and the second motor generator may be connected, and a first clutch and a second clutch.

Abstract: A multispeed spur gear transmission is provided with a planetary gear stage. The multispeed spur gear transmission includes, but is not limited to a spur gear pairing for each gear, a clutch bell with clutch device for coupling a transmission input to a motor output shaft, at least one transmission drive shaft and a transmission output shaft for receiving the spur gear pairings of the gears and a transmission output with an output gear on the transmission output shaft. Between the clutch bell and the transmission input the planetary gear stage is arranged, whose planetary gear cage includes, but is not limited to a spur gear rim that meshes with at least one first spur gear of a rotor shaft of an electrodynamic device.

Abstract: Provided is a transmission for a hybrid electric vehicle that makes it possible to more effectively transmit the torque from an engine to an output shaft, provide sufficient power performance in WOT start, achieve excellent controllability without generating transmission shock by allowing modes to be naturally and smoothly switched, and improve acceleration response.

Abstract: A rotary drive device includes a motor including a rotary shaft, a planetary gear mechanism, and a rotation position detector. The planetary gear mechanism decelerates a rotation output of the motor at a reference reduction ratio and includes an outer gear, multistage gears, and an output shaft. The outer gear is fixed to a housing of the motor. The multistage gears are provided inside the outer gear. The output shaft transmits the decelerated rotation output of the motor to an outside of the rotary drive device. The rotation position detector detects a rotation position of the output shaft to control rotation of the motor. The motor, the planetary gear mechanism, and the rotation position detector are combined into a single integrated unit and aligned in an axial direction of the rotary shaft of the motor.

Abstract: An electronic drive unit includes a case housing that extends along a primary axis. A sleeve shaft and an electric motor are disposed in the hollow interior of the case housing. The electric motor is operatively connected to the sleeve shaft to rotate the sleeve shaft about the primary axis. At least one gear set is disposed in operative engagement with the sleeve shaft and is configured for rotation about the primary axis. A pair of output shafts each extends along the primary axis within the case housing. The output shafts are rotatably connected to the gear set and are configured for rotation about the primary axis. The gear set is configured to translate rotation of the sleeve shaft into rotation of the output shafts about the primary axis at a rotational velocity that is less than the rotational velocity of the sleeve shaft.

Abstract: The present invention relates to a transmission unit for a vehicle driven by muscle force, comprising an input shaft which can be connected to cranks on opposite sides for driving the vehicle, comprising a first partial transmission. The first partial transmission comprises a countershaft, wherein a plurality of driving gear wheels is mounted on the input shaft, and wherein a corresponding plurality of driven gear wheels of the first partial transmission is mounted on the partial transmission shaft. The driven gear wheels of the first partial transmission are designed as idler gears that can be connected to the countershaft by means of shifting means in a rotationally rigid manner. The countershaft forms an input shaft of a second partial transmission. A plurality of second drive wheels are mounted on the output shaft, wherein the second partial transmission comprises an output shaft, on which a corresponding plurality of second driven gear wheels are mounted.

Abstract: A control apparatus for a vehicular drive system arranged to electrically transmit a portion of an output force of an engine through an electric path. The control apparatus is configured to reduce loads of components associated with the electric path and to restrict a temperature rise of the components associated with the electric path, making it possible to reduce the required size of a cooling system. This is accomplished by placing a differential portion in a non-differential state or placing a switching clutch or switching brake in a partially engaged state when electrical energy through the electric path has increased to a thermal limit. As a result, the amount of generated electric energy is reduced, making it possible to restrict the temperature rise of the components associated with the electric path. Accordingly, the cooling system size can be reduced for these components.

Abstract: Provided is a strain wave gearing having a high stiffness and no limitation imposed on rotation, and a robotic arm including the strain wave gearing. A strain wave gearing includes an electric motor and a strain wave gearing reducer. The strain wave gearing reducer includes: an outer ring member including a first internal gear; a pair of second internal gears each having internal teeth formed along an inner periphery thereof, and the pair of second internal gears differing from the first internal gear in number of teeth; a flexible gear; and a cam member, which distorts the flexible gear in a radial direction to cause the flexible gear to engage with the first internal gear and the pair of second internal gears. The pair of second internal gears is fixed to a pair of fixing plates coupled to each other by a shaft penetrating the cam member.

Abstract: This reduction gear of an electric actuator (1) for driving a home screen, the reduction gear comprises a reduction stage having a sun gear (42) meshing with at least one planet gear (46, 46?) rotating about a respective shaft (47) and positioned in a drum (45), the planet gear meshing with a stationary ring (48) to drive the drum (45) in rotation about an axis of rotation (X4). The reduction gear further comprises first guide means (43) serving both to guide the sun gear (42) in rotation and to guide the drum (45) in rotation about the axis of rotation (X4).

Abstract: A hybrid module for the hybrid drive train of a motor vehicle is proposed, comprising an electric motor, a planetary gear assembly and a clutch (6) which connects the drive shaft of the internal combustion engine to the planet carrier (5) of the planetary gear assembly in a releasable manner, wherein the mounting for the rotor (1) and stator (2) is provided by the electric motor by way of the cover (3) of the electric motor, whereby the hub of the rotor (1) serves as the ring gear of the planetary gear assembly of the hybrid module and features a ring gear gearing and whereby the subassembly, comprised of the cover (3), the rotor (1) and the stator (2) can be preassembled.

Abstract: A gear bearing drive provides a compact mechanism that operates as an actuator providing torque and as a joint providing support. The drive includes a gear arrangement integrating an external rotor DC motor within a sun gear. Locking surfaces maintain the components of the drive in alignment and provide support for axial loads and moments. The gear bearing drive has a variety of applications, including as a joint in robotic arms and prosthetic limbs.

Abstract: A chassis (1) for a motor vehicle has an electrical axle (2) with two electrical machines (4) for respectively driving two wheels (6). The chassis (1) also has a step-down gear mechanism (10, 11) arranged between the respective electrical machine and the associated wheel. Each step-down gear mechanism is connected to the respective wheel by a cardan shaft. The respective rotation axes (5, 5) of the two electrical machines are arranged parallel and next to one another. The chassis enables each wheel to be mounted in a non-rigid manner and permits the overall length of the electrical machines to be varied on account of the arrangement of the rotation axes of the electrical machines.

Abstract: A drive for a vehicle includes a first electric motor, a second electric motor, and a planetary gear train to couple the first and second electric motors. The planetary gear train has a sun wheel mounted on a drive shaft, and a ring gear mounted on a drive shaft. The drive shaft of the sun wheel is hereby coupled with the first electric motor, and the drive shaft of the ring gear is coupled with the second electric motor. An axle drive unit is operably connected with wheels of the vehicle and coupled with planet wheels of the planetary gear train. Sun wheel and ring gear are rotatable in opposite directions in a startup phase. As a result, the electric motors are operated in a characteristic mapping range with higher torque before the start, thereby positively affecting the acceleration of the chassis when changing the relative rotation speed.

Abstract: A technique of a heavy object turning apparatus that is compact, is enabled to reduce the distance between the center of gravity of a heavy object and a pivot positioned on an axis, and is configured so that a turning arm and a drive unit has a length in the direction of an axis passing through the pivot around which the heavy object is turned. A control unit fixes a support base onto a stand. An orthogonal axis reduction gear serves as an anterior reduction gear and has a configuration in which an output shaft is on an axis of a planetary gear type reduction gear serving as the posterior reduction gear. An input shaft is perpendicular to the axis. The orthogonal reduction gear is constituted by a hypoid reduction gear or a worm-geared reduction gear. A motor is disposed on the bottom surface of the orthogonal reduction gear.

Abstract: A transmission system having an input shaft for receiving/imparting rotation into the transmission system and an output shaft for delivering rotation from the transmission system, a flywheel component which has a ring gear portion and planet gear portion, wherein rotation of the input shaft causes rotation of the flywheel component, a first transmission shaft and a first transmission component, wherein rotation and/or orbital motion of the flywheel component is affected by the rotation or non-rotation of the first transmission shaft and by the rotation or non-rotation of the first transmission component, a second transmission shaft, wherein the first transmission component rotates if the second transmission shaft rotates, a second transmission component which rotates if the second transmission shaft rotates, wherein rotation or non-rotation of the second transmission component and rotation or non-rotation of the first transmission shaft affect the overall/net output shaft rotation, at least one modulator shaf

Abstract: A motor assembly for use in a surgical tool, has a motor and a gear train. The gear train has an output shaft, a fixed ring gear, a movable ring gear, a cover, and a multi-stage planetary gear set. Each gear stage has a sun gear, a carrier, and planet gears mounted on one side of the carrier. The planet gears are in mesh with a sun gear and either the fixed ring gear or the movable ring gear. The movable ring gear has inner teeth formed on an inner peripheral surface and one of the carriers has outer teeth formed on an outer peripheral surface.

Abstract: A drivetrain has at least one drive machine (2, 3) with a drive output shaft (6) that can be coupled via a transmission (10) to at least one drive wheel. The transmission (10) is mounted on the drive machine (2, 3) and has a planetary gear set (18). To reduce the expenditure for the development and/or manufacture of the drivetrain, the transmission (10) has different mounting positions rotated relative to the drive output shaft (6) of the drive machine (2, 3).

Abstract: An electrical power tool may include a speed change device that is capable of being automatically changed as an external torque applied to a spindle is increased. In a high speed low torque mode before an automatic speed change, an extremely high output rotation speed in which an output torque sufficient to progress the screw tightening operation to the end cannot be generated is set. The output rotation speed before the speed changing operation is set in a range of about 4.5 times to 6.0 times the output rotation speed after the speed changing operation. Thus, in an initial stage of the screw tightening operation, it is possible to quickly performing the operation with a high speed rotation than ever before. Conversely, after the automatic speed change, it is possible to complete the screw tightening operation with the large output torque.

Abstract: A power generation control system of an electric vehicle is disclosed. The power generation control system of an electric vehicle is characterized in that an elastic recovery force of a spring is converted into a rotational energy via a spring power generation apparatus, and the converted rotational energy is accelerated for thereby driving a vehicle generator and generating electric power, and when the spring is over loosened, the auto winding operation of a spring is performed by means of a spring winding motor with the help of a control of the control unit, and when the battery is over charged by means of the power generation process, the operation of the spring power generation apparatus is stopped.

Abstract: For driving an extruder (1) having disposed along a circle a plurality of shafts (3) with processing elements (4), the shafts (3) are connected to the output shafts (11) of a gearing (7) which are provided with output pinions (12, 13). The output pinions (12, 13) are disposed axially offset so that adjacent output shafts (11) have a different length (L1, L2) between the end facing the extruder (1) and the output pinion (12, 13). The axially offset output pinions (12, 13) are in engagement each with a sun gear (18, 19). One sun gear (19) is connected to a hollow torque shaft (21) and the other sun gear (18) to an inner torque shaft (22) disposed therewithin. The hollow torque shaft (21) and the inner torque shaft (22) are configured such that the difference in torsional rotation angle caused by the different length (L1, L2) of the output shafts (11) is compensated by a different torsion of the hollow torque shaft (21) and the inner torque shaft (22).

Abstract: A ship propulsion (3) with at least a fixedly positioned transmission unit (4, 204) secured to the hull (6) of the ship and a propulsion unit (5, 205) located on the exterior of the hull. The ship propulsion (3) facilitates pivoting of the propulsion unit (5, 205) around a control axis (10, 110, 210, 310), via a control device (200, 300). The control device has a control motor (120, 220, 320) and at least one control transmission (130, 230, 330). The control transmission is designed as a reduced planetary transmission, which comprises two central gears (131, 132, 231, 232, 331, 332) and a planetary gear carrier (233, 333, 433) with at least two planetary gears (238, 338), and coaxial positioned with reference to the control axis.

Abstract: A transmission system for a vehicle with an electric motor includes a continuously variable transmission having a drive pulley, a driven pulley connected to one wheel of the vehicle, and a belt operatively connected between the drive pulley and the driven pulley such that a pitch radius of the belt in contact with each pulley is variable. The transmission system further includes a planetary gear set having a sun gear connected to the output of the motor, a ring gear connected to the drive pulley, and a planet gear operatively connected between the sun gear and the ring gear. The planet gear is rotatable about a respective planet gear axis which is fixed in position relative to the sun gear axis such that the planetary gear set is arranged to be operable at a fixed gear reduction.

Abstract: A ring gear of a planetary reduction gear is screwed into an inner peripheral surface of a first housing through an opening thereof, while the thrust-receiving flange of a screw feed mechanism is held by the locknut screwed into an inner peripheral surface of a second housing through an opening thereof. In addition, the locknut and the ring gear face each other in an axial direction with a slight gap provided therebetween when the openings, respectively, of the first and second housings are connected to each other in the axial direction. Accordingly, even if the threaded connection of any one component of the locknut and the ring gear is loosened, the one component is prevented from moving by the other component.

Abstract: The present invention relates to a contra-rotating mechanism.

Abstract: A transmission is provided with a reverse input split mode and, preferably, a reverse low fixed speed ratio which provides sufficient reverse grade performance while allowing motor size and planetary and transmission ratios to be optimized for fuel economy or other design criteria. Engine-on reverse performance is improved, reducing dependence on the battery and electric motors to meet reverse grade performance requirements.

Abstract: A geared power train (100) for use in a wind turbine application to maximize a step-up ratio within a radial space that is defined by the planetary gearing system ring gear size. The geared power train (100) is configured as a split-compound planetary gearing system with a closed-carrier flex-pin planetary system in a high-torque stage (Stage 1) for receiving driving torque via an input shaft (IN) from a wind turbine, and an open-carrier flex-pin planetary system in a low-torque stage (Stage 2) coupled to the high-torque stage (Stage 1) for delivering the driving torque to an electrical generator via an output shaft (OUT).

Abstract: A heavy-duty drive arrangement for a mill having a grinding bowl ratable about a vertical axis comprises a housing, an electric motor, and a gearing arrangement disposed in the housing and supported on the housing. The grinding bowl can be driven by means of the electric motor via the gearing arrangement. The electric motor is disposed below the gearing arrangement. The electric motor is integrated in the housing. Advantageously, the electric motor is supported on the housing particularly on a bottom element of the housing. The rotor can be connected directly, or via a coupling integrated in the rotor, to a gear of the gearing arrangement. The mill may be, for example, a roller bowl mill.

Abstract: An electromechanical actuator, especially for an anti-roll bar of a motor vehicle, that has two actuator elements, which can be rotated relative to each other about a common rotational axis, for which purpose an electric motor and a gearbox coupled therewith are provided. The electric motor is arranged in an actuator element for transmitting a torque, and an output shaft of the gearbox is coupled to the other actuator element. A mechanical overload coupling is provided in the torque-transmitting load path from the electric motor to the gearbox output shaft.

Abstract: A gear transmission comprises a crankshaft that eccentrically rotates one of an internal gear and an external gear. A first gear is attached to one end of the crankshaft. A ring gear having internal teeth meshes with the first gear. An intermediate gear meshes with external teeth of the ring gear. A second gear is attached to one end of an output shaft of a motor and meshes with the intermediate gear. The motor and the crankshaft are positioned, relative to the intermediate gear, on the same side in the axial direction of the gear transmission.

Abstract: A wheel drive assembly includes a rotatable spindle-carrier affixed to a wheel. A fixed housing includes an output ring gear and the spindle-carrier resides generally within the housing. An output sun gear driven by an input carrier drives output planetary gears which, in turn, interengage the output ring gear driving and rotating the spindle-carrier. A fixed drive end housing includes an input ring gear and houses a noise reducing radially floating input carrier and a plurality of input planet gears rotatably mounted in the input carrier. The input sun gear is driven by an electric motor and drives the plurality of input planet gears which mesh with the input ring gear causing rotation of the input carrier about its true center. The input carrier is partially nested within the spindle-carrier and the motor is partially nested within the fixed drive end housing.

Abstract: A pivot assembly may include first and second subassemblies. The first subassembly may be adapted to be coupled to a frame member and rotationally fixed relative thereto. The first subassembly may include a latch mechanism displaceable between locked and unlocked positions. The second subassembly may be adapted to be coupled to the frame member and may be rotatable relative thereto. The second subassembly may include a power pivot assembly and a cam member. The power pivot assembly may be drivingly engaged with the cam member and operable to rotate the cam member in a first rotational direction to a first position where the cam member urges the latch mechanism into the unlocked position.

Abstract: An electric continuously variable transmission comprises a first rotating plate (110) which is mounted to a first shaft and provided with a sun gear (112), a second rotating plate (120) to which a planetary gear unit (121) is mounted, and a third rotating plate (130) which is mounted to a second shaft, with a ring gear (132) provided on a circumferential inner surface of the third rotating plate. The transmission further includes a field unit (140) which has a first coil (114) wound around a plurality of cores (113) provided on the first rotating plate. The transmission further includes a generation coil unit (150) which has a second coil (124) wound around a plurality of cores (123) provided on the second rotating plate.

Abstract: A vehicle includes a chassis, a traction member associated with the chassis, and a drive system associated with the chassis and the traction member comprising an electric traction motor, a planetary gear assembly coupled to the electric traction motor, the planetary gear assembly comprising an output member coupled to the traction member, wherein rotation of the output member provides a drive torque for the traction member.

Abstract: An electric motor assembly includes a stator defining a first interior space, a rotor positioned within the first interior space and configured for rotation relative to the stator, the rotor defining a second interior space, and a planetary gear assembly associated with the rotor and at least partially positioned within the second interior space.

Abstract: A planetary gear assembly includes a ring gear configured for connection to a rotor of an electric motor when in a first position and configured for connection to a housing of the electric motor when in a second position, a sun gear configured for connection to the housing when the ring gear is in the first position and configured for connection to the rotor when the ring gear is in the second position, and a plurality of planet gears configured to mesh with the ring gear and the sun gear.

Abstract: The present invention relates to a cam actuator which adopts an epicyclic reducer housed inside the eccentric cam supporting pivot, where is also provided a housing compartment for the electrical motor, whose pinion is perfectly coaxial with the axis of the epicyclic reducer and with the axis of said supporting pivot.

Abstract: To facilitate an integrating operation and to make fabricating cost inexpensive. An idle gear for transmitting rotation of an input gear of a drive motor to a cylindrical gear is rotatably supported by an input side end portion of a specific one crank pin, and therefore, the idle gear may simply be supported by the crank pin, further, a length in an axial direction of the cylindrical gear brought in mesh with both of the idle gear the input gear is sufficiently to a degree of being more or less longer than a distance between remote side ends of the two gears.

Abstract: A speed reducer part B of an in-wheel motor drive device (21) includes a casing (22), an input shaft (25) having one end arranged in the casing (22), disk-shaped eccentric members (25a and 25b) eccentric with respect to an axis O of the input shaft (25) and coupled to the one end of the input shaft, revolution members (26a and 26b) having a center part supported by outer circumstances of the eccentric members (25a and 25b) through a rolling bearing (41), to make a revolution motion around the axis O together with a rotation of the input shaft (25), an outer circumference engagement member (27) supported by the casing (22) and engaging with outer circumferential parts of the revolution members (26a and 26b) to cause the revolution members (26a and 26b) to make a rotation motion, and an output shaft (28) engaging with the revolution members (26a and 26b) to extract the rotation motion, in which the rolling bearing (41) has a lubricant oil hole (59) to supply a lubricant oil to a track surface (42a) being in rol

Abstract: The present disclosure is directed to a gear train. The gear train may include a first planetary gear set, which may include a first sun gear, a first ring gear, and a first carrier. The gear train may also include a second planetary gear set, which may include a second sun gear, a second ring gear, and a second carrier. Additionally, the gear train may include a first clutch configured to selectively connect the first carrier with the second carrier, as well as a second clutch configured to selectively connect the first sun gear with the second sun gear. The gear train may also include a first brake configured to selectively fix the second sun gear, as well as a second brake configured to selectively fix the first carrier.

Abstract: A transmission device with at least two output shafts and at least two multi-shaft planetary gearsets that are actively connected with one another. A shaft of a planetary gearset can be actively connected with an output shaft. In addition, a shifting mechanism, located between the two output shafts, shifts between a first power path or a second power path. In one of the planetary gearsets, torque from an electric machine can be transmitted along either the first or the second power path. In the first power path, torque from the electric machine is transmitted to the two output shafts in equal parts and with the same sign. In the second power path, torque is transmitted to the two output shafts in equal parts but with opposite signs. The planetary gearset, in the area of which the torque from the electric machine can be transmitted, is a simple negative planetary gearset.

Abstract: A speed change mechanism in which the gear ratio is selected by changing the direction of rotation of the power input includes first and second planetary gear sets enclosed within a hub shell. A DC electric motor is coupled to the sun gears of both gear sets and drives them simultaneously in the same rotary direction. In one of the gear sets the carrier arm is fixed and the ring gear is the output and in the other gear set the ring gear is fixed and the carrier arm is the output. A first one-way clutch transmits drive from an output of the first gear set to the hub shell and second one-way clutch transmits drive from an output of the second gear set to the hub shell, both clutches operating in the same direction. The outputs of the gear sets are driven in opposite rotary directions so that drive is transmitted to the hub shell either through the first gear set or the second gear set depending on the direction of rotation of the power input to provide two different gear ratios.

Abstract: There is described a power-driven wheel for a military vehicle, having an axial-flow electric motor, and a hub connected functionally to the motor and rotating about an axis; the motor has an output member housed inside the hub; and the wheel has an epicyclic reducer interposed functionally between the hub and the output member.

Abstract: An electronic drive unit includes a case housing that extends along a primary axis. A sleeve shaft and an electric motor are disposed in the hollow interior of the case housing. The electric motor is operatively connected to the sleeve shaft to rotate the sleeve shaft about the primary axis. At least one gear set is disposed in operative engagement with the sleeve shaft and is configured for rotation about the primary axis. A pair of output shafts each extends along the primary axis within the case housing. The output shafts are rotatably connected to the gear set and are configured for rotation about the primary axis. The gear set is configured to translate rotation of the sleeve shaft into rotation of the output shafts about the primary axis at a rotational velocity that is less than the rotational velocity of the sleeve shaft.

Abstract: A power transmission mechanism includes a cam-incorporated gear which rotates in one rotational direction by a driving force transmitted from a drive source via a planet gear when engaged with the planet gear, wherein the cam-incorporated gear stops rotating when disengaged from the planet gear; a driven member which includes a follower which contacts at least one surface cam formed on the cam-incorporated gear, the driven member being driven in accordance with the rotation of the cam-incorporated gear in the one rotational direction, and exerting a surplus torque on the cam-incorporated gear in the one rotational direction thereof so as to increase the rotation of the cam-incorporated gear in the one rotational direction, the surplus torque being independent of a torque exerted on the cam-incorporated gear by the drive source; and a damping mechanism which continuously exerts a load torque on the cam-incorporated gear in a rotational direction opposite to the one rotational direction of the cam-incorporated

Abstract: In compact drive, spiroid gear unit, and method for manufacturing a drive unit that includes at least an electric motor, a brake, a gear unit, and a frequency converter, the output shaft of the gear unit and the rotor shaft are positioned in parallel to each other, and the shaft-center distance is determined by at least one gear stage. The first gear stage includes a first toothed member connected to the rotor shaft, and a second toothed member, which engages with the first toothed member and is connected to an intermediate shaft, the brake, including at least a brake-rotor shaft, being integrated in the housing of the compact drive, the brake-rotor shaft being parallel to the rotor shaft, and the brake-rotor shaft being connected to a toothed member, which engages with the second toothed member.

Abstract: An electric drive unit for a motor vehicle includes an electric motor having a stator that is fixed with respect to a stub axle and a rotor that is rotatably supported with respect to the stub axle. A gear system has its input connected to the rotor for torque transmission. A wheel carrier is connected to the output of the gear system for torque transmission. A first bearing of the wheel carrier is provide on a first axial side of the electric motor facing away from the gear system. A second bearing of the wheel carrier is provided either on the first axial side of the electric motor, or in the gear system, realized in the form of a bearing of a rotatable gear system part connected to the wheel carrier.

Abstract: A transmission having a plurality of tilting balls and opposing input and output discs provides an infinite number of speed combinations over its transmission ratio range. The transmission provides multiple powerpaths and can be combined with electrical components to provide motor/generator functionality, which reduces the overall size and complexity of the motor and transmission compared to when they are constructed separately. In one embodiment, rotatable components of a continuously variable transmission are coupled separately to an electrical rotor and to an electrical stator so that the rotor and stator rotate simultaneously in opposite directions relative to one another. In other embodiments, an electrical rotor is configured to transfer torque to or from a disc that is in contact with a plurality of speed adjusters, while an electrical stator is configured to transfer torque to a shaft that is operationally coupled to the speed adjusters via an idler.

Abstract: An electric clutch actuator capable of operating in two power loss conditions. For a condition where a normally engaged clutch is disengaged during a system power loss and the desired action is for the clutch to remain in the disengaged positional state, a holding device moves to a power off activated position to prevent movement of an actuator for the clutch. For a condition where the clutch is disengaged during a system power loss and the desired action is for the clutch to move to an engaged positional state, a motor in the electric clutch actuator is used as a generator to convert the potential energy of a clutch pressure spring into electrical energy to provide energy for powering the holding device to remain deactivated, permitting movement of the clutch actuator to the engaged position. Maintaining the holding device deactivated permits the clutch to move to the engaged position and thereby allows vehicle engine braking to be used during a power loss of the system.

Abstract: A clutch 100 includes: an internal gear 3 that includes a gear tooth formed on an inner-surface side thereof; a sun gear 4 that is disposed on the same shaft at a central portion of the inner side of the internal gear 3; one or more planetary gears 5 that are disposed between an outer circumferential surface of the sun gear 4 and an inner surface of the internal gear 3; a carrier 6 that is provided with a boss portion 6a that supports rotatably the planetary gear 5; an electromagnetic coil portion 7; a rotation limit member 8 that is slidably inserted into the electromagnetic coil portion 7 in a shaft direction and selectively disposed at a first position for limiting rotation of the internal gear 3 or the sun gear 4 or at a second position for permitting the rotations of the internal gear 3 and the sun gear 4; and an elastic member 9 that is disposed between the electromagnetic coil portion 7 and the first flange portion 8b of the rotation limit member 8.