Abstract: A differential gear includes first and second differential mechanisms that are compact in radial and axial directions, the first and second differential mechanisms 5 and 7 arranged side by side along an axis of rotation in a center casing 3 that is rotatably supported, the differential gear 1 configured to form one of first and second coupling configurations, the first coupling configuration that couples the center casing and first and second differential mechanisms in such a way as to transmit rotation of the center casing to the first and second differential mechanisms in parallel, the second coupling configuration that couples the center casing and first and second differential mechanisms in such a way as to transmit rotation of the center casing to one of the first and second differential mechanisms (e.g. a front casing 31) via the other thereof (e.g. a second output gear 61), and at least one of the first and second differential mechanisms including face gears.

Abstract: A differential device for differentially distributing a driving force to axles along an axis is disclosed. The differential device has a case being capable of rotation about the axis, which includes a flange configured to receive the driving force and a shaft crossing the case perpendicularly to the axis; an opening defined by a peripheral border on an outer periphery of the case so as to allow access into the case, lateral extremities of which is deviated from a center of the shaft toward a direction opposite to the flange along the axis; and a differential gear set housed in and drivingly coupled to the case, the differential gear set including an input gear rotatable around the shaft and output gears so combined with the input gear as to differentially distribute the driving force to the output gears, the output gears being drivingly coupled to the axles.

Abstract: A differential device for a vehicle includes a differential casing 15, pinion shafts 25, 27 connected to through-holes of the differential casing 15, pinion gears 3 supported by the pinion shafts 25, 27, a differential mechanism 9 having side gears 5, 7 meshing with the pinion gears 3, a limited-slip differential 11 for limiting a differential rotation of the differential mechanism 9 and an actuator 13 for controlling the limited-slip differential 11. A ring gear is fixed on a flange part 17 of the differential casing 15. The flange part 17 is positioned on one side of the differential casing 15 in an axial direction of the differential casing disproportionately. The actuator 13 is arranged so as to abut on the flange part 17. The differential casing 15 is divided into casing pieces by a parting part 19 on one side of the differential casing 15 in opposition to the flange part 17 in the axial direction. The casing pieces are connected with each other by connecting members 21.

Abstract: A differential device is provided with a case rotatable about an axis; an input member configured to receive the torque from the input shaft, the input member being housed in the case and including an engaging outer periphery drivingly engaged with the case; first and second output gears configured to respectively drivingly link with the output shafts, the first and second output gears being rotatably housed in the case to form a row with the input member along the axis; one or more first pinions being rotatably housed in the case in parallel with the axis and meshing with the first output gear, the first pinions having no overlap with the engaging outer periphery of the input member and the second output gears; and one or more second pinions being rotatably housed in the case in parallel with the axis and meshing with the second output gears and the first pinions, the second pinions extending beyond the input member to reach the first pinions.

Abstract: A differential mechanism 3 is contained and supported at inside of a bell housing 7 integrally provided to a transmission case 11 of a transmission 9 to constitute a common lubrication environment. A limited slip differential mechanism 5 for limiting differential movement of the differential mechanism 3 is made to be selectively attachable to outside of the bell housing 7. The limited slip differential mechanism 5 is not restricted by a size of the bell housing 7, the sufficient limited slip differential mechanism 5 can be provided, and an interchangeability of presence/absence of the limited slip differential mechanism 5 can be provided.

Abstract: A differential device is provided with a case being capable of rotation around a rotation axis; a differential gear set housed in and drivingly coupled to the case, which includes first and second output gears and is configured to differentially transmit the rotation of the case to the first and second output gears; a clutch configured to controllably limit and free a differential motion between the first and second output gears, which is housed in the case; an actuator configured to actuate the clutch; and a notifying member configured to notify whether the differential motion is limited or freed to an exterior of the case.

Abstract: A clutch device is combinable with a rotating device rotating about an axis. The clutch device is provided with a clutch rotatable with the rotating device, a plunger for disengageably engage the clutch, a solenoid for generating a magnetic flux for driving the plunger, a magnetic core slidably fitting on a portion of the rotating device and incompletely enclosing the solenoid to expose the solenoid to the portion, and a support member configured to support the magnetic core to fit with the rotating device in an axial direction along the axis. The magnetic core in combination with the portion of the rotating device and the plunger is so dimensioned as to enclose the solenoid.

Abstract: A limited slip differential device has differential gears, a clutch to limit the differential function of the differential gears, and a electromagnetic solenoid including a plunger and a coil. The plunger is set to move forward to engage the clutch by electromagnetic force of the coil in a differential limit state and move backward by a return spring to disengage said clutch in a differential limitless state. The plunger contacts with a contacting member in at least one state of the differential limit state and the differential limitless state, and their contact area is set smaller than a facing area between them in at least the one state.

Abstract: A differential device is equipped with differential gears 3 and a pair of output gears 5, 7 that mesh with the differential gears 3 in different meshing pitch-circle radii R1, R2. The output gears 5, 7 are formed by contrate gears, while the differential gears 3 are formed by spur gears.

Abstract: A differential for a vehicle having a first output shaft and a second output shaft for wheels is provided. The differential includes an input member for inputting a driving force from an outside of the differential, a first face gear and a second face gear, both of which can be rotated by the input member, the first face gear and the second face gear being rotatable together with the first output shaft and the second output shaft and a pinion member that meshes with both the first face gear and the second face gear so as to allow a differential motion between the first face gear and the second face gear.

Abstract: A clutch device 2 has a diff case 19 rotatable with drive torque, side gears 11, 13 to which the drive torque is transferred from the diff case 19, a clutch ring 63 held in constant connection to the diff case 19 and axially movable to the side gears 11, 13 to be intermittently coupled thereto, and an electromagnetic actuator 29 operative to axially move the clutch ring 63. The electromagnetic actuator 29 includes an electromagnetic solenoid 25, and a plunger 27 axially movable in response to magnetic force of the electromagnetic solenoid 25 for axially moving the clutch ring 63. The electromagnetic solenoid 25 is disposed on the diff case 19 so as not to relatively move in an axial direction, and the diff case 19 forms a part of a magnetic flux path of the electromagnetic solenoid 25.

Abstract: An electromagnetic clutch 1 is disclosed having first and second relative rotary members 3, 5, an electromagnet 11 having a coil 7 and a yoke 9, a rotor 13 placed in close proximity to the electromagnet 11 and permeating magnetic field lines through the yoke 9, a friction clutch 15 operative to transfer drive torque between the first and second relative rotary members 3, 5, and an armature 17 permeating magnetic field lines coming from the rotor 13 for controlling coupling the friction clutch. The rotor 13 includes first and second magnetic members 21, 23 for forming at least one magnetic flux loop 19 and the first and second magnetic members 21, 23 are made of materials different from each other.