Abstract: A drive axle assembly comprises a carrier member having a trunnion outwardly extending from the carrier member, an output shaft axially outwardly extending from the carrier member, a differential assembly including a differential case supported for rotation within the carrier member and a side gear rotatably mounted about the output shaft, a clutch collar non-rotatably coupled thereto and configured to selectively drivingly engage the side gear, and an annular clutch actuator for axially moving the clutch collar between a first position and a second position. The clutch collar drivingly engages the side gear in power transmitting relationship in the first position, while the clutch collar is disengaged from the side gear in the second position.

Abstract: A power transfer unit for a vehicle is provided having a transfer sleeve, a flanged ring gear, an output shaft, and a clutching assembly. The transfer sleeve, the flanged ring gear, and the clutching assembly are disposed in a housing about an axle shaft connected to a center differential. The transfer sleeve is drivingly engaged with a carrier of the center differential and the flanged ring gear is disposed about the transfer sleeve and drivingly engaged with the output shaft. The clutching assembly includes a locking collar and a clutch. The clutch may be engaged to transfer torque through the transfer sleeve to the output shaft through the flanged ring gear and the locking collar may be engaged to drivingly engage the transfer sleeve with the output shaft through the flanged ring gear.

Abstract: A drive axle assembly comprises a carrier member having a trunnion outwardly extending from the carrier member, an output shaft axially outwardly extending from the carrier member, a differential assembly including a differential case supported for rotation within the carrier member and a side gear rotatably mounted about the output shaft, a clutch collar non-rotatably coupled thereto and configured to selectively drivingly engage the side gear, and an annular clutch actuator for axially moving the clutch collar between a first position and a second position. The clutch collar drivingly engages the side gear in power transmitting relationship in the first position, while the clutch collar is disengaged from the side gear in the second position.

Abstract: An actuator assembly for generating a fluid pressure and applying the fluid pressure to a first device. The actuator assembly comprises a first fluid chamber and a first piston disposed adjacent to the first fluid chamber, a second fluid chamber and a second piston slidably received in the second fluid chamber, a fluid passage connecting the first fluid chamber with the second fluid chamber, and an actuator motor for selectively reciprocating the first piston so that axial movement of the first piston generates a fluid pressure within the first fluid chamber. The first piston is disposed within the actuator motor. As the first chamber is fluidly communicating with the second fluid chamber, the linear motion of the first piston causes corresponding linear motion of the second piston for applying the fluid pressure to the first device.

Abstract: A transaxle unit comprises a differential assembly having a differential mechanism, a power take-off unit and a torque-coupling device for selectively restricting differential rotation of a differential mechanism. The torque-coupling device includes a friction clutch assembly for selectively frictionally engaging and disengaging a differential case and one of output axle shafts and a hydraulic clutch actuator. The hydraulic clutch actuator includes a hydraulic pump and a variable pressure relief valve assembly fluidly communicating with the hydraulic pump to selectively control a hydraulic pressure generated by the hydraulic pump.

Abstract: A drive axle assembly comprises a carrier member having a trunnion outwardly extending from the carrier member, an output shaft axially outwardly extending from the carrier member, a differential assembly including a differential case supported for rotation within the carrier member and a side gear rotatably mounted about the output shaft, a clutch collar non-rotatably coupled thereto and configured to selectively drivingly engage the side gear, and an annular clutch actuator for axially moving the clutch collar between a first position and a second position. The clutch collar drivingly engages the side gear in power transmitting relationship in the first position, while the clutch collar is disengaged from the side gear in the second position.

Abstract: A drive system designed to use a vehicle's existing hydraulic system to operate a controllable limited slip differential assembly. The limited slip differential assembly may be associated with the front axle, the rear axle, or the driveline between the front and rear axles. The differential assembly may also be used in combination that includes front, rear, or intermediate differential assemblies. The drive system further includes a friction clutch assembly for selectively engaging and disengaging an input member with an output member of the differential assembly, a fluid clutch actuator for selectively frictionally and variably loading the clutch assembly, and a fluid pump that is a common source of pressurized fluid for the fluid clutch actuator and the existing hydraulic system of the motor vehicle other than the fluid clutch actuator of the drive system. The fluid clutch actuator is actuated by fluid pressure generated by the fluid pump.

Abstract: An axle assembly for a motor vehicle comprises an axle housing having a central axis and first and second openings formed through the axle housing opposite to each other, a carrier with a differential bearing support supporting a differential thereon for rotation about the central axis, and an abutment member attached to the axle housing adjacent to the first opening to extend substantially in a direction of the central axis. The carrier is fastened to the axle housing adjacent to the second opening therein. The abutment member engages the differential bearing support and absorbs a gear separating force imparted in operation by the differential and transmitted to the differential bearing support. Thus, the abutment member restrains deflection of the differential bearing support relative to the axle housing resulting from the gear separating force.

Abstract: A front-wheel-drive transaxle unit for a motor vehicle comprises a differential assembly having a differential mechanism disposed in a differential case and two opposite output shafts outwardly extending from the differential case and a torque-coupling device for selectively restricting differential rotation of the differential mechanism. The torque-coupling device includes a friction clutch assembly for selectively frictionally engaging and disengaging the differential case and one of the output shafts, and a selectively controllable clutch actuator assembly for selectively frictionally loading the friction clutch assembly. The clutch assembly includes at least one first member non-rotatably coupled to the differential case and at least one second member non-rotatably coupled to one of said output shafts. The torque-coupling device provides the differential assembly of the front-wheel-drive transaxle unit with both limited-slip and open differential capabilities.

Abstract: An axle housing assembly for a motor vehicle comprises a hollow, elongated arm section extending along a center axis and a wheelend. The wheelend is fixed to an outboard end portion of the arm section. The wheelend includes a wheelend adapter fixed to the outboard end of the arm section so as to extend radially outwardly therefrom, a tubular spindle member extending axially outwardly from the wheelend adapter substantially along the center axis, and a brake backer plate attached to the wheelend adapter. The spindle member has a substantially cylindrical bearing support surface for supporting an axle bearing.

Abstract: A transaxle unit comprises a differential assembly having a differential mechanism, a power take-off unit and a torque-coupling device for selectively restricting differential rotation of a differential mechanism. The torque-coupling device includes a friction clutch assembly for selectively frictionally engaging and disengaging a differential case and one of output axle shafts and a hydraulic clutch actuator. The hydraulic clutch actuator includes a hydraulic pump and a variable pressure relief valve assembly fluidly communicating with the hydraulic pump to selectively control a hydraulic pressure generated by the hydraulic pump.

Abstract: An actuator assembly for generating a fluid pressure and applying the fluid pressure to a first device. The actuator assembly comprises a first fluid chamber and a first piston disposed adjacent to the first fluid chamber, a second fluid chamber and a second piston slidably received in the second fluid chamber, a fluid passage connecting the first fluid chamber with the second fluid chamber, and an actuator motor for selectively reciprocating the first piston so that axial movement of the first piston generates a fluid pressure within the first fluid chamber. The first piston is disposed within the actuator motor. As the first chamber is fluidly communicating with the second fluid chamber, the linear motion of the first piston causes corresponding linear motion of the second piston for applying the fluid pressure to the first device.

Abstract: A front-wheel-drive transaxle unit for a motor vehicle comprises a differential assembly having a differential mechanism disposed in a differential case and two opposite output shafts outwardly extending from the differential case and a torque-coupling device for selectively restricting differential rotation of the differential mechanism. The torque-coupling device includes a friction clutch assembly for selectively frictionally engaging and disengaging the differential case and one of the output shafts, and a selectively controllable clutch actuator assembly for selectively frictionally loading the friction clutch assembly. The clutch assembly includes at least one first member non-rotatably coupled to the differential case and at least one second member non-rotatably coupled to one of said output shafts. The torque-coupling device provides the differential assembly of the front-wheel-drive transaxle unit with both limited-slip and open differential capabilities.

Abstract: A drive system designed to use a vehicle's existing hydraulic system to operate a controllable limited slip differential assembly. The limited slip differential assembly may be associated with the front axle, the rear axle, or the driveline between the front and rear axles. The differential assembly may also be used in combination that includes front, rear, or intermediate differential assemblies. The drive system further includes a friction clutch assembly for selectively engaging and disengaging an input member with an output member of the differential assembly, a fluid clutch actuator for selectively frictionally and variably loading the clutch assembly, and a fluid pump that is a common source of pressurized fluid for the fluid clutch actuator and the existing hydraulic system of the motor vehicle other than the fluid clutch actuator of the drive system. The fluid clutch actuator is actuated by fluid pressure generated by the fluid pump.

Abstract: A transfer case including a hydraulically actuated torque-coupling device is provided for selectively actuating a secondary drive axle of an All-Wheel Drive motor vehicle when wheel slippage occurs with a primary axle. The transfer case comprises a housing, an input shaft and an output shaft both rotatably supported within the housing, and the torque-coupling device. The torque-coupling device comprises a hollow casing, a selectively engageable friction clutch assembly for operatively coupling the input shaft to the output shaft, and a hydraulic clutch actuator. The hydraulic actuator includes a hydraulic pump located within the casing and adapted to generate a hydraulic pressure to frictionally load the friction clutch assembly, and a variable pressure relief valve assembly fluidly communicating with the hydraulic pump to selectively control the hydraulic pressure generated by the pump.

Abstract: An electronically controlled front wheel drive limited slip differential assembly that is designed to allow an operator to manually or automatically control the limited slip function. The differential control and actuation assembly is located external to the front transaxle and differential case. The assembly includes an electric solenoid that modulates hydraulic pressure produced by a gerotor pump. When the limited slip differential control is in the ON position, hydraulic pressure produced by the gerotor pump engages a friction clutch pack, which couples the differential case to the front axle output shaft. When the limited slip function is in the OFF position, the electrical solenoid does not allow the gerotor pump to generate sufficient hydraulic pressure to actuate the clutch pack.

Abstract: A hydraulically actuated torque-coupling device is provided for selectively actuating a secondary drive axle of an All-Wheel Drive motor vehicle when wheel slippage occurs with a primary axle. The torque-coupling device comprises a housing, an input shaft and an output shaft both rotatably supported within the housing, a selectively engageable friction clutch assembly for operatively coupling the input shaft to the output shaft, and hydraulic clutch actuator. The hydraulic actuator includes a hydraulic pump located within the housing and adapted to generate a hydraulic pressure to frictionally load the friction clutch assembly, and a variable pressure relief valve assembly fluidly communicating with the hydraulic pump to selectively control the hydraulic pressure generated by the pump. The variable pressure relief valve assembly includes an electro-magnetic actuator for selectively varying a release pressure of the pressure relief valve assembly based on a magnitude of an electric current applied thereto.

Abstract: A transfer case housing includes a single-piece casing forming an interior compartment provided with an access opening for assembling components of the transfer case, and a casing cover member for closing the access opening. The casing is manufactured as a single-piece casting wherein bearing bores could be machined into the unitary single-piece casing. The interior compartment is adapted to house an appropriate torque transfer mechanism, such as constant four-wheel-drive, or “on-demand” four-wheel-drive, providing rear or front wheel drive (two-wheel-drive mode), or four wheel drive (four-wheel-drive mode), controlled automatically or manually by a vehicle operator.

Abstract: A method for manufacturing a banjo-type drive axle housing for a motor vehicle is disclosed. The first step is the operation of forming the substantially identical upper and lower half members having a U-shaped cross-section along entire length thereof with radially extending wall sections. Each of the members is metal formed, such as by stamping or forging, from a blank sheet of steel. Next step is to select a desired box-section of an axle beam portions, and a desired size of an opening in a central portion of the axle housing. Then, if necessary, the wall sections of the housing half members are trimmed so that when assembled said housing half members provide the desired box section and size of the opening in the central portion of the axle housing. Finally, the trimmed housing half members are welded to each other to produce the axle housing.

Abstract: A differential gear assembly has a friction clutch for variably restricting differential action. A simple hydraulic piston mechanism is used to amplify the axial force generated by the electric coil and mechanical ball ramp mechanism. The hydraulic system consists of an annular primary piston in contact with the clutch pack, and a multiple set of secondary pistons are attached to the unrestrained ball ramp race. Hydraulic fluid fills the cavity between the primary and secondary pistons. This system provides force multiplication proportional to the surface areas of the respective piston faces.