Abstract: An axle assembly having an interaxle differential unit. The interaxle differential unit includes first and second side gears and a gear nest but does not have a case. The gear nest includes a spider having at least one spider shaft, a pinion gear that is rotatably disposed on the spider shaft, and a pinion gear retainer that is fastened to the spider shaft to retain the pinion gear.

Abstract: A diff-lock operation shaft 50 is supported by a case 11 in such a manner as to be rotatable around an axis P1 of the diff-lock operation shaft 50 and operates a diff-lock section 48 to a lock position A2 by being rotated, and a first coil spring 51 is wound around the outer surface of the diff-lock operation shaft 50 concentrically with the diff-lock operation shaft 50, and is linked at one end portion 51b to the diff-lock operation shaft 50 and at another end portion 51a to linking members 55 and 56. The first coil spring 51 is twisted around the axis P1 via the linking members 55 and 56 by the manual operation tool 58 being operated, and the diff-lock operation shaft 50 is rotated via the first coil spring 51.

Abstract: The present disclosure discloses a locking structure of a differential. The locking structure comprises a bi-stable electromagnetic clutch sleeved on an output axle shaft on one side of the differential. The bi-stable electromagnetic clutch comprises a movable locking disc and a fixed locking disc; the fixed locking disc is fixedly connected to a differential housing, and the movable locking disc and the fixed locking disc have face teeth that can engage with each other. The movable locking disc is sleeved on the output axle shaft, the bi-stable electromagnetic clutch drives the movable locking disc to move axially after being energized, the output axle shaft and the differential housing are locked when the movable face teeth engaged with the fixed face teeth so that the output axle shaft on either side of the differential and the differential housing have a same rotational speed and output torque.

Abstract: A work vehicle includes a drive axle assembly having an axle housing with an input opening and output openings in communication with an interior cavity. A gear assembly is disposed in the interior cavity of the axle housing, with the gear assembly having an input shaft extending through the input opening and coupled for co-rotation with a drive shaft. A park brake assembly is integrated with the drive axle assembly and is disposed within the axle housing. The park brake assembly imparts a brake force to arrest rotation of the input shaft, with the park brake assembly including a brake pack and a piston disposed about the input opening of the axle housing and with the piston configured to move relative to and act on the brake pack. A Belleville spring arrangement is also disposed about the input opening of the axle housing and acts on the piston to engage or release the park brake.

Abstract: A differential device is provided with a casing rotatable about an axis, a differential gear set coupled therewith including a pinion gear with a pressure angle (a4) and side gears in mesh therewith, output members respectively mediating torque transmission from the side gears to axles, each of which includes a friction face as a friction clutch for limiting the differential motion, dog teeth, and an oblique face forming an angle (a1) and constituting a cam for operating the friction clutch, a clutch member axially movable for functioning as a clutch to lock the differential motion and including a leg having a side face forming an angle (a2) to function as a cam and movable dog teeth each forming an angle (a3) satisfying an inequality a2?a3; and an actuator capable of driving the clutch member toward a position where the movable dog teeth mesh with the dog teeth.

Abstract: An inter-axle differential (IAD) assembly including a unitary IAD case having one or more spaced-apart apertures extending therethrough, wherein each of the IAD case apertures defines a groove, and a spider having a plurality of radially, outwardly extending legs, wherein one or more of the legs include an opening at an outward end thereof, and wherein each IAD case apertures are aligned with each of the leg openings. The IAD assembly further includes a locking mechanism having one or more fastening elements, wherein the fastening elements are selectively inserted through the IAD case apertures and into the one or more leg openings and/or into the grooves of the IAD case apertures.

Abstract: A locking angle gear box is provided. The locking angle gear box includes a torque transfer assembly, a ring gear, at least one connection drive assembly and an actuator. The torque transfer assembly is configured to communicate torque between the torque transfer assembly and a pair of outputs to halfshafts. The ring gear is rotationally supported on the torque transfer assembly. The ring gear is configured to transfer torque between at least a portion of a driveline and the torque transfer assembly. The at least one connection drive assembly is configured to selectively lock rotation of the torque transfer assembly with the rotation of the ring gear to selectively couple torque between the torque transfer assembly and the ring gear. The actuator is in communication with the at least one connection drive assembly to selectively manipulate the at least one connection drive assembly.

Abstract: Driveline of two driving tandem axles comprising a first axle and a second axle parallel to the first axle, having opposite ends, each suitable to support at least one wheel, an auxiliary shaft having a first end and a second end opposite the first, wherein said first end is provided with a joint to connect the auxiliary shaft coaxially to a main driveline shaft and wherein said second end is stably connected to said first axle to guide it in rotation, an intermediate shaft having a first end and a second end opposite the first, wherein said second end is stably connected to said second axle to guide it in rotation, a transmission device reversibly connected with said auxiliary shaft to transfer a rotation from said auxiliary shaft to said intermediate shaft, actuation means configured to deactivate said lifter when said actuator controls said connection and to activate said lifter when said actuator activates a disconnection between said transmission device and said auxiliary shaft.

Abstract: An axle assembly having a carrier housing, a locking differential assembly, a pair of differential bearing and an actuator assembly. The carrier housing includes a cavity. The locking differential assembly includes a differential case that is received in the cavity. The differential case includes a bearing bore into which an outer race of the differential bearing is received. The actuator assembly includes a sleeve that is movable between a first sleeve position, which is configured to cause the locking differential assembly to operate in an unlocked mode, and a second sleeve position that is configured to cause the locking differential assembly to operate in a locked mode. The sleeve is at least partly radially in-line with the differential bearing when the sleeve is in the first and/or second sleeve positions such that a plane taken perpendicular to the axis extends through both the sleeve and the differential bearing.

Abstract: A miniaturized differential mechanism restricting device that is mechanically connected to two operation elements. A plurality of holes are formed in an output-side cam, and pin holes are formed in a differential case in a penetrating manner such that the pin holes overlap with the plurality of holes. A plurality of first pins, which pass through the pin holes in a penetrating manner and are fitted in the holes, extend from a first slide member, and a plurality of second pins, which pass through the pin holes in a penetrating manner and are fitted in the holes, extend from a second slide member. The first slide member is moved in the axial direction by a first shift fork, and the second slide member is moved in the axial direction by a second shift fork.

Abstract: To prevent a differential lock status during operation, in a differential gear with a differential lock. A locking piece which rotates along with rotation of a differential case is attached to the differential case. A contact piece contactable with the locking piece is formed in a fork member that moves a lock pin to set the differential lock status. When the number of revolutions of the differential case becomes a predetermined number of revolutions, the locking piece moves to a position facing the contact piece, to regulate actuation of the fork member. Accordingly, the differential mechanism section is prevented from entry into the differential lock status.

Abstract: A differential assembly includes an axle, a differential, a differential lock assembly, a selector, and a coupler. The differential is coupled with the axle and is configured to facilitate operation of the axle at an axle speed. The differential lock assembly is associated with the differential and is movable between locked and unlocked positions. The selector is movable between lock-initiate and unlock-initiate positions. The coupler is configured to selectively couple the differential lock assembly and the selector. The coupler is configured for operation in deactivated and activated modes. When the coupler is in the deactivated mode, the differential lock assembly and the selector are decoupled from each other. When the coupler is in the activated mode, the differential lock assembly and the selector are coupled together.

Abstract: A differential assembly includes an axle, a differential, a differential lock, a blocking member, and a pump. The differential is coupled with the axle and configured to facilitate operation of the axle at an axle speed. The differential lock is associated with the differential and movable between a locked position and an unlocked position. The blocking member is associated with the differential lock and is movable between a blocking position and a non-blocking position. When the blocking member is in the blocking position, the differential lock is inhibited from moving to the locked position. The pump includes an outlet in fluid communication with the blocking member. The pump is operably coupled with the axle and is configured to facilitate movement of the blocking member into the blocking position when the axle speed is above a threshold speed. Vehicles including a differential assembly are also provided.

Abstract: A brake/differential lock pedal linkage includes a two-stage manual control that may lock a differential before progressively engaging a brake. The manual control may be a foot pedal or hand lever. The linkage may include a brake cam lever that pivots on a brake cam shaft in response to movement of the manual control, a differential lock link connected between the brake cam lever and an actuator that can move a differential lock shaft to lock the differential, and a lost motion coupling between the brake cam lever and the actuator allowing the brake cam lever to pivot to a differential lock position in which the actuator moves the differential lock shaft sufficiently to lock the differential, before the brake cam lever pivots further to progressively engage the brake.

Abstract: A differential lock assembly includes a differential lock and a blocking assembly. The differential lock assembly is movable between a locked position and an unlocked position. The blocking assembly is associated with the differential lock and includes a blocking member and a shape memory member. The blocking member is movable between a blocking position and a non-blocking position. When the blocking member is in the blocking position, the differential lock is inhibited from moving to the locked position. The shape memory member is coupled with the blocking member and configured to receive an activation signal. The shape memory member is configured for actuation between a first length and a second length in response to the activation signal, wherein actuation of the shape memory member between the first length and the second length facilitates movement of the blocking member between the non-blocking and blocking positions.

Abstract: A differential lock mechanism is provided for use in an axle assembly having a differential, an input member and first and second axles. A lock sleeve is co-axially disposed about the first axle, with the lock sleeve being rotatable with the first axle and laterally movable relative to the first axle. A lock collar is co-axially disposed about the lock sleeve and is laterally movable between outboard and inboard positions. A biasing member biases the lock sleeve toward the rotatable carrier and a lock fork is engaged with the lock collar. The lock fork is operable for moving the lock collar between the outboard and inboard positions. The lock collar is disengaged with the rotatable carrier when the lock collar is in the outboard position and is engaged with both the rotatable carrier and the lock sleeve when the lock collar is in the inboard position.

Abstract: A pin retention and assembly system that is used with vehicles, such as, off-road vehicles is provided. The pin retention and assembly system has modular locking pins engaging a collar positionable about a bearing journal of a differential housing. Channels are formed in the bearing journal for receiving the locking pins. The channels aid in maximizing the size of the bearing journal. The locking pins engage the collar to lock the differential housing. In an embodiment, the locking pins and locking apertures in the differential housing are orientated asymmetrically causing the number of locking pins to be independent to the apertures in the side gear.

Abstract: A differential lock mechanism is provided for use in an axle assembly having a differential, an input member and first and second axles. A lock sleeve is co-axially disposed about the first axle, with the lock sleeve being rotatable with the first axle and laterally movable relative to the first axle. A lock collar is co-axially disposed about the lock sleeve and is laterally movable between outboard and inboard positions. A biasing member biases the lock sleeve toward the rotatable carrier and a lock fork is engaged with the lock collar. The lock fork is operable for moving the lock collar between the outboard and inboard positions. The lock collar is disengaged with the rotatable carrier when the lock collar is in the outboard position and is engaged with both the rotatable carrier and the lock sleeve when the lock collar is in the inboard position.

Abstract: A brake/differential lock pedal linkage includes a two-stage manual control that may lock a differential before progressively engaging a brake. The manual control may be a foot pedal or hand lever. The linkage may include a brake cam lever that pivots on a brake cam shaft in response to movement of the manual control, a differential lock link connected between the brake cam lever and an actuator that can move a differential lock shaft to lock the differential, and a lost motion coupling between the brake cam lever and the actuator allowing the brake cam lever to pivot to a differential lock position in which the actuator moves the differential lock shaft sufficiently to lock the differential, before the brake cam lever pivots further to progressively engage the brake.

Abstract: A differential for motor vehicles installed between two half-shafts on which two drive wheels are keyed includes a box driven by the engine by a connecting element which causes it to rotate about axes of the half-shafts, on free ends of the latter there being keyed two bevel gears housed inside the box, the differential and the half-shafts being contained inside a casing. Each of the flanges through which the half-shafts penetrate into the box has a cylindrical extension outwards, with grooves which are complementary with respect to other grooves formed on the surface of a coaxial cavity formed in a sleeve slidable coaxially on each half-shaft and rotationally locked thereto, mounted inside the casing and provided with an element which causes it to slide in the two directions causing engagement between the grooves or disengagement thereof, locking together the box and the half-shafts or performing disengagement thereof.

Abstract: This invention relates to multiple driven axle vehicles, and particularly to all-terrain vehicles equipped for rear wheel drive, four wheel drive, and on-demand front wheel drive. The invention is directed toward a system of switchable traction options allowing the vehicle operator to easily choose between different modes, such as rear wheel drive with an open or unlocked differential, rear wheel drive with a locked differential, four wheel drive with open differentials, four wheel drive with one locked differential, four wheel drive with two locked differentials, or rear wheel drive with on-demand four wheel drive.

Abstract: An axle driving apparatus comprises a housing. The housing contains a hydrostatic transmission, a differential unit driven by the hydrostatic transmission, a pair of axles mutually differentially connected through the differential unit, and a restricting mechanism for selectively restricting differential motion of the axles by manual operation. The differential unit comprises a ring gear serving as an input gear and a pair of bevel gears which can be differentially rotated by rotation of the ring gear. The restricting mechanism engages one of the bevel gears with the ring gear. If a pair of differential side gears fixed on the respective axles serve as the bevel gears, the restricting mechanism engages one of the bevel gear to the ring gear through a claw clutch or a friction clutch.

Abstract: A differential with an improved locking mechanism is provided. The differential includes first and second clutch members in the form of a differential case having a first set of teeth and a an axle shaft mounted clutch collar having a second set of teeth. A yoke urges the clutch into an out of engagement and is supported on a pivot shaft. The yoke is selectively urged in one direction by an actuator acting on a lever on the pivot shaft. The lever is coupled to the yoke by a spring. The yoke is urged in an opposite direction by one or more return springs mounted on the same pivot shaft. The compact nature of the locking mechanism and the balance of forces provided by the springs and actuator provide an inexpensive and reliable locking mechanism.

Abstract: The present invention relates to a transmission for a recreation vehicle, such as an all-terrain vehicle that includes a locking assembly for locking a differential joint in the front- or rear-end portion of the transmission. A vehicle having both front and rear differentials may include separate locking assemblies for each differential to lock and unlock the differentials for various combinations of power allocation to wheels of the vehicle. A differential joint according to the invention may include a ring gear and spider gears that drive a universal joint coupled to wheels of the vehicle. A coupler of the locking assembly includes an inner surface configured to engage outer surfaces of the ring gear and the universal joint, and an outer surface configured to be engaged by an actuator. The actuator adjusts the coupler between a locked position wherein the ring gear and the universal joint are locked together, and an unlocked position wherein the universal joint is free to rotate relative to each other.

Abstract: A recess is formed on the side surface of output-side cams on the right side with through holes being formed on the sidewall of the case body of the differential case at positions corresponding to the recesses. An annular member is placed on the case body so as to be capable of moving, and projections are provided on the annular member so that they can be inserted into and pulled out of the recess via the through hole. The differential case and the right side output cam are rigidly joined by inserting the projection into the recess on the right side output cam through the through hole and thus the input-side block is not operated. Therefore, a power force is not transmitted to the left side output cam, and thus the differential function of the left and right drive wheels can be suspended.

Abstract: The differential includes a differential casing configured to be rotatably driven by a motor under a driving force. The differential includes a differential mechanism which includes a pair of first and second side-gears for distributing a torque of the differential casing to first and second output shafts. The differential includes a frictional clutch for interconnecting the first and second output shafts. The frictional clutch includes first and second power-transmitting members connected to first and second output shafts respectively and first and second clutch plates. The first and second clutch plates are connected to the first and second power-transmitting members respectively. The differential includes an actuator for operating the frictional clutch. One output shaft of the first and second output shafts is axially displacable by the actuator under an engagement force to engage the frictional clutch.

Abstract: A differential with an improved locking mechanism is provided. The differential includes first and second clutch members in the form of a differential case having a first set of teeth and a an axle shaft mounted clutch collar having a second set of teeth. A yoke urges the clutch into an out of engagement and is supported on a pivot shaft. The yoke is selectively urged in one direction by an actuator acting on a lever on the pivot shaft. The lever is coupled to the yoke by a spring. The yoke is urged in an opposite direction by one or more return springs mounted on the same pivot shaft. The compact nature of the locking mechanism and the balance of forces provided by the springs and actuator provide an inexpensive and reliable locking mechanism.

Abstract: An over-running clutch assembly comprises an outer race having a cylindrical inner surface and an inner race having a cammed outer surface coaxial with the cylindrical inner surface and defining a gap therebetween and a roller clutch disposed within the gap; a biasing element biases the roller clutch to a disengaged position; and an actuator selectively overcomes the biasing element to engage the roller clutch and lock the inner and outer races to prevent relative rotation therebetween. The actuation disk and the case end includes a first portion adapted to provide initial axial surface to surface contact between the actuation disk and the case end when the actuation disk contacts the case end and a second portion adapted to provide an surface to surface contact only after deflection of the actuation disk under the force of the actuator, thereby providing a spring back response when the actuator is de-energized.

Abstract: A vehicle driveline assembly for an automotive vehicle includes a differential assembly adapted to transfer torque proportionally between first and second axle half-shafts. An over-running clutch is adapted to selectively lock the differential assembly thereby effectively rotationally locking the axle half shafts to one another. The differential has three modes of operation; an open mode, wherein the differential is kept un-locked; a locked mode, wherein the differential is kept locked; and an automatic mode, wherein the differential is locked or un-locked based upon predetermined operating parameters. A selector switch allows an operator to selectively place the differential in one of the three modes. An electronic control unit receives inputs from the vehicle, compares the inputs to pre-determined operating parameters, and selectively engages or disengages the over-running clutch when the differential is in the automatic mode.

Abstract: A differential limiting mechanism produces a changeable differential limiting torque. A differential limiting mechanism operating lever is disposed so as to be operated and turned by a hand gripping a handgrip attached to a handlebar. The operating lever is interlocked with the differential limiting mechanism so that the differential limiting torque varies according to an angle through which the operating lever is turned. A lever stopping mechanism stops the operating lever at an angular position for producing a predetermined maximum differential limiting torque.

Abstract: A differential for a wheel set provided with three modes of operation. A stub axle and wheel axle in combination provide drive torque to one wheel of the wheel set. A single wheel axle provides torque to the other wheel of the wheel set. The stub axle and wheel axle are releasably interconnected by a clutch ring and when connected provide conventional differential operation including equalized torque applied from a propeller shaft to the wheels of the wheel set. Alternatively the clutch ring can also provide connection to the differential casing to insure common rotation of the two wheels. In the third mode, the clutch ring does not connect any of the components and the non-resisted rotation of the stub axle effectively disconnects the wheel axles from the propeller shaft. An actuator provides actuation from a position at the exterior of the differential into and through the case to the clutch ring.

Abstract: The temperature-based differential lock control monitors the temperature of a differential lock in a vehicle driveline. Depending on the detected temperature, the differential lock is automatically disengaged to avoid potential damage to the differential lock. The control preferably includes a controller that records information regarding the detected temperature over time.

Abstract: A differential having variable traction control and permitting preferably infinite planet or side gear braking adjustment during differential operation. In some preferred embodiments, an actuation element is movable during differential operation to exert braking force upon a side or planet gear. The braking force can be exerted directly or indirectly upon a gear surface by a braking element. The amount of braking force is preferably controlled via the actuation element through a range of positions. The actuation element is preferably a lever or similar element movable either to drive a brake element in harder or lighter frictional engagement with a planet or side gear or to drive a planet or side gear in harder or lighter frictional engagement with a brake element. Alternatively, the actuation element can be a set of cables movable to actuate a brake element. In other embodiments, actuation of the brake elements is inherently generated by differential operation.

Abstract: A lockable differential having a carrier and opposed bevel gears which engage respective shafts, and opposed pinion gears which engage the bevel gears, wherein a locking means includes a selector annulus engaging the carrier, a locking annulus engaging the carrier and selectively engagable with one of the bevel gears, and push rods connecting the selector annulus with the locking annulus for moving the locking annulus between locked and unlocked positions in which the locking annulus is, respectively, engaged with and disengaged from the selectively engagable one of the bevel gears.

Abstract: A locking differential is provided for selectably locking a first axle to a second axle. The locking differential utilizes a dog clutch assembly characterized by two interlocking clutch members positioned between the differential side gears on opposing sides of the differential pinion shaft. The interlocking clutch members have face splines thereon for engaging corresponding face splines formed on the side gears. An actuating mechanism can be selectably activated to force the two interlocking members into engagement with the side gears.

Abstract: A locking differential is provided for selectably locking a first axle to a second axle. The locking differential utilizes a dog clutch assembly characterized by two interlocking clutch members positioned between the differential side gears on opposing sides of the differential pinion shaft. The interlocking clutch members have face splines thereon for engaging corresponding face splines formed on the side gears. An actuating mechanism can be selectably activated to force the two interlocking members into engagement with the side gears.

Abstract: A vehicle drive mechanism as shown and described includes both a differential lock and an operating mechanism therefor, and a parking brake and an actuator mechanism therefor, in which the mechanism is constructed and arranged so that the differential lock mechanism can be actuated to lock out the differential without applying the parking brake so that application of the parking brake always locks out the differential. This may be accomplished by means of an actuator mechanism which includes a mechanical linkage extending from a parking brake piston surrounding the input shaft of the vehicle to a slidable member which engages a differential locking member in order to lock the differential. This linkage includes a slotted link which permits actuation of the differential lock independently of the vehicle brake, while inter-locking the vehicle brake actuator with a differential lock actuator so that setting the vehicle brake will always lock the differential.

Abstract: A spacer system for a differential lock assembly having a fixed clutch and a sliding clutch with a sliding-clutch collar. The spacer system comprises a shift fork member and a bearing adjuster which contact when the sliding clutch and fixed clutch are engaged so as to prevent the shift fork member from binding within the sliding-clutch collar, without requiring a manual adjustment to account for tolerance stackups or gear or bearing positional adjustments.

Abstract: A locking differential comprising a differential carrier1 housing a pair of bevel gears 2, 3 and at least one pinion gear 4 which meshes with the pair of bevel gears, a locking ring 6 positioned within the differential carrier1 between the carrier and one of the bevel gears and splined to the carrier 1 at 7 and 8, locking teeth 9 on the locking ring 6 and corresponding locking teeth 10 on the bevel gear 3, an annular cylinder 12 formed in the carrier 1 and receiving a piston 11 and seal 11 a, the piston 11 being integral with the locking ring whereby the charging of the cylinder 12 with compressed air causes the locking ring 6 to move into its locking position with the teeth 9 engaging the teeth 10 against the action of springs 13 to lock the differential. The locking ring is located within a shaped cover plate C which closes the differential carrier 1 and provides bearing support for the bevel gear 3.

Abstract: A driver-controlled differential lock control system allows vehicles with automatic, electronic and single range manual transmissions and air pressure actuated differential locking devices to have the vehicle differential thereof locked on only at low speeds. The control system includes a vehicle speed sensor, such as a speedometer transmitter, and a speed switch responsive to the vehicle speed sensor to selectively actuate a normally-closed air solenoid valve disposed in a vehicle air supply line upstream of a manually controlled air valve which supplies the differential lock actuator. The speed switch normally supplies power to the air solenoid valve until the speed of the vehicle exceeds a predefined limit whereat power is discontinued to the air solenoid valve causing disengagement of the differential lock.

Abstract: A four-wheel drive vehicle control system has a differential mode control device which operates in at least a first mode, in which differential action of a differential is variably restricted between an unlocked state and a locked state according to driving conditions, and a second mode, in which the differential is forcibly locked. The first and second modes are manually selected by the driver.

Abstract: In a differential, a clutch links an axially stationary planet carrier with an axially mobile output shaft so that they rotate together. Engaging gears with engaging surfaces parallel to the main axis link an axially stationary clutch part with the output shaft so that they rotate together. Engaging gears with engaging surfaces parallel to the main axis link an axially mobile clutch part with the planet carrier so that they rotate together.

Abstract: In a clutch (6) for locking a differential gear for a vehicle, a movable half (60) of the clutch (6) is pushed indirectly via a sliding sleeve (70) and intermediate members (77) in an engaging direction. Then the sliding sleeve (70), with a locking surface (74), retains the intermediate members (77) firmly in a locking position between a bearing surface (64) of the movable half (60) and an axially stationary retaining surface (4). Flanks (52, 62) of clutch teeth (51, 61) of an axially stationary half (50) and of the movable half (60) form in the axle direction a deflection angle (55). The bearing surface (64) and the retaining surface (4) form a wedge angle (65). The locking surface (74) of the sliding sleeve (70) is inclined in an axial direction forming a small releasing angle (75). To open the clutch (6), the sliding sleeve (70) is pulled away. A torque produces through the deflection angle (55) an axial deflection force which then disengages the clutch (6).

Abstract: A drive axle assembly and subassembly for use in tandem driving axle arrangements has a removable drive pinion shaft subassembly. An input shaft is journalled in an axle housing and is coupled to an output shaft also journalled in the housing by an inter-axle differential for torque sharing of driveline power. An input gear receives power from the inter-axle differential and drives a countershaft gear mounted on the drive pinion shaft. The drive pinion shaft is journalled in primary and secondary bearings which straddle the countershaft gear and are mounted on a removable cage which substantially surrounds the countershaft gear. The drive pinion shaft with countershaft gear is assembled into the primary and secondary bearings on the cage and is shimmed between the bearings to form a pinion shaft and subassembly. A threaded nut is torqued over the end of the drive primary shaft to retain and preload the drive pinion shaft in the bearings.

Abstract: A locking differential includes a case which is rotatably driven by a power source. A cross shaft is mounted within the case for rotation therewith. A pair of pinion gears are rotatably mounted on the ends of the cross shaft. The pinion gears mesh with side gears splined onto respect axle shafts. Thus, when the case is rotated, torque is transmitted through the cross shaft, the pinion gears, and the side gears to the axle shafts. A locking collar is journalled on one of the side gears for axial movement between locked and unlocked positions. In the locked position, the locking collar is connected to the side gear for rotation therewith. In the unlocked position, the side gear is free to rotate relative to the locking collar. The locking collar is connected to a shifting collar by a plurality of spoke portions which extend through respective slots formed through the case. Bearing means are provided in each of the slots for engaging and guiding the axial movement of the shifting and locking collars.

Abstract: To realize a small-sized differential gear provided with both differential limiting and locking functions simultaneously without markedly modifying the conventional differential case, the differential gear comprises a differential mechanism having a differential case, pinion shafts, pinion gears, two side gears, etc.; two frictional multiplate clutches disposed between the two side gears and two inner side wall surfaces of the differential case, respectively for limiting differential function; a lock clutch disposed within the differential case for generating two opposite direction thrust forces to engage said limit multiplate clutches into engagement and further locking the differential function; and actuator for actuating the lock clutch from outside of the differential case.

Abstract: A differential gear unit includes a viscous coupling for restricting the differential rotation of output gears (27, 29), with the conneciton of one of the parts (31) of the viscous coupling to one output gear being by way of a releasable connecting device so that the viscous coupling can be brought out of operation when required, e.g. under vehicle braking. The connecting device comprises a sleeve (1), coupling members (11) movable radially in the sleeve (1) to engage, when in radially outermost positions, groove (35) for torque transmission, and an actuating member (2) movable axially within the sleeve and operable on the coupling members. The actuating member (2) is movable by an axially displaceable positioning member (87, 49) through the intermediary of latching balls (68, 48) which are themselves radially displaceable to hold the actuating member in position without continuous application of a high force. The positioning member may be movable mechanically, electro-magnetically, or by fluid pressure.

Abstract: A differential gear unit for the drive axles of motor vehicles has a positive differential lock comprising a jaw clutch plate which is connected non-rotatably but movable axially with the differential case and which works in conjunction with a jaw clutch counterplate which is mounted non-rotatably and axially immobile on a differential gear drive shaft. The jaw clutch plate also serves as an armature for an electromagnet shaped as a ring magnet, which can be switched on and off manually. The jaw clutch plate is released from the jaw clutch counterplate by the preloaded spring means when the ring magnet is switched off. The electric circuit for controlling the ring magnet includes an electronic control unit developed as a velocity sensor which allows switching on of the ring magnet only below a predetermined velocity limit of the vehicle. Above this velocity limit the ring magnet switches off automatically.

Abstract: Disclosed is a differential mounted between two drive wheels of a vehicle, the differential having a lock-out mechanism for disabling the differential and forcing the drive wheels to rotate at the same speed.