Abstract: A method and apparatus are provided for smoothing the ball transition in rolling element/cam type speed converters, with an alternative cable-run through the drive mechanism in either a single or multistage configuration.

Abstract: An automatic transmission using a torque converter as a starting apparatus comprises a stator hub, an one-way clutch both of which are offset on the pump impeller side respectively, a brake cylinder case provided in an inner diameter portion of the torque converter, a brake piston provided in the brake cylinder case, a part or the whole of a reverse brake and a part of or the whole of a planetary gear which are accommodated in the inner diameter portion of the torque converter, thereby the axial length of the automatic transmission can be reduced.

Abstract: A method for selecting between first and second manual shift modes for an automatic transmission is provided. The method includes the steps of providing a gear shift lever with first and second manual positions, placing the gear shift lever in a first manual position, and subsequently placing the gear shift lever in a second position. The method further includes the steps of selecting the first manual shift mode if the gear shift lever remains in the second position for a predetermined time period, cycling between the second and first manual positions while the gear shift lever remains in the second position, and setting a current manual mode equal to a last one of the first and second manual mode prior to the gear shift lever being released.

Abstract: Paired planetary gears 3A, 3B are each provided on one end thereof with a long gear portion 31, on the other end with a short gear portion 32, and a neck portion 33 between the long gear portion 31 and the short gear portion 32. The long gear portion 31 of the planetary gear 3A is in engagement with the short gear portion 32 of the other planetary gear 3B at an inner gear portion 31b and with a gear portion 2a of a side gear 2A at an outer gear portion 31a. The long gear portion 31 of the other planetary gear 3B is in engagement with the short gear portion 32 of the planetary gear 3A at the inner gear portion 31b and with a gear portion 2b of a side gear 2B at the outer gear portion 31a.

Abstract: A limited slip differential gear that is simple in construction, small in size and light in weight is provided. The limited slip differential gear includes a pair of divided gear cases that are turned by a driving force of an engine. A pressure ring provided in one of the gear cases is movable in the direction of the wheel axles. Pinion shafts each have an end that is freely engageably supported between the pressure ring and the gear cases. Pinion gears are turnably supported by the pinion shafts. A pair of side gears mesh with the pinion gears positioned therebetween to transmit the driving force to both wheel axles. A multiple disc clutch mechanism provided between one of the gear cases, the side gears and the pressure ring limits differential motion of the side gears when the pressure ring is moved in an axial outward direction.

Abstract: A control apparatus and control method for an engine powertrain of a vehicle including a CVT type automatic transmission and a lean burn engine. The control apparatus is designed to compute an engine torque in a stoichiometric area or a lean burn area, calculate an output torque from a present transmission ratio and a present torque ratio, calculate a transmission ratio change so that the output torque approximates a target torque, and vary the transmission ratio. With this configuration, shock due to steps in the output torque can be prevented to obtain a comfortable acceleration feeling.

Abstract: A novel drive train includes a motor, a differential gear unit, and a counter gear mechanism for transmitting the power of the motor to the differential gear unit. A universal joint for joining the differential gear unit to an axle shaft of a vehicle is arranged outward of one axial end of the motor to eliminate interference with the motor, and the differential gear unit is arranged adjacent the opposite axial end of the motor, radially overlapping the motor to the maximum, to thereby shorten the axial distance between the motor and the differential gear unit.

Abstract: An axle case assembly is provided with a speed sensitive torque coupling mechanism used to transmit torque from the ring gear to a planetary differential assembly. The differential assembly provides torque transfer proportional to the speed difference between the ring gear sub-assembly and a planetary gear set sub-assembly, wherein the invention splits a differential case assembly into two primary pieces and a speed sensitive mechanism is installed between each piece. The mechanism is entirely contained inside an axle differential case assembly. An optional limited slip device may be provided for the differential gears. The torque transmission coupling assembly eliminates the need for a center differential in the transfer case, i.e. an interaxle differential, thereby reducing the driveline complexity and cost without requiring a separate torque coupling in the transfer case or in-line with the driveline.

Abstract: A differential apparatus (7) comprises: a differential casting (21) rotated by an engine power; a plurality of pinion gears (65, 66) slidably housed in accommodation holes (63, 64) formed in the differential casing; a pair of side gears (35, 37) geared with each other via the pinion gears, two opposing end surfaces thereof being slid relative to each other, either directly or via a thrust washer (61); and a block member (47, 91, 97) interposed between two inner circumferential surfaces of the two side gears so as to center the side gears, respectively. In particular, at least one oil sump (77,) is formed between the block member and the side gears, to supply lubricant to sliding portions between the bolck member (47, 91, 97) and the side gears (35, 37) and between two opposing end surfaces of the two side gears, by a centrifugal force generated by the rotating differential casing.

Abstract: A control system of a lockup clutch of a torque converter of a vehicle automatic transmission. A basic manipulated variable is determined in response to the vehicle operating condition in accordance with a predetermined characteristic, and the lockup clutch engaging force is controlled in response to the variable. In the system, fuzzy reasoning is carried out using the detected vehicle operating parameters to correct the basic manipulated variable, and the engaging force is controlled in response to the corrected manipulated variable, when the control condition is met. The corrected manipulated variable is gradually decreased with respect to time when the vehicle driving state has shifted from a region in which the engaging force is controlled in response to the corrected manipulated variable to a region in which the lockup clutch is disengaged.

Abstract: An automatic transmission for motor vehicles includes a traction drive variator having two sets of input discs, a set of output discs, a gearset, a compound planetary gearset, and two clutches for connecting and releasing various elements of the gearsets. The carrier of the gearsets is connected continually to both sets of variator input discs, and a sun gear is continually connected to the variator output discs. The ring gear of the compound planetary gearset is continually fixed against rotation. The transmission operates in geared neutral condition, reverse and forward low ranges, and high and low forward ranges.

Abstract: Automotive vehicle control apparatus including a running stability control device for reducing engine output and/or applying brake to vehicle wheels for improving vehicle running stability, a shift control device for shifting an automatic transmission by engagement of at least one hydraulically operated frictional coupling device, depending upon a detected vehicle running condition as compared with a predetermined shift boundary pattern, a running stability control detecting device for detecting an operation of said running stability control device, and one of (a) a coupling pressure control device for controlling a hydraulic pressure of the frictional coupling device to be engaged to shift the automatic transmission, such that a rate of rise of the hydraulic pressure is lower when the operation of running stability control device is detected by the running stability control detecting device, than when the operation of the running stability control device is not detected, and (b) a shift point changing device

Abstract: The present invention provides shift mechanisms and methods of controlling a transmission. According to one embodiment of the present invention, a shift mechanism for use with a transmission includes a central axle defining a central axis; a master cylinder configured to increase the pressure of a liquid; and an eccentric assembly comprising a support member provided about the central axle and an eccentric mount coupled with the support member, the eccentric mount defining an eccentric axis and being in fluid communication with the master cylinder and configured to provide radial adjustment of the eccentric axis relative to the central axis providing adjustment of the gear ratio of the transmission.

Abstract: A high output transmission is made for increasing speed and torque from an engine or motor. It includes a planetary drive for gradually increasing speed output, a speed reducer for increasing torque output, and a friction brake which gradually slows and stops a wheel member of the planetary drive. The planetary drive wheel member is gradually slowed and stopped so that the planetary drive input to output speed ratio is increased starting from a 1 to 1 speed ratio. As the braking force is gradually increased power output is transmitted starting with a slow speed with high torque to a fast speed with lower torque and when the braking force is decreased power output resumes to a slow speed with high torque while the engine or motor can run at a set or constant speed. A clutch means is included in the transmission by the on/off action of the brake thereby providing a clutch and continuously variable transmission or CCVT.

Abstract: An engaging force control system of a fluid coupling is provided with a fluid coupling disposed between an input element connected with an engine and an output member connected with a drive wheel side member and including a lock-up clutch which is selectively engaged with and disengaged from the input and output elements, an engaging force adjusting device for adjusting the engaging force of the lock-up clutch, a throttle opening sensor for sensing a value related to a throttle opening of the engine, a vehicle speed sensor for sensing a value related to a vehicle speed of a vehicle, an engaging force control device for controlling the engaging force adjusting device based on an engaging property which is predetermined based on the values related to the throttle opening and vehicle speed as parameters and the values sensed and, an uphill detecting device for detecting an uphill running condition of the vehicle.

Abstract: A five speed planetary transmission has a simple planetary gear set, a compound planetary gear set and six torque transmitting devices which are engaged in combinations of three to provide five forward ratios and one reverse ratio. The planetary gear sets are interconnected with a continuous drive connection and one of the torque transmitting devices. Two of the transmitting devices are input clutches and the other three are brakes. The planetary carrier assembly member of the simple planetary gear set is the only member connected with the output shaft during all of the ratios. The ratio interchanges in both single step and double step forward interchanges are of the single transition type.

Abstract: A positive acting differential of the type having toothed drivers and couplers which automatically connect the two axles together to provide optimum traction for the vehicle, yet release one axle when the vehicle is proceeding around a curve without drive wheel slippage, whereby only a single axle is engaged through the drive system. In assemblies of the type wherein the axles are retained in the assembly by a C clip, at least one driver and one spacer are slotted so as to provide space for the insertion of C clip during assembly. This allows selection of the driver and coupler thicknesses without being restricted by the possible positions of the C clip groove in the axles during assembly, and reduces wear in the driver and coupler teeth by eliminating a source of asymmetry between the engaging drivers and couplers. Preferred and some alternate embodiments are disclosed.

Abstract: A one-piece differential casing for a parallel-axis differential assembly is provided. The integral casing includes a drum segment defining an internal chamber and a flange segment extending radially from the outer periphery of the drum segment. The casing further includes a window aperture extending through the drum segment that communicates with the chamber, a pair of sockets formed in the axle openings to rotatably support the side gears therein, and paired sets of gear pockets. A set of first pinion pockets are formed as elongated bores which communicate with the internal chamber and have an opening through one end wall of the drum segment. In addition, a set of second pinion pockets are formed as elongated bores which communicate with the internal chamber and have an opening through the opposite end wall of the drum segment. The first and second pinion pockets are arranged in paired sets and each has an axis which is parallel to the axis of the axle openings.

Abstract: A drive system for a hybrid drive vehicle, comprises a driving mechanism which includes a clutch, an engine connected the clutch, a first motor for generating power, connected to the clutch, a second motor for driving a drive wheel, connected to the clutch, and a transmission connected to the clutch. A third motor is provided for driving a hydraulic pump of a hydraulic system for the transmission. A first inverter is connected between the first motor and a battery, in which charging and discharging between the first motor and the battery being made through the first inverter. A second inverter is connected between the second motor and the battery, in which charging and discharging between the second motor and the battery being made through the second inverter. A third inverter is connected between the third motor and the battery, in which changing and discharging between the battery and the motor being made through the third inverter.

Abstract: A drive device for an engine-driven load, which in the drive direction successively includes an engine, a torque converter with an input shaft and an output shaft, and a continuously variable transmission unit with a primary shaft and a secondary shaft, between which torque can be transmitted with the aid of friction forces. The nominal torque which can be generated by the combination of engine and torque converter on the primary shaft of the transmission unit is greater than the maximum slipping torque of the transmission unit. The device is provided with devices which act on parts of the drive device in such a manner that the torque which can actually be generated in operation by the combination of engine and torque converter on the primary shaft of the transmission unit is limited. The limited level for the torque is controlled in such a manner that the torque generated is at most equal to the maximum slipping torque of the transmission unit.