A manual transmission unit has at least one input shaft, a transmission output shaft, a first intermediate shaft, a second intermediate shaft, a traction device, a plurality of gears and at least two traction wheels and a plurality of torque transmission devices for selectively connecting tooth and traction wheels to at least one of the shafts. Torque from the transmission input shaft can be transferred directly to the transmission input shaft by the traction device.

A multiple speed transmission includes an input shaft, an output shaft, a first planetary gearset having a first member, a second member, and a third member, and a second planetary gearset having a first member, a reaction member, a second member, and a third member. The transmission also includes a plurality of interconnecting members each connected between at least one of the first and second planetary gearsets and at least another of the first and second planetary gearsets. The transmission includes a plurality of torque-transmitting mechanisms which are selectively engageable in combinations of at least two to establish between seven and nine forward speed ratios and between two and four reverse speed ratios between the input shaft and the output shaft.

The input element of the automatic transmission is fixedly connected to the second sun gear, the output element is fixedly connected to the third planetary carrier, the second planetary carrier is fixedly connected to the third gear ring, the first gear ring is fixedly connected to the third planetary carrier, and the third sun gear is stationary. The first brake is engaged to brake the first rear sun gear, the second brake is engaged to brake the first front sun gear, and the third brake is engaged to simultaneously brake the first planetary carrier and the second gear ring; the first rear sun gear is connected to the input element via the first clutch, the first planetary carrier is connected to the second sun gear via the second clutch, and the first planetary carrier is connected to the second gear ring via the third clutch.

An automatic manual transmission comprising: a first sub-transmission configured for establishing even-numbered (2nd, 4th, 6th) gears and the reverse gear by a plurality of gear pairs (42/52, 44/54, 46/56, 40/50), and a second sub-transmission configured for establishing odd-numbered (1th, 3rd, 5th, 7th) gears by a plurality of gear pairs (41/51, 43/53, 45/55, 47/57); one or more output shafts (14, 15); one or more intermediate shafts (71, 72, 73, 74) each of which is coaxially and rotatably mounted either to an input shaft (11, 12) or to an output shaft (14, 15) and kinematically interposed between an output shaft and an input shaft; wherein said first sub-transmission is connected and disconnected to and from the output of the transmission by means of a first synchronizer (S1), and said second sub-transmission is connected and disconnected to and from the output of the transmission by means of a second synchronizer (S2).

A vehicle includes: an automatic transmission configured to select a gear from a plurality of gears by switching engagement of a plurality of friction engaging mechanisms; a determination unit configured to determine whether a predetermined deceleration condition is satisfied during traveling; and an engagement control unit configured to control the plurality of friction engaging mechanisms. If the determination unit determines that the predetermined deceleration condition is satisfied, the engagement control unit decelerates the vehicle by controlling, in addition to a friction engaging mechanism corresponding to a current gear among the plurality of friction engaging mechanisms, a degree of engagement of another friction engaging mechanism that can generate interlock of the automatic transmission.

A dual-clutch transmission assembly where engine torque is split between first and second shafts. Torque is supplied to the first shaft by a first clutch and torque is supplied to the second shaft by a second clutch. A first gearset is carried on the first shaft and a second gearset is carried on the second shaft. The first gearset includes a primary first gear and the second gearset includes a duplicate first gear. The first and second shafts receive torque from a transmission input shaft in response to contemporaneous engagement of the primary first gear, the duplicate first gear, and the first and second clutches, which can be used during vehicle launch to split the torque applied to the first and second clutches. Both the primary first gear and duplicate first gear meshingly engage first and second counter shaft gearsets, which are rotatably coupled to a transmission output shaft.

A method for determining transmission and/or clutch parameters of a motor vehicle automatic transmission having at least one clutch, in particular for basic calibration of the transmission, in particular an automated manual transmission and/or a dual-clutch transmission, includes determining drag torque and/or kiss point of the clutch using an actuable synchronization device. The clutch has at least one drive side connected to an internal combustion engine output shaft and at least one output side connected to a transmission input shaft. The transmission output and/or drive shaft is blocked. The drive side of the clutch is driven. Basic calibration of the transmission is improved by driving the drive side of the clutch by an electric motor, providing a freewheel-shifted gear stage, and driving the drive side of the clutch by the electric motor in a rotation direction opposite the internal combustion engine output shaft.

A dual-clutch transmission assembly where engine torque is split between first and second shafts. Torque is supplied to the first shaft by a first clutch and torque is supplied to the second shaft by a second clutch. A first gearset is carried on the first shaft and a second gearset is carried on the second shaft. The first gearset includes a primary first gear and the second gearset includes a duplicate first gear. The first and second shafts receive torque from a transmission input shaft in response to contemporaneous engagement of the primary first gear, the duplicate first gear, and the first and second clutches, which can be used during vehicle launch to split the torque applied to the first and second clutches. Both the primary first gear and duplicate first gear meshingly engage first and second counter shaft gearsets, which are rotatably coupled to a transmission output shaft.

A hybrid drivetrain for a hybrid-drive vehicle, including an electric motor and an internal combustion engine, the force output shaft of which alternatingly acts either on a first input shaft or on a coaxial second input shaft of a dual clutch transmission via two separating clutches of a dual clutch, wherein a respective first and second sub-transmission can be activated using the input shafts, and wherein fixed and idler gears are arranged in wheel planes on the two in-put shafts and a common axially parallel output shaft, said fixed and idler gears being combined into gear sets which form gear stages.

The invention relates to a shiftable transmission (1) having at least two shifting levels, preferably for use in rolling mill technology, said shiftable transmission comprising: a rotatably mounted input shaft (20), to which an input torque an be applied; a rotatably mounted first output shaft (30) and a rotatably mounted second output shaft (40), which are arranged parallel and are connected to each other by means of an output transmission stage in such a way that aid output shafts rotate oppositely, preferably at the same rotational speed, when an input torque is applied to the input shaft (20) at any shifting level of the shiftable transmission (1); a first coupling (50), which is designed to selectively connect an disconnect the input shaft (20) and the first output shaft (30), a first shifting level of the shiftable transmission (1) being realized in the coupled state, in which first shifting level the input shaft (20) and the first output shaft (30) are connected to each other in such a way that the input torque is transferred from the input shaft (20) to the first output shaft (30) without step-up or step-down, preferably without redirection and without a spur gear stage.