Gear arrangement for a vehicle, having an input shaft, a layshaft, an output shaft connected to a drive wheel of the vehicle, a plurality of shiftable first gear wheel sets which connect the input shaft and the layshaft and which are each associated with at least one gear stage, and a machine gear connected to one of the shafts and into which the drive torque of an electric machine can be introduced. The first gear wheel sets form a first part-gear mechanism, wherein at least one second shiftable gear wheel set connects the layshaft and the output shaft and forms a second part-gear mechanism, wherein the at least one second gear wheel set is associated with at least one gear stage and wherein the machine gear is arranged in an axial direction between the first part-gear mechanism and the second part-gear mechanism.

Methods and systems for a vehicle transmission are provided. A transmission system includes, in one example, an intermediate shaft rotationally coupled to an input shaft and an output shaft, wherein the input shaft is configured to receive rotational input from an electric machine. The system further includes a first gear coupled to the intermediate shaft, and a plurality of clutches coupled to the input shaft and the output shaft and configured to in a first mode, transfer power directly between a second gear coupled to the input shaft, the first gear, and a third gear coupled to the output shaft, and in a second mode, transfer power indirectly between the second gear, the first gear, and/or the third gear.

A transmission system, including: a first input shaft (1) that is arranged to receive drive directly from a drive source (80); a second input shaft (3) that is arranged to receive drive from the drive source (80) via a drive interruption means (86), such as a friction clutch device; a first lay shaft (5); a gear element (19) rotatably mounted on the first input shaft (1); a gear element (15) mounted on the first lay shaft (5); a first selector assembly (29) arranged to selectively lock the gear element (19) rotatably mounted on the first input shaft (1) for rotation with the first input shaft (1) and to selectively lock the gear element (15) mounted on the first lay shaft (5) for rotation with the first input shaft (1), the first selector assembly (29) comprising a single engagement ring (35) that includes a first side (35a) having a first set of engagement elements (28a), wherein each engagement element (28a) has a drive face (43a) arranged to drivingly engage in a first rotational direction a first set of drive formations (20a) associated with the gear element (19) rotatably mounted on the first input shaft (1) and a non-driving face (45a), such as a ramp, that is arranged to slip with respect to the first set of drive formations (20a) in a second rotational direction, thereby preventing driving engagement with the first set of drive formations (20a), and a second side (35b) having a second set of engagement elements (28b), wherein each engagement element (28b) has a drive face (43b) arranged to drivingly engage in the second rotational direction a second set of drive formations (20b) associated with the gear element (15) mounted on the first lay shaft (5) and a non-driving face (45b), such as a ramp, that is arranged to slip with respect to the second set of drive formations (20b) in the first rotational direction, thereby preventing driving engagement the second set of drive formations (20b).

A dual clutch transmission-equipped power unit includes a prime mover including a drive shaft and a dual clutch transmission that changes the speed of rotation produced by rotational power output by the drive shaft. The dual clutch transmission includes a first input shaft which overlaps the drive shaft when viewed in a first direction perpendicular to the drive shaft. The dual clutch transmission includes a second input shaft which overlaps the drive shaft when viewed in a second direction perpendicular to the drive shaft. The dual clutch transmission includes a countershaft which overlaps the drive shaft when viewed in a third direction perpendicular to the drive shaft.

A hybrid drivetrain for a hybrid powered vehicle, having an electric machine and a combustion engine, whose power output shaft acts in alternating manner either on a first input shaft or on a coaxial second input shaft of a dual clutch transmission across two separating clutches of a dual clutch, wherein a respective first and second subtransmission can be activated using the input shafts, and wherein fixed and idler gearwheels are arranged in wheel planes on the two input shafts and a common axially parallel driven shaft, said fixed and idler gears being combined into gear sets which form gear stages, in which the idler gearwheels can be coupled to the shafts by means of gear-shifting elements.

A planetary gearbox including a first planetary gear assembly, a second planetary gear assembly, and a disconnect assembly. The first planetary gear assembly includes a first sun gear, a first carrier, at least one first planet gear mounted in the first carrier, and a ring gear. The second planetary gear assembly includes a second sun gear, a second carrier, at least one second planet gear mounted in the second carrier, and the ring gear. The disconnect assembly includes a disconnect member and a connecting member. The disconnect member is coupled to the second carrier of the second planetary gear assembly, and the connecting member is coupled to both the disconnect member and the movable second sun gear.

A transmission includes a main shaft having two or more main shaft clutches that couple gears to at least one countershaft, and an automated manual transmission coupled to the main shaft via the at least one countershaft. The automated manual transmission includes a front input shaft coupled directly to a main clutch and having a first clutch coupleable to the at least one countershaft, and a rear input shaft coupled to the front input shaft and having a second clutch coupleable to the at least one countershaft. The automated manual transmission is operable to selectively engage the first clutch and the second clutch.

A power train for an electric vehicle may include an input shaft to which a motor is fixedly connected; an output shaft mounted in parallel to the input shaft; a first driving gear and a first driven gear mounted on the input shaft and the output shaft, respectively, to be gear-engaged with each other; a second driving gear and a second driven gear mounted on the input shaft and the output shaft, respectively, to be gear-engaged with each other; a one-way clutch mounted in a first path where power is transmitted from the input shaft to the output shaft through the first driving gear and the first driven gear; a restraining mechanism mounted to selectively restrain the one-way clutch from freely rotating; and a friction clutch mounted to regulate a second path where power is transmitted from the input shaft to the output shaft through the second driving gear and the second driven gear.

A transmission (2) of a motor vehicle includes a first input shaft (7) for a first prime mover (3), a second input shaft (8) for a second prime mover (4), and an output shaft (9). A first sub-transmission (5) includes the first input shaft and a countershaft (11) coupled to the first input shaft (7) via a constant ratio. Gearwheels (16, 17, 18) are arranged on the countershaft, which mesh exclusively into gearwheels (12, 13, 15) arranged coaxially to the first input shaft (7). At least some of these gearwheels mesh into gearwheels (20, 21) arranged on the output shaft (9). Shift elements (A, B, C, D) are associated with the first input shaft (7) as well as with the countershaft (11), which provide either a gear with a first number of instances of gearwheel meshing or a winding-path gear with a second number of instances of gearwheel meshing. A second sub-transmission (6) includes the second input shaft (8), which is designed as a planetary transmission. A ring gear (22) forms the second input shaft (8), and a carrier (23) is coupled to the output shaft (9) via a gearwheel (14) arranged coaxially to the first input shaft (7). Shift elements (F, E) are associated with the planetary transmission, via which a sun gear (24) is fixedly connectable to the housing or the planetary transmission is bringable into direct drive. A sub-transmission coupling of the sub-transmissions is providable via one of the shift elements (A) associated with the countershaft.

A hydro-mechanical transmission device with a dual-clutch transmission includes an input mechanism, a pump-controlled motor mechanism, an odd-numbered gear transmission mechanism, an even-numbered gear transmission mechanism, an output mechanism, and a jackshaft. The input mechanism is connected to the odd-numbered gear transmission mechanism and the even-numbered gear transmission mechanism that are connected in parallel, and is connected to an input end of the pump-controlled motor mechanism. An output end of the pump-controlled motor mechanism is connected, through the jackshaft, to the odd-numbered gear transmission mechanism and the even-numbered gear transmission mechanism that are connected in parallel, and is connected to the output mechanism. Switching among hydraulic transmission, hydro-mechanical transmission, and mechanical transmission modes between the input mechanism and the output mechanism is implemented by controlling combination and engagement/disengagement of clutches and a brake.