A vehicle drive device that includes an input member drivingly coupled to an internal combustion engine; an output member drivingly coupled to wheels; a first rotating electric machine; a second rotating electric machine drivingly coupled to the output member; a differential gear device having three rotating elements, namely a first rotating element, a second rotating element, and a third rotating element, in order of rotational speed; and a friction engagement first clutch that is located in a power transmission path connecting the input member to the differential gear device and that allows the input member and the differential gear device to be decoupled from each other.

A variable output planetary gear set includes an input shaft, and input gear affixed to the input shaft so as to rotate with a rotation of the input shaft, a brake rotor, a rotor input gear affixed to the brake rotor, a planetary gear set, an output shaft cooperative with the planetary gear set, and an electromechanical brake cooperative with the brake rotor so as to selectively apply a braking force so as to slow a rotation of the rotor input gear. The electromechanical brake is, in particular, an eddy current brake. The planetary gear set includes a planetary input gear, a planetary carrier, plurality of planetary gears, a sun gear and a ring gear. The input gear is engaged with the planetary input gear. The ring gear is engaged with the rotor input gear.

A continuously variable transmission includes a first asymmetrical differential, having a transmission input shaft and a first output shaft, aligned along a transmission axis, a second asymmetrical differential, having a transmission output shaft and a first input shaft, aligned along the transmission axis, and a reduction gear unit, coupled between the first output shaft of the first asymmetrical differential and the first input shaft of the second asymmetrical differential. Rotation of the input shaft at a first input speed and torque is converted into rotation of the transmission output shaft at a second output speed and torque that varies independently of the first input speed and torque in response to a rotational resistance on the transmission output shaft.

A working machine including a working assembly that can be driven by an engine, with the engine being connectable to the working assembly via a power branching transmission including a first mechanical power branch and a second electric or hydraulic power branch, the first and second power branches being combined by a summation transmission that can be coupled to the working assembly on the output side and provides a variable transmission ratio between the first mechanical power branch and the working assembly that can be adjusted by the rotational speed of the second electric or hydraulic power branch. A blocking device is provided for blocking the variability of the transmission ratio that can be adjusted between the first mechanical power branch and the output side of the summation transmission by the rotational speed of the second electric or hydraulic power branch.

Transmission system (TS) comprising: a clutch module (CM) having an input (In) and a first and a second output (O1, O2), wherein between the first output and the input, a first clutch device (B, B1, C2) provided with first actuating means is present, and between the second output and the input a second clutch device (C, B2) with second actuating means is present, and a transmission module (TM), with an output (Out) and a first and a second input (i1, i2), wherein between the first input and the output, a first partial transmission provided with at least one transmission (VAR) is present, and between the second input and the output a second partial transmission provided with at least one further transmission or a mechanical connection is present, in which the two outputs (O1, O2) of the clutch module are connected to the two inputs (i1, i2) of the transmission module.

The transmission system further comprises a short-circuit clutch (S), which is present between the two outputs of the clutch module and/or the two inputs of the transmission module.

The transmission (VAR) inside the first partial transmission is continuously variable within a specified transmission range.

A continuously-variable transmission (CVT) has: a gearbox having a first planetary gear train, a second planetary gear train, a first rotating spool defined by one of two sun gears, two ring gears, and two carriers of the first and second planetary gear train, a second rotating spool defined by another one of the two sun gears, the two ring gears, and the two carriers, an input defined by a remaining one of the first sun gear, the first carrier, and the first ring gear, and an output defined by a remaining one of the second sun gear, the second carrier, and the second ring gear; a first brake operatively connected to the first rotating spool; a second brake operatively connected to the second rotating spool; and a transmission motor drivingly engaged to the first rotating spool or to the second rotating spool.

The present invention provides a controllable epicyclic type clutch device coupled with hybrid power train structured by using the controllable brake device to manipulate an epicyclic gear set (EG101), in which the power train having the clutch device structured by using the controllable brake device to manipulate the epicyclic gear set (EG101) can be widely applied in a dual rotary kinetic power source or a triple rotary kinetic power source, the structural configuration includes a coaxial in-series structure or a multiple axial in-parallel structure for satisfying the requirement of applied space.

An exemplary transmission system (TS) includes a clutch module (CM) having an input (In) and a first and a second output (O1, O2). A first clutch device (B, B1, C2) provided with a first actuator is present between the first output and the input, and a second clutch device (C, B2) with a second actuator is present between the second output and the input. The transmission system also includes a transmission module (TM), with an output (Out) and a first and a second input (i1, i2). A first partial transmission provided with at least one transmission (VAR) is present between the first input and the output, and a second partial transmission provided with at least one further transmission or a mechanical connection is present between the second input and the output. Two outputs (O1, O2) of the clutch module are connected to the two inputs (i1, i2) of the transmission module.

Packaged boost systems and electrical assist assemblies presented. In one example, packaged boost system includes a supercharger, a brake assembly, and a transmission assembly that are packaged together in a generally axisymmetric configuration. In one example, a packaged electrical assist assembly includes a supercharger, a transmission assembly, and a brake assembly that are packaged together in a generally axisymmetric configuration.

This invention relates to a method and arrangement for reduction of rotational mass of transmission system of a vehicle to improve its fuel efficiency. The reduction of rotational mass is achieved by replacing the torque converter of an automatic transmission or conventional clutch system of a manual transmission, by a flywheel and a holding device. The flywheel and the holding device are located inside the bell housing of the transmission.