In a hybrid transmission, a traction motor is mounted between a dry clutch module and a manual gearbox. A slave cylinder is mounted within the rotor of the traction motor to reduce axial length. The rotor is fixedly coupled to an engine crankshaft. The stator may be cooled by circulating engine coolant through the housing. The stator and the rotor may be cooled by spraying transmission fluid into a sealed motor cavity.

In a hybrid transmission, a traction motor is mounted between a dry clutch module and a manual gearbox. A slave cylinder is mounted within the rotor of the traction motor to reduce axial length. The rotor is fixedly coupled to an engine crankshaft. The stator may be cooled by circulating engine coolant through the housing. The stator and the rotor may be cooled by spraying transmission fluid into a sealed motor cavity.

A powertrain is provided with a combustion engine, a front drive axle, a longitudinal drive shaft, and a rear drive axle, whereby the combustion engine is connected to a front drive axle, the longitudinal drive shaft, and the rear drive axle, such that the combustion engine can be in drive connection with the front drive axle, the longitudinal drive shaft, and the rear drive axle. The rear drive axle is provided with a hybrid drive module that comprises at least one drive unit and a transfer gear set. The transfer gear set comprises an input, an output, and a first connection clutch provided operatively in between the input and the output, whereby the output of the transfer gear set is adapted to be in drive connection with the rear drive axle. The longitudinal drive shaft is provided with a second connection clutch and, the first connection clutch and the second connection clutch are hydraulically controlled and are connected to a same hydraulic circuit.

A powertrain is provided with a combustion engine, a front drive axle, a longitudinal drive shaft, and a rear drive axle, whereby the combustion engine is connected to a front drive axle, the longitudinal drive shaft, and the rear drive axle, such that the combustion engine can be in drive connection with the front drive axle, the longitudinal drive shaft, and the rear drive axle. The rear drive axle is provided with a hybrid drive module that comprises at least one drive unit and a transfer gear set. The transfer gear set comprises an input, an output, and a first connection clutch provided operatively in between the input and the output, whereby the output of the transfer gear set is adapted to be in drive connection with the rear drive axle. The longitudinal drive shaft is provided with a second connection clutch and, the first connection clutch and the second connection clutch are hydraulically controlled and are connected to a same hydraulic circuit.

A hybrid drive system has two sources of driving power: a non-combustion drive system to provide mechanical torque and rotation to a driveshaft, and an opposed-piston, internal combustion engine configured to provide energy for the non-combustion drive system.

A hybrid drive system has two sources of driving power: a non-combustion drive system to provide mechanical torque and rotation to a driveshaft, and an opposed-piston, internal combustion engine configured to provide energy for the non-combustion drive system.

A mining machine including a bi-directional electrical bus, a power source coupled to the bi-directional electrical bus, a motor coupled to the bi-directional electrical bus, the motor powered by energy available on the bi-directional electrical bus, a kinetic energy storage system coupled to the bi-directional electrical bus and a controller. The controller is configured to communicate with the kinetic energy storage system and the power source. Wherein the controller is configured to operate the kinetic energy storage system as a primary power source for the bi-directional electrical bus and to operate the power source as a secondary power source for the bi-directional electrical bus when the kinetic energy storage system cannot satisfy an energy demand on the bi-directional electrical bus.

A mining machine including a bi-directional electrical bus, a power source coupled to the bi-directional electrical bus, a motor coupled to the bi-directional electrical bus, the motor powered by energy available on the bi-directional electrical bus, a kinetic energy storage system coupled to the bi-directional electrical bus and a controller. The controller is configured to communicate with the kinetic energy storage system and the power source. Wherein the controller is configured to operate the kinetic energy storage system as a primary power source for the bi-directional electrical bus and to operate the power source as a secondary power source for the bi-directional electrical bus when the kinetic energy storage system cannot satisfy an energy demand on the bi-directional electrical bus.

A hybrid vehicle powertrain with a flywheel-based short-term energy storage system (SESS), including control and design optimization for a hybrid electric vehicle with the flywheel as a third energy storage system. The powertrain comprises three different propulsion systems including: an internal combustion engine (ICE); an electric motor (EM) with battery; and a flywheel and continuously variable transmission (CVT) that comprise the SESS.

A method for exiting from a recuperation phase in a parallel hybrid vehicle includes, in a first step, the vehicle is in a recuperation phase, started by means of a trigger, with a predefined recuperation driving demand, and, in a second step, the electric machine is brought to an increased rotational speed during the recuperation phase. In a third step, a phase for departing from the recuperation phase is started by means of a trigger, wherein, in this phase, the internal combustion engine is made available for coupling to the electric machine, such that a target rotational speed determined between the internal combustion engine to be connected and the electric machine for the connection to the transmission input is set, and in parallel, by means of an upshift, a highest possible gear ratio for the connection to the drivetrain is set, in order to satisfy a present driving demand. In a fourth step, the departure from the recuperation phase is completed.