In order to be able to supply the traction drive on the one hand and the working unit (210) on the other hand with the energy required in each case independently of one another in a purely electrically driven vehicle (200), in particular a self-travelling working machine (200), a fully electric drive unit (100) is provided which supplies both, with a planetary gear unit (1) which is driven by two separately controllable electric machines (E1, E2) and thus, considered on its own, acts as a summing gear.

Because of an additional power output (NA1), which is coupled to one of the two E-machines (E1) and/or the corresponding drive input into the planetary gear (1) with a fixed transmission ratio, the working unit (210) can be supplied via this power output (NA1), while the speed of the traction drive is independently controlled via the differential speed between the sun gear (2) and the ring gear (3), which are driven by the two E-machines (E1, E2).

The sum of the planetary gear and the power output (NA1) thus acts primarily as a power divider gear.

In order to be able to supply the traction drive on the one hand and the working unit (210) on the other hand with the energy required in each case independently of one another in a purely electrically driven vehicle (200), in particular a self-travelling working machine (200), a fully electric drive unit (100) is provided which supplies both, with a planetary gear unit (1) which is driven by two separately controllable electric machines (E1, E2) and thus, considered on its own, acts as a summing gear.

Because of an additional power output (NA1), which is coupled to one of the two E-machines (E1) and/or the corresponding drive input into the planetary gear (1) with a fixed transmission ratio, the working unit (210) can be supplied via this power output (NA1), while the speed of the traction drive is independently controlled via the differential speed between the sun gear (2) and the ring gear (3), which are driven by the two E-machines (E1, E2).

The sum of the planetary gear and the power output (NA1) thus acts primarily as a power divider gear.

Systems and methods for driving an accessory of a vehicle. The system includes a power take-off (PTO) device, a mechanically driven accessory, a battery, and power conversion circuitry electrically connected to the battery. The system also includes a first electric motor mechanically coupled to the PTO device and a second electric motor mechanically coupled to the mechanically driven accessory. The system further includes an engageable mechanical connector that, when engaged, mechanically couples the PTO device and the mechanically driven accessory. The system performs operations including engaging the engageable mechanical connector when a speed of the PTO device is within a predetermined speed range; disengaging the engageable mechanical connector when the speed of the PTO device is outside the predetermined speed range; and based on disengaging the engageable mechanical connector, providing electric power to the second electric motor to generate and transfer mechanical energy to the mechanically driven accessory.

A system includes a PTO device that selectively couples to a driveline of a vehicle, a motor/generator electrically coupled to an electrical power storage system, and a shared load selectively powered by one of the driveline or the motor/generator. The PTO device further includes a coupling actuator that couples the shared load to the motor/generator at a first selected ratio in a first position, and couples the shared load to the driveline at a second selected ratio in a second position.

A system includes a PTO device that selectively couples to a driveline of a vehicle, a motor/generator electrically coupled to an electrical power storage system, and a shared load selectively powered by one of the driveline or the motor/generator. The PTO device further includes a coupling actuator that couples the shared load to the motor/generator at a first selected ratio in a first position, and couples the shared load to the driveline at a second selected ratio in a second position.

A hybrid drive train for a hybrid vehicle includes an internal combustion engine configured to drive the hybrid vehicle and an output shaft configured to provide torque to drive the hybrid vehicle, and a transmission which has a transmission input shaft. The hybrid drive train also includes a first electric machine by which the transmission input shaft can be driven, a second electric machine by which the output shaft can be driven to start the internal combustion engine, and an auxiliary unit configured to be driven by the second electric machine.

An excavator includes a lower traveling body, an upper turning body turnably mounted on the lower traveling body, actuators configured to drive driven portions including the lower traveling body and the upper turning body, a power storage mounted on the upper turning body and used as an energy source for driving the actuators, a cooling circuit configured to cool the power storage, and a fan mounted on the upper turning body and configured to blow air to a radiator and a condenser for cooling the radiator and the condenser. Further, the power storage is arranged such that the power storage is apart from a path in which air outside the upper turning body, by an operation of the fan, is introduced into inside the upper turning body, passes across the heat exchanging device, and is discharged to the outside of the upper turning body.

A machine is adapted for operation powered by any one of a plurality of interchangeable power sources. The machine may include an undercarriage configured for supporting ground engagement members that propel the machine and an upper structure rotatably supported on the undercarriage. The upper structure may include a swing frame, with the swing frame supporting an operator cab, any one of the plurality of interchangeable power sources, hydraulic components, electrical components, and a counterweight disposed at a first end of the swing frame. The counterweight may include a hollowed out portion facing toward the swing frame. The hollowed out portion of the counterweight may be centrally aligned with a center core portion of the swing frame configured for supporting any one of the plurality of interchangeable power sources, with the one power source being partially accommodated within the hollowed out portion of the counterweight.

A vehicle system includes an electric motor that also operates as a generator. A torque transfer mechanism is attached to the electric motor and a second torque transfer mechanism is connected via a disconnect mechanism. An AC compressor is attached to the first torque transfer mechanism via a clutch, which has an open position and a closed position. During recuperation, the second torque transfer mechanism is connected to the first torque transfer mechanism and the clutch is closed, and the compressor is driven by the motor. During stand-still, the second torque transfer mechanism is disconnected from the first torque transfer mechanism, and the compressor is driven by the motor. During drive operation, the second torque transfer mechanism is connected to the first torque transfer mechanism, and the clutch is open such that the compressor is not driven, but the system continues to provide cool air to the vehicle cabin.

An electric driveline system is provided. The electric driveline system includes a first electric machine and a second electric machine mechanically coupled to a transmission and a power take-off (PTO) assembly coupled to the first electric machine. The PTO assembly includes a first clutch coupled to a PTO gearset and designed to selectively disconnect a PTO from the first electric machine and the PTO gearset is mechanically coupled to the first electric machine.