An electric axle drive for a motor vehicle includes a first electric engine, which has a first rotor, a second electric engine, which has a second rotor, and a differential transmission with three shafts. The first rotor can be coupled with the input shaft such that torques originating from the first rotor are introduced into the differential transmission via the input shaft. A first switch element is configured to couple the second rotor with the first output shaft such that torques originating from the second rotor are introduced into the first output shaft. A second switch element is configured to couple the second rotor with the second output shaft such that torques originating from the second rotor are introduced into the second output shaft.

A hybrid power train structure for off-road vehicles (ATVs, UTVs and SSVs) uses an internal combustion engine (ICE) rotating a crankshaft through a continuously variable transmission (CVT) as a primary source of locomotion torque, but also includes a driving/generator motor which, in certain established conditions, can either provide an additional or alternative source of locomotion torque or can harvest electricity from the torque created by the internal combustion engine. The driving/generator motor is an axial flux motor of small size for its relative torque output, which can either be directly coupled to the CVT output shaft or, when additionally used as a starter motor for the ICE in an automatic ICE starting and stopping routine.

A drive axle for a motor vehicle includes two vehicle wheels, a first shaft by which a first of the vehicle wheels can be driven and a second shaft by which the second vehicle wheel can be driven. The drive axle also includes a first electric motor having a first stator and a first rotor, a differential gear by which the shafts can be driven and, via the shafts, the vehicle wheels can be driven by the first rotor of the first electric motor, and a second electric motor having a second stator and a second rotor. Only one of the shafts is assigned a clutch, by means of which the one shaft can be connected to the second rotor in a torque-transmitting manner, bypassing the other shaft and the differential gear.

An electric drive device includes a transmission with a first planetary gear set having a first element, a second element, and a third element. The transmission includes a second planetary gear set having a fourth element connected to the third element for conjoint rotation, a fifth element and a sixth element. A first output shaft is connected to the fifth element for conjoint rotation and a second output shaft is connected to the fourth element for conjoint rotation. A first electric machine has a first rotor that is or can be coupled to the sixth element such that torques provided by the first rotor can be introduced into the transmission via the sixth element.

A drive device for a car includes a first output shaft via which a first vehicle wheel of the car is drivable, a second output shaft arranged coaxially to the first output shaft via which a second vehicle wheel of the car is drivable, a differential transmission via which the output shafts are drivable, and three axial flux machines arranged coaxially to one another and coaxially to the output shafts. The three axial flux machines are a first axial flux machine via which the first output shaft is drivable by bypassing the differential transmission, a second axial flux machine via which the second output shaft is drivable by bypassing the differential transmission, and a third axial flux machine between the first axial flux machine and the second axial flux machine in the axial direction of the axial flux machines via which the output shafts are drivable via the differential transmission.

An electric drive device includes a transmission with a first planetary gear set having a first element, a second element, and a third element. The transmission includes a second planetary gear set having a fourth element connected to the third element for conjoint rotation, a fifth element and a sixth element. A first output shaft is connected to the fifth element for conjoint rotation and a second output shaft is connected to the fourth element for conjoint rotation. A first electric machine has a first rotor that is or can be coupled to the sixth element such that torques provided by the first rotor can be introduced into the transmission via the sixth element.

An electric drive system for a motor vehicle includes a first electric machine having a first rotor, a differential having a differential input shaft and a first differential output shaft and a second differential output shaft. The two differential output shafts are arranged coaxially with respect to the first rotor. A first side shaft is coupled to the first differential output shaft for conjoint rotation. A second side shaft is coupled, or is couplable, to the second differential output shaft for conjoint rotation. A second electric machine has a second rotor arranged coaxially with respect to the first rotor. A first switching element is configured to couple the first rotor to the first side shaft for conjoint rotation. A second switching element is configured to couple the second rotor to the second side shaft for conjoint rotation. The first rotor is coupled, or couplable, to the differential input shaft for conjoint rotation.

An electric axle drive for a motor vehicle includes a first electric engine, which has a first rotor, a second electric engine, which has a second rotor, and a differential transmission with three shafts. The first rotor can be coupled with the input shaft such that torques originating from the first rotor are introduced into the differential transmission via the input shaft. A first switch element is configured to couple the second rotor with the first output shaft such that torques originating from the second rotor are introduced into the first output shaft. A second switch element is configured to couple the second rotor with the second output shaft such that torques originating from the second rotor are introduced into the second output shaft.

Integrated vehicle structures are provided herein. An integrated vehicle structure can include an enclosure portion configured to house an electric motor and a plurality of extended portions extending from the enclosure portion. The enclosure portion and the plurality of extended portions can be load-bearing and configured to bear vehicle loads. The extended portions of the integrated vehicle structures can include a connection portion configured to connect with another load-bearing structure to at least receive or transmit loads. The plurality of extended portions can be configured to transfer vehicle loads along physically separate paths. A portion of the enclosure portion can define an opening configured to allow a drive shaft to connect the electric motor to a wheel. The enclosure portion can be configured with an opening for allowing the installation and removal of the electric motor.

The invention relates to an expansion vessel for a cooling circuit of an axial-flux electric motor, comprising: a receptacle suitable for containing a cooling liquid; a deformable membrane which delimits two compartments in the receptacle and which is suitable for matching the shape of the surface of the cooling liquid contained in a first of said compartments; and means for regulating the pressure in a second of said compartments.