A two-gear and dual-motor driven hybrid power transmission device and a transmission method therefore are provided, belonging to the technical field of transmissions. An input end of an input shaft is connected to an engine power system, and an output end of the input shaft is connected to a front-end motor by means of a front-row planetary gear train. The front-row planetary gear train is connected to one end of a first clutch, another end of the first clutch is connected to an input end of an output shaft, and an output end of the output shaft is connected to a rear axle of a vehicle. The output shaft is connected to a rear-end motor by means of a rear-row planetary gear train, and the rear-row planetary gear train is connected to a second clutch and a third clutch.

Methods and systems are provided for a hybrid electric vehicle including a front-wheel drive system and a rear-wheel drive system. In one example, the rear-wheel drive system includes an internal combustion engine configured to drive rear wheels of the vehicle, and the front-wheel drive system includes a first electric motor and a second electric motor mounted directly to opposing sides of the engine. The first electric motor is coupled to a first reduction gearbox to drive a first front wheel of the vehicle, and the second electric motor is coupled to a second reduction gearbox to drive a second front wheel of the vehicle.

A power apparatus includes a drive motor, a motor shaft mechanically connected to a wheel of a vehicle, an engine, a crankshaft mechanically connected to the motor shaft and configured to output torque of the engine, a clutch disposed on a power transmission path between the crankshaft and the motor shaft, a controller configured to start-control the engine with the torque of the drive motor, and a magnetic deceleration mechanism which reduces torque of the drive motor necessary for starting the engine by magnetically reducing the rotational speed of the crankshaft during start control. When starting the engine, the controller excites the magnetic deceleration mechanism in a state where the clutch is released.

The present disclosure relates to a transmission for a vehicle having a power source, the transmission comprising: an input member for receiving power from the power source; an output member for outputting power to at least one component of the vehicle; at least one power split gear set having a plurality of members and operatively connected between said input member and said output member; an electromagnetic variator having a stator, an outer rotor and an inner rotor; wherein the inner rotor is at least partially received in the outer rotor and the electromagnetic variator is configured to provide variable torque transmission ratios between the outer rotor and inner rotor; and wherein said first and second rotors are each operatively connectable to different ones of said members of said power split gear set and are each operatively connectable to the input member to be driven thereby.

An electric vehicle includes: an intake device provided upstream of an intake pipe of an engine; a power transmission device configured to transmit a power of an electric motor to drive wheel; an electric-power control device configured to control an electric power transferred between a driving battery and the electric motor; and a charger configured to charge the driving battery with the electric power supplied from an external power supply. The electric motor and the power transmission device constitute at least a part of a driving apparatus. The driving apparatus and the electric-power control device constitute a mechanical-electrical integrated unit which is housed in a single casing and which is located in a position adjacent to the engine. The charger and the intake device are located on an upper side of the mechanical-electrical integrated unit in a vertical direction of the electric vehicle.

Disclosed in the present invention is a dual-structured power output apparatus of an electric drive and power system that provides a means for outputting both mechanical power and electrical power. It comprises dual motor/generators having two stator assemblies, two rotor assemblies and a power transmission unit all integrated into a single housing for easy mounting. The power transmission unit is disposed adjacent to the two motor/generators and coupled on both ends to rotating shafts mechanically linked to the rotor assemblies such that they are rotatable relative to each other. It function is to change the rotational speed and torque of at least one of the rotors in order to reduce weight and physical size of the apparatus, and thus significantly improving the power density and capability. The structure of the apparatus is well-suited to improve the performance and fuel efficiency of the prior art hybrid powertrain.

The present invention relates to a hybrid vehicle including an engine part, a power shaft part connected to the engine part and configured to transmit power, a shift part connected to the power shaft part and configured to shift power, a motor part disposed between the engine part and the shift part and configured to rotate the power shaft part, and a power supply part configured to supply electric power to the motor part.

Systems and methods for an electric axle. The electric axle includes, in one example, a first electric machine directly coupled to a sun gear of a planetary gear set and a second electric machine directly coupled to a carrier of a planetary gear set. The planetary gear set includes a set of planet gears that rotate on the carrier and an output gear that meshes with an input gear in a differential.

An electric vehicle in which a mechanical-electrical integrated unit including a driving apparatus and an electric-power control device is housed in a single casing and is located in a position adjacent to an engine including a supercharger, an air cleaner is located on one of opposite sides of the mechanical-electrical integrated unit which is remote from the engine in a width direction of the vehicle, and an intake pipe includes a portion which is located downstream of the air cleaner and upstream of the supercharger, wherein the portion of the intake pipe is located on an upper side of the mechanical-electrical integrated unit in a vertical direction of the vehicle, and straddles the mechanical-electrical integrated unit in the width direction.

Transition is made from a motor single-drive mode to a motor dual-drive mode while there is a margin in torque output from a motor MG2 with respect to rated torque. With this, the torque of the motor MG1 is changed slowly in the motor dual-drive mode, whereby it is possible to suppress the generation of vibration (shock) due to torsion of a damper and to compensate for a shortage of the torque of the motor MG1 due to slow change processing with an increase in torque from the motor MG2. As a result, it is possible to achieve both of reduction of a shock due to the torque of the motor MG1 and output of required torque to a drive shaft.