A drive device for a motor vehicle, with a first drive assembly, a second drive assembly, and a planetary gearing, via which the first drive assembly and the second drive assembly, which has a drivable axle of the motor vehicle, can be operatively connected. In this case, it is provided that the first drive assembly can be operatively connected to the planetary gearing via a first clutch coupling, and the drivable axle can be operatively connected to the planetary gearing via a second clutch coupling, and the second drive assembly and an auxiliary assembly are permanently operatively connected to the planetary gearing.

A hybrid electric vehicle is capable of maximizing energy efficiency during platooning, and a platooning control method is carried out on the hybrid electric vehicle. The method includes acquiring acceleration information and deceleration information of each of a plurality of vehicles traveling in a platoon form for platooning so as to realize a pulse-and-gliding traveling mode, determining a traveling order of the vehicles during the platooning based on the acceleration information, and determining a time at which to start a glide phase of a following vehicle in the determined traveling order based on a time at which a glide phase of a preceding vehicle starts using the acceleration information and the deceleration information.

A drive force control system configured to reduce a total energy consumption of a hybrid vehicle. The drive force control system calculates: an output power of the engine which can optimize a thermal efficiency given that the engine is operated at a best fuel point; and a required electric power to be supplied from a battery or to be generated by a control motor, which can adjust the drive power established by the output power of the engine to the required power. A power exchange between the control motor and the battery is interrupted if the required electric power to be supplied from the electric storage device or to be generated by the control motor is less than a first predetermined electric power.

A hybrid vehicle without having a torque converter that can be launched rapidly and accelerated sharply in a WOT condition. The hybrid vehicle comprises a motor operated by an engine torque to generate electricity, and a clutch for selectively transmitting power between the first motor and drive wheels. The hybrid vehicle is launched by engaging the clutch to deliver the engine torque to the drive wheels. A torque absorbing control is executed to reduce the engine torque delivered to the clutch by operating the motor by the torque of the engine, when the clutch is disengaged and an accelerator pedal is depressed.

A hybrid vehicle without having a torque converter that can be launched rapidly and accelerated sharply in a WOT condition. The hybrid vehicle comprises a motor operated by an engine torque to generate electricity, and a clutch for selectively transmitting power between the first motor and drive wheels. The hybrid vehicle is launched by engaging the clutch to deliver the engine torque to the drive wheels. A torque absorbing control is executed to reduce the engine torque delivered to the clutch by operating the motor by the torque of the engine, when the clutch is disengaged and an accelerator pedal is depressed.

A control apparatus of a hybrid vehicle including a temperature detection part detecting a temperature of a first motor-generator, and a microprocessor. The microprocessor is configured to perform controlling an internal combustion engine, the first motor-generator and a second motor-generator so that the hybrid vehicle travels in accordance with a required driving force, outputting a request for temperature increase suppression of the first motor-generator based on the temperature of the first motor-generator, and the controlling including controlling the internal combustion engine, the first motor-generator and the second motor-generator so that power generation amount of the first motor-generator is reduced, the second motor-generator generates an electric power by a regenerative torque and a driving force of the internal combustion engine increases by an amount corresponding to the regenerative torque when the request for the temperature increase suppression is output.

A control system for a hybrid vehicle configured to limit a thermal damage to a starting clutch without generating a shock. The control system is applied to a vehicle in which a prime mover includes an engine, a first motor, and a second motor. In the vehicle, the first motor is connected to the engine, and a first clutch and a second clutch are disposed between the engine and drive wheels. A controller executes a transient slip control to cause the second clutch to slip while bringing the slipping first clutch into complete engagement if a temperature of the first clutch is high. If an engine speed is changed during execution of the transient slip control, the first motor generates a collection torque to suppress the change in the engine speed.

A vehicle powertrain includes first and second power sources and a transmission assembly having first and second input members and an output member. The transmission assembly also includes a first multiple node planetary gear-set connected to both input members and a second multiple node planetary gear-set connected to the output member. The transmission assembly additionally includes a transmission housing retaining the first and second gear-sets. Furthermore, the transmission assembly includes a first torque-transmitting device for connecting one second gear-set node to the transmission housing and a second torque-transmitting device for connecting one first gear-set node to one second gear-set node. One first gear-set node is directly and continuously connected to one second gear-set node. The first and second power sources are connected to the first gear-set, and the first power source is connected to the first gear-set node not directly and continuously connected to the second gear-set.

Provided is an internal-combustion engine starting device in which a control unit controls a motor to realize a first starting mode of starting an internal-combustion engine by increasing a rotation speed of the internal-combustion engine to a predetermined first rotation speed NE1 by the motor and a second starting mode of starting the internal-combustion engine by increasing the rotation speed of the internal-combustion engine to a second rotation speed NE2 set higher than the first rotation speed NE1 and set based on a temperature of a coolant by the motor.

Provided is an internal-combustion engine starting device in which a control unit controls a motor to realize a first starting mode of starting an internal-combustion engine by increasing a rotation speed of the internal-combustion engine to a predetermined first rotation speed NE1 by the motor and a second starting mode of starting the internal-combustion engine by increasing the rotation speed of the internal-combustion engine to a second rotation speed NE2 set higher than the first rotation speed NE1 and set based on a temperature of a coolant by the motor.