Disclosed in the present invention is a tandem starter-generator construction that includes an induction motor-generator, a permanent magnet motor-generator and power transmission unit disposed adjacent to the motor-generators. The induction motor-generator is utilized predominantly as a motor to provide mechanical power at relatively high efficiency as a motor, and as a generator to provide electrical power during regenerative braking. The permanent magnet motor-generator is used predominantly as a generator for very high efficiency power conversion and to capture additional electrical power during regenerative braking to compensate for the regenerative energy captured at lower efficiency by the induction motor-generator. Accordingly, the tandem motor-generator construction disclosed herein overcomes the drawbacks of low efficiency of an induction motor-generator operating in regenerative mode and a permanent magnet motor-generator magnetic drag losses during periods of non-utilization at high speeds in order to improve fuel efficiency of a parallel hybrid vehicle.

In an electrical traction drive for a vehicle comprising at least two individual wheel drives that are to be controlled independently of each other, the drives are able to be operated redundantly in order for an emergency operating function to be implemented.

A rotary electric machine includes a rotor, and a rotor shaft connected to the rotor so as to be integrally rotatable and provided with a coolant flow path through which a coolant flows. The rotor shaft includes a first rotor shaft and a second rotor shaft which is inserted into the first rotor shaft and is connected to the first rotor shaft so as to be integrally rotatable. The first rotor shaft includes an opposing surface opposed to a tip surface of the second rotor shaft, and a coolant supply path extending radially from a vicinity of the opposing surface. A gap is provided between the opposing surface of the first rotor shaft and the tip surface of the second rotor shaft. The gap constitutes a connection flow path connecting the coolant flow path and the coolant supply path.

An engine system comprising: a housing having an accommodating cavity; a crankshaft part, a speed change mechanism and a transmission shaft are provided in the accommodating cavity; and a first motor and a second motor are located outside the accommodating cavity and provided on the housing. The crankshaft part is provided in the accommodating cavity and outputs first power. The first motor comprises a first motor shaft which is connected to an output end of the crankshaft part to convert the first power into electric energy. The second motor comprises a second motor shaft and is configured to output second power according to electric energy. The speed change mechanism is drivingly connected to the second motor shaft without connecting the output end of the crankshaft part. The transmission shaft is connected to an output end of the speed change mechanism. Also disclosed is an all-terrain vehicle.

The inventors' findings relate to a transmission for vehicles, comprising an input side configured for being coupled to a prime mover and an output side configured for being coupled to a driven element wherein the transmission comprises an electromagnetic torque converter (EMTC), wherein the EMTC has at least two output paths, namely the first output path coupled to a gear box which is preferably configured for being coupled to a drive shaft of the vehicle, and a second output path which is configured to be coupled to an auxiliary power provider. The inventors' findings also relate to a vehicle driveline comprising said transmission. Furthermore, the inventors' findings also relate to a vehicle comprising said vehicle driveline.

A drive device for a hybrid vehicle includes an engine, a first motor, a power split device, a second motor, a first speed reduction unit, a second speed reduction unit, and a differential gear. The first motor generates electric power. The power split device splits drive power output from the engine to the first motor side and a drive wheel side. The second motor increases or decreases torque output from the power split device and to be transmitted to the differential gear. The second motor is coupled to a sun gear. The first speed reduction unit is coupled to the sun gear. The second speed reduction unit is provided between the first speed reduction unit and the differential gear. The differential gear transmits torque to the drive wheel.

An oblique motor of a vehicle including an engine and a transmission includes a stator having a diameter formed to be smaller toward the engine; a rotor disposed inside the stator and having a diameter formed to be smaller toward the engine; a cooling member fixed to the stator and configured to cool heat generated from the stator; and a housing enclosing the cooling member and fixedly installed between the engine and the transmission.

The present invention relates to an automobile hybrid power generator system including a double-acting power generation unit and, more specifically, to an automobile hybrid power generator system including a double-acting power generation unit which not only allows the double-acting power generation unit to store mechanical power of an engine as electrical energy and supply electrical energy required to drive an automobile, but also, as the occasion demands, allows the double-acting power generation unit to assist power of the engine due to the characteristics of the double-acting power generation unit, and thus increases the fuel consumption efficiency of the automobile and improves the fuel efficiency thereof.

A multi-functional electromechanical device is provided. The device includes a first assembly that includes: 1) at least one motor/generator set configured to act as both: i) a motor to provide rotational assistance to an engine to which it is connected by converting electrical energy from an accumulator set to rotational energy, and ii) a generator configured to act to generate electrical energy to run parasitic devices of the engine to which it is connected, to store in an accumulator set, or to act in both of these capacities, using rotational energy provided by the engine or the transmission; and 2) a second assembly that includes: at least one energy distributor configured to: i) use rotational energy provided by at least one motor/generator set to assist an engine to which it is connected or a transmission to which it is connected to rotate, or ii) use rotational energy of an engine or a transmission to which it is connected to provide rotational energy to at least one motor/generator set to convert the rotational energy into electrical energy for use by parasitic devices or for storage in an accumulator set.

A second motor is connected to a shaft. A power transmission mechanism is configured to transmit power from the shaft and power from a second motor to a driving wheel. A power switching mechanism is connected to a first motor, the shaft, and an internal combustion engine. The power switching mechanism is switchable to a first state in which power transmission between the first motor and the shaft is allowed, a second state in which power transmission between the first motor and the shaft is inhibited and power transmission between the first motor and the internal combustion engine is inhibited, and a third state in which power transmission between the first motor and the internal combustion engine is allowed.