The patent presents Resilient In-Wheel-Motor (RIWM) technology with an enhanced scheme to control the regenerative power that can be delivered by hybrid and electric vehicles to be faster and with a lower total cost than other electric drive systems. Hub motors have been included a built-in inverter, control electronics, software and smart battery management that simplify the adoption of hybrid and electrified powertrains across a broad range of vehicles, based on add new performance feature to handle some existing challenges that will be mentioned bellow. The objective of the paper is to propose hub motor that is incorporated with high-speed dynamic energy storage as fast batteries, ultracapacitors and small flywheel units. That can achieve integrated hub motor system that will be reflected in enhanced structure to each component of electric vehicle systems, in addition to, Interior Search Algorithm (ISA) will be applied to control and optimize the performance parameters.

The invention relates to a control device for controlling an engine driven transport apparatus. The control device comprises a fitness apparatus having a base part and at least one movable part movable with respect to the base part for enabling a user to perform a physical exercise. The control device further comprises a sensor device for sensing a degree of physical exercise. The control device is arranged for controlling engine power of an engine of the transport apparatus at least partly based on the sensed degree of physical exercise. The fitness apparatus comprises a flywheel rotatably connected to the base part. The fitness apparatus is arranged for setting the flywheel into motion by means of at least one of the one or multiple movable parts. The sensor device is arranged to sense the degree of performed physical exercise at least partly by sensing a degree of motion of the flywheel.

The disclosure is related to a flywheel energy storage system comprising a casing, a shaft, a flywheel, and at least one electric motor assembly. The shaft is rotatably disposed in the casing. The flywheel comprises a hub and an annular part, the shaft is disposed through the annular part, the annular part is fixed to the shaft via the hub, and the annular part has at least one cavity. The electric motor assembly is accommodated in the cavity and comprises a first motor rotor and a motor stator. In the cavity, the first motor rotor is fixed on the shaft, and the motor stator is fixed to the casing and located between the first motor rotor and the annular part.

A rotary tilling apparatus separates a power transmission system starting from a flywheel to a passive movement device through an elastic coupler from another power transmission system starting from the flywheel to a rotor of a motor generator, and thereby reduces a load applied to the rotor and prevents the power transmission system of the passive movement device from providing a negative effect to an engine and the rotor. A parallel hybrid power transmission mechanism includes an engine, a crank shaft disposed on the engine, a motor generator, a passive movement device configured to receive a motive power of the motor generator, an input shaft disposed on the passive movement device, a flywheel coupled to the crank shaft, an elastic coupler configured to couple the flywheel to the input shaft, and a rotor disposed on the motor generator and coupled to the fly wheel.

A hybrid module for a motor vehicle drive train includes an electric machine, a rotor bearing carrier, a first bearing, a second bearing, and an intermediate shaft. The electric machine has a rotor unit with a rotor. The roller bearing carrier is for rotatably supporting the rotor unit. The intermediate shaft is for transmitting a torque between an internal combustion engine and a transmission or an output. The internal combustion engine and, the transmission or the output, can be connected to the hybrid module. The intermediate shaft is rotatably supported by the first bearing and the second bearing. The first bearing or the second bearing is supported on the rotor bearing carrier, supported or on the rotor unit, or is arranged to be supported on an output shaft of the internal combustion engine.

Systems and methods for improving operation of a stop/start vehicle are presented. In one example, an engine throttle position is adjusted in response to whether or not a starter engages a flywheel during engine stopping. The throttle may be adjusted to a more open position if the starter engages the flywheel or to a more closed position if the starter does not engage the flywheel.

A kinetic energy recovery system (KERS) is provided. The KERS (1) comprises a first speed-up gear arrangement (12) having an input (10) connectable to a vehicle powertrain. The KERS further comprises a hydraulic variator made up of first and second bent axis motors (20,22) fluidly connected to one another, wherein at least the first motor (20) is a variable displacement motor, and the first motor (20) is connected to an output of the first speed-up gear arrangement (12). A second speed-up gear arrangement (34) has an input connected to the second motor (22). At least one flywheel (52) is connected to an output of the second speed-up gear arrangement (34), where the at least one flywheel is located in a vacuum within at least one flywheel chamber (58).

An electric drive assembly for a motor vehicle comprises a high-speed electric machine with a nominal rotational speed of at least 20,000 revolutions per minute and with a high-speed rotor that can be used as a flywheel mass for storing kinetic energy; a superimposed transmission having a drive element, a regulating element and a driven element, wherein the drive element is drivable by an electric machine around a drive axis, wherein the regulating element is rotatable around a regulating axis and wherein the driven element is drivingly connected to the regulating element and the drive element; an electromagnetic regulating device having a stator and a rotor that is connected to the regulating element in a rotationally fixed way, wherein by means of magnetic forces acting in the circumferential direction between the stator and the rotor, a regulating moment can be transmitted to the rotor, wherein the magnetic forces are variably adjustable.

The invention provides a powertrain for an electric vehicle, and an electric vehicle as such. The powertrain has an electric motor and a drivetrain for transmitting rotary power from the electric motor to at least one of the vehicle wheels. A mechanical rotary transmission is provided in association with a flywheel. The mechanical rotary transmission is controllable to transmit power in a direction from the vehicle wheels to the flywheel and further transmit power in the reverse direction. Power from both the electric motor and the flywheel is concurrently used to accelerate the vehicle. The vehicle kinetic energy is recovered and stored at the flywheel during vehicle deceleration. The motor vehicle has at least one battery unit to supply the electric motor. The battery unit is removable from the vehicle, without tools, and is portable so that it is carried away from the vehicle for charging.

The present invention provides a system and method for economically using compressed air as automobile power source, comprising: a compressed air power device, which includes automobile air storage tubes (1) to store a sufficient amount of high-pressure compressed air and a cylinder-combined engine consisting of the first and second cylinders (9)(10), and which can make full use of the compressed air to produce driving power; a mechanism to produce, store and provide high-pressure compressed air, which includes a boiler-type high-pressure compressed air producing and storing device, abbreviated as boiler-type HCAPS device (4), to be able to use electricity during periods of low energy demand (off-peak) such as at night simultaneously recovering the by-produced heat for central heating, and pressurizing and inflating into the automobile air storage tubes (1) during daytimes; brake energy recovery and regeneration devices, which include a spring reserving-releasing device and/or a compressed air reserving-releasing device to save the compressed air in the automobile air storage tubes (1) for saving the driving power; an inner gear ring assembly, which includes an inner gear ring (2) gearing meshing with inner acting gears (45), with the first and second accelerating gears (72)(92), with a flywheel front inner meshing gear (48) and reset gears (46), for transmitting torque and mixing/outputting power; some clutch transmission devices and a controller, which controls orderly coordinated operation of devices and mechanisms.