A vehicle includes a powertrain configured to transfer energy to a tire and including both an engine and an electric machine. The vehicle also includes a controller configured to charge a traction battery with torque captured by the electric machine in excess of torque required to maintain the departure. The charging is in response to indication of departure from static friction between the tire and a surface during a line lock tire slip event powered by the engine.

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.

A prime mover arrangement includes a prime mover (23) including a first shaft (25) driven by the prime mover, a second shaft (27), and a speed and torque manipulator (29) connected to the first shaft (25) and to the second shaft (27), the speed and torque manipulator permitting manipulation between at least one non-one-to-one ratio or a plurality of different input/output ratios of speeds and torques input by the first shaft and output to the second shaft. A method is also disclosed.

A vehicle driveline and a method for synchronizing a flywheel and the vehicle driveline are provided. The vehicle driveline includes a power source, a primary clutch drivingly engaged with the power source, a primary transmission drivingly engaged with the primary clutch, a secondary transmission drivingly engaged with one of a portion of the primary clutch and an input of the primary transmission, a controller in communication with the secondary transmission, and a flywheel drivingly engaged with the secondary transmission. The vehicle driveline facilitates a transfer of energy to and from the flywheel based on at least one of a state of charge of the flywheel, a power requirement of the vehicle driveline, and a state of operation of the power source.

A transmission for an energy storage and recovery system is disclosed. A variable slip transmission and a clutch arranged to transmit drive while slipping. The level of torque transmitted through the slipping clutch is dependent on the clutch force but is independent of the clutch slip speed. Preferably the clutch is provided by a plurality of clutches connected in parallel in a range extender. When drive is transferred between clutches in parallel, the clutch forces of both clutches are controlled to maintain the total torque transmitted by the clutches. This reduces torque fluctuations at the energy source/sink during clutch transfer. Where there are two slipping clutches in series, one clutch is controlled to provide the required torque and the other clutch is controlled in response to a clutch slip speed. This helps to control the speed of rotation of the mass between the clutches.

A system for assisting propulsion of a vehicle by utilizing stored spring strain energy is disclosed. The propulsion assistance system includes a disc assembly, a caliper and friction brake assembly, a centrifugal clutch assembly, a torsion spring pan assembly, a rear bearing, a shaft, and a front bearing. The caliper and friction brake assembly holds the disc assembly until released, and slowly transfers energy from the torsion spring to the centrifugal clutch assembly, via the shaft. The disc assembly holds the shaft until released by actuating the caliper and friction brake assembly. Release of the friction brake in the caliper and friction brake assembly allows the disc and shaft to turn at variable speeds. Stored strain energy is passed through the shaft to the centrifugal clutch, which engages to assist the drivetrain and convert the strain energy to kinetic energy.

A system for assisting propulsion of a vehicle by utilizing stored spring strain energy is disclosed. The propulsion assistance system includes a disc assembly, a caliper and friction brake assembly, a centrifugal clutch assembly, a torsion spring pan assembly, a rear bearing, a shaft, and a front bearing. The caliper and friction brake assembly holds the disc assembly until released, and slowly transfers energy from the torsion spring to the centrifugal clutch assembly, via the shaft. The disc assembly holds the shaft until released by actuating the caliper and friction brake assembly. Release of the friction brake in the caliper and friction brake assembly allows the disc and shaft to turn at variable speeds. Stored strain energy is passed through the shaft to the centrifugal clutch, which engages to assist the drivetrain and convert the strain energy to kinetic energy.

A vehicle driveline and a method for synchronizing a flywheel and the vehicle driveline are provided. The vehicle driveline includes a power source, a primary clutch drivingly engaged with the power source, a primary transmission drivingly engaged with the primary clutch, a secondary transmission drivingly engaged with one of a portion of the primary clutch and an input of the primary transmission, a controller in communication with the secondary transmission, and a flywheel drivingly engaged with the secondary transmission. The vehicle driveline facilitates a transfer of energy to and from the flywheel based on at least one of a state of charge of the flywheel, a power requirement of the vehicle driveline, and a state of operation of the power source.

The present invention relates to methods of controlling kinetic energy recovery systems (KERS), to controllers, KERS, drivetrains and vehicles including the KERS and controllers. The KERS comprises an energy storage system. In an embodiment, a vehicle is provided with a first vehicle operating mode wherein the energy storage system has a first target state of charge, and with a second vehicle operating mode wherein the energy storage system has a second target state of charge. The first or second vehicle operating mode is selected and energy is transferred between the energy storage system and the vehicle in order to achieve the target state of charge associated with the selected vehicle operating mode. In other embodiments, the KERS includes a variable power transmission device adapted to transfer energy to and from the energy storage system. The energy storage system is maintained at suitable energy levels for the vehicle's driving conditions.

A work vehicle and energy storage device include an electric machine having a stator and a rotor. The rotor is configured to rotate from the flow of electrical current provided to the electric machine, rotate to store energy of the work vehicle, provide a rotor mass to an end of the work vehicle, and generate electrical current for the work vehicle from rotation of the rotor. The rotor mass is greater than a stator mass.