The Kinetic Kar will have a large high pressure chamber filled with hydraulic fluid pressured up to 20 ton for the initial motion of the car. The pressure harvested by means of pumps, pistons, valves, and electrical gadget will be too high for the high pressure chamber. It is estimated that the car will move from zero to 20 miles in a matter of 2 seconds and run at up to 150 miles per hour for a mile before pressure tank is depleted totally. It will only take 3-4 seconds for pressure reservoir to replenish.

A kinetic energy recovery system (KERS) for a machine having a swing motor and/or an actuator includes a hydraulic motor/pump that can output pressurized fluid for operating at least one of: the swing motor and the actuator. A first shaft of the hydraulic motor/pump can be rotated by fluid returning from at least one of: the swing motor and the actuator back to the hydraulic motor/pump. Further, the KERS also includes a flywheel that can selectively couple with the first shaft with the help of a first clutch. The flywheel stores drive power generated by the hydraulic motor/pump from the return flow of fluid when the first clutch couples the flywheel with the first shaft of the hydraulic motor/pump. A gearing arrangement is coupled to the flywheel and can selectively engage with a second shaft associated with a prime mover of the machine with the help of a second clutch.

The embodiments disclose a database and file management system for real estate transactions including a real estate database comprising real estate information stored within files therein relating to a plurality real estate parcels, a server coupled to the plurality of real estate databases configured to receive the real estate information, a mobile automobile having an integrated navigation system coupled to the server, a graphical user interface having geographical mapping data displayed on the graphical user interface, wherein the graphical user interface is configured to allow a user to search and collect the real estate database with voice commands for real estate parcels of interest to the user that are in close proximity to a real-time location of the mobile automobile, and wherein the navigation system is further configured to compare and analyze the collected real estate parcels and display recommended real estate parcels for the user to select.

An energy storage arrangement includes a shaft for transmitting torque, a housing, an actuator configured to be axially moved, a freewheel disposed between the shaft and actuator and fastened to the shaft, the freewheel being configured to transmit no torque in one rotational direction, an energy store configured to store torque, a support element, an outer coupling between the housing and the support element, and an inner coupling between the support element and the shaft.

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.

Some implementations can include a supplemental regenerative braking system comprising a power take-off section to receive mechanical energy, and an electric clutch to engage the power take-off section and transfer mechanical energy from the power take-off section to an output of the electric clutch. The system can also include a roller stop assembly coupled to the output of the electric clutch and constructed to transfer mechanical energy from the output of the electric clutch, and a generator coupled to the roller stop assembly. The system can further include a flywheel coupled to the generator.

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).

A dual-clutch seven speed transmission arrangement comprises a dual-clutch gearbox, a drive machine and a transfer transmission. The dual clutch gearbox comprises first and second input shafts provided with first and second input clutches. The first input shaft is provided with at least first and second gearwheels, which are arranged to host three even and one reverse drive gear, and the second input shaft is arranged to host four odd drive gears. Furthermore, the first input shaft is a hollow shaft enclosing the second input shaft. The drive machine is a flywheel and the transfer transmission meshes with the first gearwheel that also hosts a fourth drive gear of the dual clutch gearbox.

A hybrid vehicle powertrain with a flywheel-based short-term energy storage system (SESS), including control and design optimization for a hybrid electric vehicle with the flywheel as a third energy storage system. The powertrain comprises three different propulsion systems including: an internal combustion engine (ICE); an electric motor (EM) with battery; and a flywheel and continuously variable transmission (CVT) that comprise the SESS.

A hybrid vehicle comprises an internal combustion engine, a transmission, at least one driving wheel rotationally connected to the transmission, and a coupling arrangement arranged between the internal combustion engine and the transmission, and controllable between a first state in which a drive shaft of the engine is rotationally connected to the transmission and a second state in which the drive shaft of the engine is rotationally disconnected from the transmission. The vehicle further comprises an energy recovery device connected to the coupling arrangement via a flexible driving member for allowing recovery and storage of energy recovered from deceleration of the at least one driving wheel. The vehicle may further comprise a sensor for sensing a parameter value indicative of desired deceleration, and a control unit for controlling the coupling arrangement to the second state when the sensed parameter value indicates desired deceleration of the hybrid vehicle.