A method of operating a vehicle having an electric hybrid power system comprising a battery powered electric motor connected to drive the wheels of the vehicle and a combustion engine which may be releasably coupled mechanically to the electric motor. When so coupled the combustion engine may drive the vehicle and the electric motor may act as a generator to maintain a desired charge level in the batteries. In operation the power train is automatically controlled by a process controller to produce maximum fuel economy for the engine and to maintain the batteries at an acceptable charge level. Means are provided to apply the combined power of the electric motor and the combustion engine to the drive wheels for short duration peaking power. Means are also provided whereby the combustion engine may drive the electric motor to function as a generator and charge the batteries when the vehicle is stationary.
An operating method for a hybrid car which has an electric motor for driving the vehicle and an internal combustion engine for power generation. Using an operational expression including a motor output correction factor whose value is variably adjusted to different values depending on whether the engine is operated for battery charging or the engine is stopped, a required motor current supply that matches the vehicle operating state represented by an actual vehicle speed and an accelerator pedal depression depth is calculated, and the motor current supply is controlled in accordance with the result of the calculation. Consequently, the cruising range of the hybrid car is increased, and also the power performances and exhaust gas characteristics of the hybrid car are improved.
This power supply system for a D.C. electrical load, such as an illuminated sign, is normally energized by batteries. A central processing unit monitors the battery voltage and when it falls below a predetermined magnitude, the central processing unit then activates a starter motor which cranks an engine coupled to it. The central processing unit also actuates a valve and fuel pump to pass fuel to the engine. The engine drives an alternator which produces A.C. voltage which is then rectified by aa rectifier to recharge the batteries. When the batteries are fully charged the central processing unit stops the engine. The central processing unit employs a microprocessor chip to control operations of the system.
A capacity estimator determines a total maximum allowable power storage capacity for a work vehicle. A timer times the operating time of the work vehicle in an electrically propelled mode. A load manager, a driver or both decrease the available power to at least one of a drive motor of the work vehicle and an ancillary load over the operating time to conserve the available power stored for operating at least one critical work vehicle.
Method for potentiating an engine's power contribution to a hybrid electric vehicle's performance in a take-off operating condition is disclosed. Normally, fuel injection to, and ignition at the engine 511 are only commenced when the engine is operating at a speed exceeding the resonance speed of the drive train to reduce engine start harshness; such resonance speeds of the drive train being dictated, at least in part, by transmission backlash, softness and the like. During high driver acceleration demands, however, ignition and the injection of fuel is desirably started as early as possible to potentiate output power and acceleration.
A starter for a drive unit, such as an internal combustion engine, includes a stationary and a movable base element which form a linear motor. The movable base element is seated on a revolving shaft of the drive unit an inertia mass of a flywheel of the drive unit. The inertia mass of the flywheel is rigidly connected with the revolving shaft and is acted upon with sufficient torque required for the starting of the drive unit. Upon starting, the linear motor is switched over into a generator operation.
