Patent ID: 8910599
Filing Date: 2014-12-16
Classification: F01L,F02D,Y02T

Abstract:
1. Multi-cylinder internal combustion engine, comprising, for each cylinder: a combustion chamber, at least one intake conduit and at least one exhaust conduit ending up in said combustion chamber, an intake valve and an exhaust valve associated to said intake conduit and said exhaust conduit and each provided with respective return springs which push the valve towards a closed position, a camshaft for actuating the intake valves, by means of respective tappets, wherein each intake valve is controlled by the respective tappet against the action of the abovementioned return spring by interposing hydraulic means including a pressurized fluid chamber on which there is faced a pumping spring connected to the tappet of the valve, a solenoid valve which can be controlled between a closed condition and an open condition wherein said solenoid valve places said pressurized fluid chamber in communication with an exhaust channel to decouple the intake valve from the respective tappet and cause the quick closure of the intake valve due to the respective return spring, electronic control means, for controlling said solenoid valve to vary the opening instant and/or the closing instant and/or the lift of the intake valve as a function of one or more engine operative parameters, wherein said electronic control means are programmed for the differentiated control of the solenoid valve associated to each cylinder, said electronic means receiving signals indicating the operative performance of each cylinder during the operation of the engine and programmed to dynamically vary the amount of air taken in by each cylinder during the operation of the engine, through the differentiated control of said solenoid valves, so as to maintain the torques produced by the engine cylinders substantially identical to each other, means for sensing the rotation speed of the engine, a first electronic module for analyzing the signal emitted by said sensor means, adapted to dynamically obtain, during the operation of the engine, signals indicating the differences of the torque produced by the various cylinders, a second electronic module adapted to dynamically calculate, during the operation of the engine, with a closed loop procedure, as a function of the abovementioned signals indicating the differences of the torque produced by the various cylinders, a first correction regarding the amount of air taken in by one cylinder with respect to the other which should be implemented so as to obtain torques produced by the various cylinders substantially identical to each other means for sensing the engine load, a third electronic module adapted to statically calculate, with an open loop procedure, by means of previously memorized experimental maps, as a function of the signals indicating rotation speed of the engine and the load of the engine, a second correction regarding the amount of air taken in by one cylinder with respect to the other which should be implemented so as to obtain torques produced by the various cylinders substantially identical to each other, and a fourth electronic module which receives the correction signals from said second module and from said third module and processes them to emit a signal indicating a variation of the crank angle value corresponding to the opening of the intake valve, for each cylinder of the engine.