The present invention is a system and method for adapting and modifying an existing mono-fuel delivery system for an internal combustion engine to run as a bi-fuel system by reusing and repurposing OEM components of the mono-fuel system. The bi-fuel system makes use of an integration plate that may be mounted to the system fuel filter in substantially the same location as the fuel filter is mounted in the mono-fuel configuration. The integration plate also may deliver either fuel types into the existing engine fuel intake port thus the system does not require the creation of a secondary fuel intake port for the secondary fuel. The integration plate may also be situated such that it minimizes the space it must use within the engine compartment and it may use the preexisting engine mounting points designed for the fuel filter in the mono-fuel system.

A fuel metering system for an internal combustion engine having a fuel injection timing unit to indicate a timepoint during one or more engine strokes, a fuel metering element have a predetermined full stroke volume for metering fuel into an air-fuel mixing location during one or more of the engine strokes, and a fuel metering element controller to control the delivery of fuel by causing the fuel metering element to deliver one of a full stroke volume and a fraction of a full stroke volume to achieve a desired AFR. In some embodiments, power generator circuitry is provided to harvest power from the ICE to power at least one of the fuel injection timing unit, the fuel metering element, and the fuel metering controller.

Engine control apparatus includes: engine including injector configured to inject fuel into combustion chamber and ignition plug configured to ignite air-fuel mixture of fuel and air in combustion chamber; temperature sensor configured to detect temperature of engine; and controller configured to control injector based on temperature detected by temperature sensor. Fuel injected by injector is at least one of gasoline fuel and reformed fuel obtained by reforming part of gasoline fuel into peroxide. Controller controls injector so as to inject gasoline fuel at first target injection timing when temperature detected by temperature sensor exceeds predetermined temperature at starting of engine, and controls injector so as to inject reformed fuel at second target injection timing retarded from first target injection timing when temperature detected by temperature sensor is equal to or lower than predetermined temperature.

A method for controlling an internal combustion engine whereby, in a piston-cylinder unit provided with a prechamber, the quantity of propellant gas supplied to the prechamber is adjusted to regulate the operating characteristics of an inlet and/or outlet valve of the piston-cylinder unit.

Engine control apparatus includes: engine including injector configured to inject fuel into combustion chamber and ignition plug configured to ignite air-fuel mixture of fuel and air in combustion chamber; temperature sensor configured to detect temperature of engine; and controller configured to control injector based on temperature detected by temperature sensor. Fuel injected by injector is at least one of gasoline fuel and reformed fuel obtained by reforming part of gasoline fuel into peroxide. Controller controls injector so as to inject gasoline fuel at first target injection timing when temperature detected by temperature sensor exceeds predetermined temperature at starting of engine, and controls injector so as to inject reformed fuel at second target injection timing retarded from first target injection timing when temperature detected by temperature sensor is equal to or lower than predetermined temperature.

The present invention is a system and method for adapting and modifying an existing mono-fuel delivery system for an internal combustion engine to run as a bi-fuel system by reusing and repurposing OEM components of the mono-fuel system. The bi-fuel system makes use of an integration plate that may be mounted to the system fuel filter in substantially the same location as the fuel filter is mounted in the mono-fuel configuration. The integration plate also may deliver either fuel types into the existing engine fuel intake port thus the system does not require the creation of a secondary fuel intake port for the secondary fuel. The integration plate may also be situated such that it minimizes the space it must use within the engine compartment and it may use the preexisting engine mounting points designed for the fuel filter in the mono-fuel system.

A method of reducing NO.sub.x in the exhaust of a diesel engine having at least one combustion chamber by introducing NH.sub.3 into the diesel engine prior to a combustion event, at least some of the NH.sub.3 injected reducing the amount of NO.sub.x in the exhaust of the diesel engine, whereby the exhaust will contain an amount of NO.sub.x that is less than if no injection of NH.sub.3 was used, and will also contain an amount of NH.sub.3 that is less than the amount injected into the diesel engine, the rest of the NH.sub.3 being consumed during the combustion event and the reduction of NH.sub.3.

The invention relates to a device for dispensing a liquid additive into a fuel circulation circuit (2) for an internal combustion engine, in particular for an engine equipping a vehicle, said device comprising: a tank (26) containing the additive, an enclosure (24) communicating with the fuel circulation circuit (2) and inside which the tank (26) containing the additive is inserted, means for injecting additive connected to the tank (26) and the fuel circulation circuit (2) and making it possible to dispense the additive in the fuel circulation circuit (2), and control means for controlling the injection means.

An electronic control unit includes a seat temperature calculating unit, a supply amount control unit, and a concentration acquiring unit. The seat temperature calculating unit calculates a simulated temperature of an exhaust valve seat. When the simulated temperature of the exhaust valve seat becomes equal to or higher than a threshold temperature, the supply amount control unit starts fuel increase control of increasing a lower limit value of an amount of fuel to be supplied into a cylinder to a larger value than that before the simulated temperature becomes equal to or higher than the threshold temperature. The concentration acquiring unit acquires an ethanol concentration of the fuel. In the fuel increase control, the supply amount control unit makes the amount of increase in the lower limit value larger as the ethanol concentration of the fuel acquired by the concentration acquiring unit is higher.

Disclosed is a turbocharged internal combustion piston engine system that includes a waste-heat recovery system. The waste-heat recovery system involves injecting heated water into the cylinders during combustion to increase engine power and efficiency and to reduce emissions. The engine can be a spark or compression ignition type of engine, and can utilize fuels including but not limited to diesel, natural gas, gasoline, and ethanol. The engine also includes a turbocharger that utilizes a turbine in the exhaust gas flow to provide power to a compressor in the intake air flow to pressurize the intake air and provide additional charge flow to the engine to increase engine output.