A power system for a work vehicle, includes an intake arrangement configured to intake charge air; a fuel arrangement configured to provide at least one fuel; a compression ignition engine including a plurality of piston-cylinder sets configured to receive, ignite, and combust the at least one fuel from the fuel arrangement and intake gas that includes the charge air from the intake arrangement to generate mechanical power and exhaust gas; at least one compression ignition assistance apparatus associated with at least one of the intake arrangement and the fuel arrangement; and a controller coupled to command the compression ignition assistance apparatus, the intake arrangement, and the fuel arrangement such that, in an enhancement mode, the controller commands activation of the compression ignition assistance apparatus; and in a nominal mode, the controller commands or maintains deactivation of the compression ignition assistance apparatus.

A gaseous fuel engine system includes a quick start fuel system having a pressurized gaseous fuel supply, a fuel feed conduit and a quick start fuel admission valve. The fuel feed conduit is coupled to an intake conduit for the engine at a downstream fuel admission location. A main fuel system is coupled to the intake conduit at an upstream fuel admission location. The quick start fuel admission valve is electrically actuated to admit a pressured gaseous fuel from the pressurized gaseous fuel supply for quick starting the gaseous fuel internal combustion engine. The quick start fuel may have a fuel composition different than a fuel composition of the main fuel.

A method is provided for operating an internal combustion piston engine, including introducing air into a cylinder of the engine, compressing the air in a first compression stroke of the cylinder, providing fuel into the cylinder for a first combustion, with a portion of the oxygen in the compressed air as oxidant, in a first power stroke succeeding the first compression stroke, to produce residues including oxygen, compressing the residues in a second compression stroke succeeding the first power stroke, and providing, after the first combustion, fuel into the cylinder for a second combustion, with at least a portion of the oxygen of the residues as oxidant, in a second power stroke succeeding the second compression stroke, wherein the first compression stroke is repealed immediately after the second power stroke, and the introduction of air into the cylinder is done at the end of the second power stroke and/or at the beginning of the first compression stroke.

Methods and systems for starting and stopping a diesel engine are presented. In one example, a cetane enhancer is selectively mixed with diesel fuel to provide a cetane enhanced diesel fuel. A diesel engine may be supplied the cetane enhanced diesel fuel after an engine cold start to improve catalyst light off time and engine emissions.

In a fuel supply device for separating raw fuel into high-octane fuel and low-octane fuel and supplying the fuel, to arrange the structural components compactly and to facilitate sealing against fuel vapor, the fuel supply device (1) includes: a raw fuel tank (2) for storing raw fuel; a separator (6) provided inside the raw fuel tank to separate the raw fuel into high-octane fuel that contains a greater amount of components with high octane numbers than the raw fuel and low-octane fuel that contains a greater amount of components with low octane numbers than the raw fuel; and a high-octane fuel tank (5) provided inside the raw fuel tank to store the high-octane fuel separated from the raw fuel by the separator.

A fuel storage apparatus includes a fuel tank, a heat exchanger, a fuel pipe, and a medium pipe. The heat exchanger performs heat exchange between fuel inside the fuel tank and a heat exchange medium. The fuel pipe is provided inside the fuel tank and delivers the fuel to the heat exchanger. The medium pipe is provided outside the fuel tank and delivers the heat exchange medium to the heat exchanger. The heat exchanger includes a first joint and a second joint. The first joint is provided inside the fuel tank and is connectable to the fuel pipe. The second joint is provided outside the fuel tank and is connectable to the medium pipe.

A fuel tank containing a fuel and oil mixture is managed to determine if the fuel and oil mixture contains the correct ratio for a motor. The fuel tank containing a fuel and oil mixture is monitored. A fuel to oil ratio is selected for the motor. A combined viscosity of the fuel and oil mixture is calculated with respect to the fuel to oil ratio, and the temperature of the fuel and oil mixture. The combined viscosity is used to determine a predetermined range of the combined viscosity. The viscosity of the fuel and oil mixture within the fuel tank is measured as a measured viscosity. If the measured viscosity of the fuel and oil mixture does not correspond with the predetermined range, then a user may be alerted that the measured viscosity does not correspond with the predetermined range.

A fuel tank containing a fuel and oil mixture is managed to determine if the fuel and oil mixture contains the correct ratio for a motor. The fuel tank containing a fuel and oil mixture is monitored. A fuel to oil ratio is selected for the motor. A combined viscosity of the fuel and oil mixture is calculated with respect to the fuel to oil ratio, and the temperature of the fuel and oil mixture. The combined viscosity is used to determine a predetermined range of the combined viscosity. The viscosity of the fuel and oil mixture within the fuel tank is measured as a measured viscosity. If the measured viscosity of the fuel and oil mixture does not correspond with the predetermined range, then a user may be alerted that the measured viscosity does not correspond with the predetermined range.

Engine-control-apparatus includes: engine including injector injecting fuel into combustion-chamber and ignition-plug igniting air-fuel-mixture in combustion-chamber; and controller controlling injector/ignition-plug to switch combustion-mode based on required-torque of engine. Combustion-mode includes: SI-combustion of gasoline-fuel with ignition; first-HCCI-combustion of reformed-fuel without ignition, reformed-fuel being obtained by reforming portion of gasoline-fuel into peroxide; second-HCCI-combustion of reformed-fuel with ignition; and diffusion-combustion of reformed-fuel without ignition. Controller controls injector/ignition-plug to switch combustion-mode: to second-HCCI-combustion when required-torque is less than first-predetermined-value; to first-HCCI-combustion when required-torque is first-predetermined-value or more and less than second-predetermined-value larger than first-predetermined-value; to SI-combustion when required-torque is second-predetermined-value or more and less than third-predetermined-value larger than second-predetermined-value; and to diffusion-combustion when required-torque is third-predetermined-value or more.

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.