The invention relates to the technology of gasoline direct injection (GDI) in automotive engines. In this context, the invention provides a method for maximizing the formation of deposits in injector nozzles of GDI engines, said method including at least one test cycle, each test cycle including at least one testing step in which a predetermined condition of speed and load of the GDI engine is maintained for a specified period of time, wherein, in said cycle, in at least one testing step, the engine speed is maintained between 1300 and 3700 rpm, the engine load is maintained between 10 and 80% and the specified period of time is from 10 to 200 minutes. Thus, the method of the invention is able to reproduce severe conditions of deposition of material in a few days, so that, in a short period of time, the test fuel can be assessed for tendency to form deposits.

The invention relates to the technology of gasoline direct injection (GDI) in automotive engines. In this context, the invention provides a method for maximizing the formation of deposits in injector nozzles of GDI engines, said method including at least one test cycle, each test cycle including at least one testing step in which a predetermined condition of speed and load of the GDI engine is maintained for a specified period of time, wherein, in said cycle, in at least one testing step, the engine speed is maintained between 1300 and 3700 rpm, the engine load is maintained between 10 and 80% and the specified period of time is from 10 to 200 minutes. Thus, the method of the invention is able to reproduce severe conditions of deposition of material in a few days, so that, in a short period of time, the test fuel can be assessed for tendency to form deposits.

A method and apparatus according to the invention is described, which in a first mode operates as an internal combustion engine delivering energy and in a second mode operates as a pulsed compression reactor converting electrical energy in the form of chemical compounds. In the second mode, at least one of the generated compounds is collected and temporarily stored.

A method and apparatus according to the invention is described, which in a first mode operates as an internal combustion engine delivering energy and in a second mode operates as a pulsed compression reactor converting electrical energy in the form of chemical compounds. In the second mode, at least one of the generated compounds is collected and temporarily stored.

Disclosed are an apparatus of injecting fuel for an engine and a method thereof.

The apparatus of injecting fuel for an engine includes: a main injector positioned adjacent to an exhaust valve and injecting the fuel into a combustion chamber of the engine; and an auxiliary injector positioned adjacent to an intake valve and injecting the fuel into the combustion chamber of the engine later than injection time of the main injector, wherein the fuel injected from the main injector and the fuel injected from the auxiliary injector are injected into the combustion chamber in a tumble direction.

Disclosed are an apparatus of injecting fuel for an engine and a method thereof.

The apparatus of injecting fuel for an engine includes: a main injector positioned adjacent to an exhaust valve and injecting the fuel into a combustion chamber of the engine; and an auxiliary injector positioned adjacent to an intake valve and injecting the fuel into the combustion chamber of the engine later than injection time of the main injector, wherein the fuel injected from the main injector and the fuel injected from the auxiliary injector are injected into the combustion chamber in a tumble direction.

An exothermic cutting rod comprising an ignition assembly portion and a main portion. The main portion may comprise a plurality of fuel rods and a rod housing that is configured to allow a flow of oxygen to the ignition assembly portion. The ignition assembly portion may comprise an ignition fuel housing and an ignition fuel, which is entirely contained within said exothermic cutting rod. The ignition fuel housing may have one or more windows that are configured to allow a heat source to ignite the ignition fuel, which then in turn ignites the fuel rods.

Methods and systems are provided for a fluid injection arrangement integrally formed in a cylinder head. In one example, a method may include molding a polymer composite structure as a single-piece with a fluid injection arrangement arranged integrally therein.

A reciprocating, internal combustion engine is capable of two modes of operation. The engine comprises three cylinders of substantially equal diameter. Each cylinder is provided with a piston. During operation, all pistons are synchronized and move in phase with one another. Valves are configured to selectively close paths between the second cylinder and two combustion chambers. Further valves are provided to selectively seal intake and exhaust channels leading to the two combustion chambers. A high efficiency combustion mode is achieved by increasing an expansion ratio through intake and compression of the fuel mixture in one cylinder and expansion in two cylinders. A high power combustion mode is achieved by compression and intake of the fuel mixture in two cylinders and expansion in one cylinder.

A two-stroke engine includes an engine block which defines a fuel/air transfer cylinder and a combustion cylinder. A piston is operative within the combustion cylinder in a two-stroke power producing manner while a fuel/air transfer piston is operative within the fuel/air transfer cylinder to inject fuel/air mixture into the combustion cylinder. The engine further includes a cylinder head which supports a plurality of movable valves to control the flow of air and fuel through the engine.