Abstract: An electromagnetic fuel injector comprises a body with a fuel inlet and a fuel outlet and a base that comprises a valve seat connected to the body. A moveable valve assembly comprising an armature and a valve outlet member is disposed at the fuel outlet for controlling the flow of fuel from the outlet. Positioned between the armature and valve outlet member is a dampening device that acts on the moveable valve assembly to reduce bounce of the valve outlet member at the valve seat. An electromagnetic fuel injector comprises a body with a fuel inlet and a fuel outlet and a base that comprises a valve seat connected to the body. A moveable valve assembly comprises an armature connected to a valve outlet member that includes a pintle and a ball element that is disposed at the fuel outlet to control the flow of fuel from the outlet. At least one spring, positioned between the armature and the valve outlet member, acts on the moveable valve assembly to reduce bounce of the valve outlet member at the valve seat.

Abstract: An electromagnetic fuel injector comprises a body with a fuel inlet and a fuel outlet and a base that comprises a valve seat connected to the body. A moveable valve assembly comprising an armature and a valve outlet member is disposed at the fuel outlet for controlling the flow of fuel from the outlet. Positioned between the armature and valve outlet member is a dampening device that acts on the moveable valve assembly to reduce bounce of the valve outlet member at the valve seat. An electromagnetic fuel injector comprises a body with a fuel inlet and a fuel outlet and a base that comprises a valve seat connected to the body. A moveable valve assembly comprises an armature connected to a valve outlet member that includes a pintle and a ball element that is disposed at the fuel outlet to control the flow of fuel from the outlet. At least one spring, positioned between the armature and the valve outlet member, acts on the moveable valve assembly to reduce bounce of the valve outlet member at the valve seat.

Abstract: An actuator (10) for a fuel injector having a dual coil solenoid. The solenoid coils (14, 16) are connected in parallel and have windings that are wound in opposite directions. The actuator (10) of the present invention defines three air gap surfaces (22, 24, 26), one of which (24) is located in the space shared between the two coils (14, 16). The shared air gap surface (24) has a high flux density due to the additive nature of the magnetic forces between the oppositely wound coils (4, 16). The dual-coil solenoid of the actuator (10) of the present invention creates a very high force and a low inductive load which results in fast injector response times.

Abstract: A fuel delivery module integrates a fuel rail, with its associated connections, features and components, with the injectors for one bank of a direct injection engine. When the module is secured to the engine, loading springs between the inlet ends of the injectors and abutments in the mounting recesses accommodate variations in manufacturing and assembly tolerances to provide adequate but not excessive loading of the injectors against associated seats of the engine. Manufacturing and assembly costs are reduced by the use a module with injectors pre-installed. Also, the module may be pretested in a suitable test fixture prior to installation to assure proper flow and spray development from each of the injectors. The module may integrate other components also, such as intake air passages, EGR passages and coolant passages and their associated components. Various examples of injector loading springs are described.

Abstract: A vehicle fuel system has an integrated fuel rail and fuel pump that supplies high pressure fuel directly to the injectors mounted on the engine. The pump is a double acting single piston pump that has two pumping chambers formed co-axially in a single cavity. One pumping chamber is twice the size of the other pumping chamber thereby producing an output flow equal to one half the volume of the larger pumping chamber during each stroke. The smaller pumping chamber communicates with a co-axial fuel rail portion of the cavity. A plurality of outlet ports, one for each injector, are disposed in fluid communication with the fuel rail portion of the cavity.

Abstract: An electromagnetic fuel injector has an upper, middle and lower body. A solenoid and guide tube are mounted within the middle body. A plug is mounted within the guide tube. The armature moves from its lower position when the solenoid is not energized to its upper position. There are two air gaps which are closed when the armature moves to its upper position, one between the armature and a stop shoulder on the middle body and the other between the armature and the plug. During assembly, the plug is inserted partially into the guide tube. Next, the armature is inserted into the guide tube. The armature is pushed upward until it contacts a stop on the middle body. The armature and the plug then stop moving. Because the plug is in a tight fitting relationship with the upper body, it remains in place when the armature is moved back to its lower position. This positions the plug such that the two air gaps are equal. The second air gap is positioned between the top and bottom of the solenoid.

Abstract: A damper control valve includes a body having an inlet, a main outlet and a pilot outlet with a valve disc normally substantially closing the inlet off from the outlet. The valve disc has a continuously open orifice that permits restricted fluid communication between the inlet and the pilot outlet. An armature normally closes the pilot outlet. The armature is movable by a coil to open the pilot outlet and in response, the valve disc independently moves in response to a pressure differential to open the main outlet to the inlet.