An apparatus and a method for testing a fuel injector nozzle with a tip having at least one fuel outlet are provided. The apparatus comprises a test chamber, a holder for holding the fuel injector nozzle such that the outlet is within the test chamber, a fuel supply arrangement for supplying fuel to the fuel injector nozzle, a sensor having a sensor surface for sensing an atomized fuel spray supplied by the fuel injector nozzle through the fuel outlet and movement module for moving the sensor. The movement module is configured to position the sensor surface of the sensor at a plurality of positions corresponding to a surface of a sphere having a radius R and a center point C adjustable to match a center point c.sub.t of the tip of the fuel injector nozzle or a center point c.sub.f of an orifice of the fuel outlet.

An apparatus and a method for testing a fuel injector nozzle with a tip having at least one fuel outlet are provided. The apparatus comprises a test chamber, a holder for holding the fuel injector nozzle such that the outlet is within the test chamber, a fuel supply arrangement for supplying fuel to the fuel injector nozzle, a sensor having a sensor surface for sensing an atomized fuel spray supplied by the fuel injector nozzle through the fuel outlet and movement module for moving the sensor. The movement module is configured to position the sensor surface of the sensor at a plurality of positions corresponding to a surface of a sphere having a radius R and a center point C adjustable to match a center point c.sub.t of the tip of the fuel injector nozzle or a center point c.sub.f of an orifice of the fuel outlet.

An apparatus to detect fluid sealing of fuel tank includes a flow inlet and a flow outlet. The apparatus also includes a first flow path, fluidly connected between the flow inlet and the flow outlet, where the first flow path includes a fluid pump which pressurizes fluid from the flow inlet, the first flow path including an on-off valve to allow flow from the flow inlet to the flow outlet, the first flow path including a pressure sensor, and a flow control orifice located in the first flow path between the check valve and the flow outlet. The apparatus also includes a second flow path fluidly connected between the flow inlet and the flow outlet, the second flow path including an on/off valve located therein.

A method for determining an effective injection time of a valve having a coil drive includes determining an opening time of the valve, determining a closing time of the valve, and determining the effective injection time of the electric actuation of the valve for an injection operation based on the defined opening time and the defined closing time.

A method for determining an effective injection time of a valve having a coil drive includes determining an opening time of the valve, determining a closing time of the valve, and determining the effective injection time of the electric actuation of the valve for an injection operation based on the defined opening time and the defined closing time.

A fuel injector (10) comprising a needle (16) that can move between an entirely open position (PO) and a closed position (PF) is provided with a device (82) for identifying the position of the needle, in which an electrical circuit (84) is closed in the two extreme positions (PO, PF), the needle (16) being in electrical contact with the ground (G), the circuit (84) being open in any other intermediate position (Pi) of the needle (16), the needle (16) not being grounded (G).

A fuel injection feedback system comprises a light source disposed inside a fuel injector, an optical sensor disposed inside the fuel injector, and a computing device electronically connected to the optical sensor. The light source is a device configured to emit light capable of being reflected by cavitation. The light source could be disposed on or within the needle or nozzle of the fuel injector, or at a variety of other locations inside the fuel injector. The optical sensor is configured to detect an intensity of light caused by receiving light reflected from cavitation occurring inside the fuel injector.

A driveshaft assembly, for example in an Electronic Unit Injector, Unit Injector or Electronic Unit Pump testing machine, wherein an indexing arrangement, such as complementary external and internal splines, enables a cam to be mounted on a shaft at a number of discreet positions, each providing a different offset of a central axis of the base cylinder section from a central axis of the shaft, each position providing a different maximum lift value of a plunger in contact with the cam, directly or via a rocker arm.

A driveshaft assembly, for example in an Electronic Unit Injector, Unit Injector or Electronic Unit Pump testing machine, wherein an indexing arrangement, such as complementary external and internal splines, enables a cam to be mounted on a shaft at a number of discreet positions, each providing a different offset of a central axis of the base cylinder section from a central axis of the shaft, each position providing a different maximum lift value of a plunger in contact with the cam, directly or via a rocker arm.

An apparatus and a method are provided for an inline fuel pump for conveying liquid fuel from a fuel source to an intake of an internal combustion engine. The inline fuel pump operates with various fuels, such as gasoline, diesel, biodiesel, gasoline-ethanol blends, as well as commonly used fuel additives. The inline fuel pump comprises an inlet placed into fluid communication with the fuel source. An outlet of the inline fuel pump is placed into fluid communication with the intake. An electric motor coupled with an internal liquid pump convey liquid fuel from the inlet to the outlet. The electric motor and the internal liquid pump are housed within a sealed case configured to protect the electric motor and the liquid pump from an exterior environment. Power leads convey electrical power from an electrical system of the vehicle to the electric motor.