Abstract: Exemplary illustrations are provided of a common rail system for an internal combustion engine, having a rail for fuel and an injector for the purpose of injecting the fuel into a working space of the internal combustion engine, said injector having a fluid connection to said rail via a high-pressure conduit. The high-pressure conduit may have a high-pressure component with an individual reservoir, and the high-pressure conduit and/or the rail may have a pressure measurement device. The pressure measurement device may be coupled to a local logic and storage device of a decentralized, local electronic device which is designed for the purpose of locally analyzing and storing measurement data of the pressure measurement device, e.g., injector data and/or rail data, and the pressure measurement device is connected to the central electronic device via a bus, with the local logic and storage device connected between the same.

Abstract: A method for torque control of an internal combustion engine includes a pressure sensor that is associated with at least one, but at the most two cylinders of the internal combustion engine, whereby an cylinder internal pressure for the cylinder associated with the pressure sensor is detected. The method carries out an adjustment of injection characteristics for the injectors allocated to the individual cylinders of the internal combustion engine by way of a method which is independent from the detected cylinder pressure. A torque control for the internal combustion engine is performed based on the detected cylinder pressure.

Abstract: The invention relates to a method for adjusting an injection behavior of injectors in an internal combustion engine, including the following steps: switching off an injector; detecting a crank angle signal of the internal combustion engine; transforming the crank angle signal into the frequency range by way of a discrete Fourier transformation; detecting and storing a quantity of the harmonic of the 0.5th order of the Fourier transform of the crank angle signal, and assigning the quantity to the switched-off injector; switching on the switched-off injector; performing the previous steps sequentially for all injectors of the internal combustion engine; forming an average value of the stored quantities with respect to all injectors, and correcting the control of the injectors using a deviation from the average value of a quantity associated with an injector that is to be corrected.

Abstract: The invention relates to a method for detecting the failure of injectors in an internal combustion engine, comprising the following steps: measuring a crank angle signal; transforming the crank angle signal into the frequency range by means of a discrete Fourier transformation; switching off each injector once and in a sequential manner; detecting and storing an angle of the harmonic of the 0.5th order of the Fourier-transformed crank angle signal for each switched-off injector once and in a sequential manner; continuous detection and storage of an angle and an amount of the harmonic of the 0.

Abstract: The invention relates to a method for torque control of an internal combustion engine, wherein a pressure sensor is associated with at least one, but at the most two cylinders of the internal combustion engine, and wherein an cylinder internal pressure for the cylinder associated with the pressure sensor is detected. The method is characterized in that an adjustment of injection characteristics is carried out for the injectors allocated to the individual cylinders of the internal combustion engine by way of a method which is independent from the detected cylinder pressure, and that a torque control for the internal combustion engine is performed based on the detected cylinder pressure.

Abstract: A method is proposed for controlling and regulating an internal combustion engine according to the HCCI combustion method, in which a first fuel in a basic mixture is ignited using a pilot fuel, and in which the fuel quantities of the first fuel and the pilot fuel are changed to represent an operating point of the internal combustion engine. The invention is characterized in that a target combustion energy (VE(SL)) is calculated as a function of a power demand and, based on the target combustion energy (VE(SL)), the fuel quantity of the first fuel and the fuel quantity of the pilot fuel are determined using a distribution factor (CHI), wherein the distribution factor (CHI) is calculated as a function of an actual combustion position (VL(IST)) to a target combustion position (VL(SL)) using a combustion position controller (18).

Abstract: Exemplary illustrations are provided of a common rail system for an internal combustion engine, having a rail for fuel and an injector for the purpose of injecting the fuel into a working space of the internal combustion engine, said injector having a fluid connection to said rail via a high-pressure conduit. The high-pressure conduit may have a high-pressure component with an individual reservoir, and the high-pressure conduit and/or the rail may have a pressure measurement device. The pressure measurement device may be coupled to a local logic and storage device of a decentralized, local electronic device which is designed for the purpose of locally analyzing and storing measurement data of the pressure measurement device, e.g., injector data and/or rail data, and the pressure measurement device is connected to the central electronic device via a bus, with the local logic and storage device connected between the same.

Abstract: In a method for a model-based determination of a temperature distribution of an exhaust gas post-treatment unit, a differentiation is made between steady operating states and non-steady operating states by taking into account the axial and the radial temperature distribution, and, on the basis of virtual segmentation of the post-treatment unit, in particular the radial heat transfer to the surroundings is taken into account in the model-based determination for steady operating states, and for non-steady operating states the heat transfer from the exhaust gas which flows axially through the post-treatment unit to the segments is taken into account by a heat transfer coefficient k.

Abstract: For an internal combustion engine with a common rail system including individual accumulators, a process for open- and closed-loop control is proposed, in which the individual accumulator pressure (pE) is detected within a measuring interval and stored, an absolute minimum value of the stored individual accumulator pressure (pE) is interpreted as the end of the main injection, and on the basis of the end of the main injection, a mathematical function is used to calculate a virtual starting time for the main injection. In the measuring interval after the end of the main injection, the individual accumulator pressure (pE) is filtered within a time window, a local minimum value of the filtered individual accumulator pressure is interpreted as the end of a post-injection, and a mathematical function is used to calculate a virtual start of the post-injection.

Abstract: In an arrangement and a method for controlling an internal combustion engine including a control unit, an injector for injecting fuel into the combustion chambers of the engine, connecting lines interconnecting the engine control unit and the injector for transmitting signals therebetween and an intelligent electronic component provided with the injector for an integral structure, the electronic component comprises an electronic storage unit for storing data, a computing unit, a measuring unit for determining momentary actual injector values and an energy storage device for storing electric energy which is supplied to the electronic components and to the injector unit during engine operation via the connecting lines either constantly or only during the fuel injection procedure.

Abstract: A method for controlling an internal combustion engine having a common rail system together with individual accumulators. A rotational speed-control deviation (dn) is determined from a target rotational speed (nSL) that represents the set point for an outer control loop to control the rotational speed, as well as from an actual rotational speed (nIST). A target torque (MSL) is determined from the rotational speed-control deviation (dn) via a rotational speed controller as a master controller. A target injection duration (SD(SOLL)) is determined from the target torque (MSL). The target duration injection (SD(SOLL)) represents the set point for an inner control loop for controlling cylinder-specific injection duration. An injection duration deviation is determined from the target injection duration (SD(SOLL)) and from an actual injection duration.

Abstract: In an arrangement for controlling an internal combustion engine comprising an electronic engine control unit, a cylinder with a combustion chamber, a fuel injector, an intelligent electronic block with an electronic data storage unit, a computing unit, a signal measuring unit and an electric energy storage device for supplying energy to the electronic block during operation of the internal combustion engine, and control lines for the transmission of fuel injection control signals from the electronic engine control unit to the injector, the control lines for the transmission of injector control signals serve as energy transmission for the energy storage device and, at the same time, as bi-directional data exchange lines.

Abstract: In an internal combustion engine including an electronic engine control unit and electric consumers including an electric generator, a starter system, a performance module having integrated therein switching means for activating or deactivating consumers and monitoring means for the surveillance of the consumers and also power distribution means for the distribution of the electric power to the consumers is connected to the crankcase of the engine and wired via wiring harnesses to the engine and the consumers.

Abstract: In an arrangement for controlling an internal combustion engine, comprising an electronic engine control unit, an injector with an injection needle for controlling the injecting of fuel into a combustion chamber of the engine and a connecting line extending between the electronic engine control unit and the injector for the transmission if signals therebetween, an intelligent electronic component is integrated into the injector including an electronic memory unit, a computation unit, an energy storage device forming an energy supply for the electronic component and also a measuring unit for opto-electronically detecting the movement of the fuel injector needle.

Abstract: In an arrangement for controlling an internal combustion engine comprising an electronic engine control unit, a cylinder with a combustion chamber, a fuel injector, an intelligent electronic block with an electronic data storage unit, a computing unit, a signal measuring unit and an electric energy storage device for supplying energy to the electronic block during operation of the internal combustion engine, and control lines for the transmission of fuel injection control signals from the electronic engine control unit to the injector, the control lines for the transmission of injector control signals serve as energy transmission for the energy storage device and, at the same time, as bi-directional data exchange lines.

Abstract: In an arrangement for controlling an internal combustion engine comprising an electronic engine control unit, a fuel injector, electronic connecting lines extending between the electronic engine control unit and the injector and an intelligent electronic block forming with the injector a component unit, the intelligent electronic block comprises an electronic data storage device, a computing unit, an energy storage device for storing energy and supplying energy to the intelligent electronic block and also a measuring unit for detecting the movement of an injector needle as an indication of fuel injection begin and fuel injection end.

Abstract: In an internal combustion engine comprising an electronic engine control unit and electric consumers including an electric generator, a starter system, a performance module having integrated therein switching means for activating or deactivating consumers and monitoring means for the surveillance of the consumers and also power distribution means for the distribution of the electric power to the consumers is connected to the crankcase of the engine and wired via wiring harnesses to the engine and the consumers.

Abstract: In an arrangement for controlling an internal combustion engine, comprising an electronic engine control unit, an injector with an injection needle for controlling the injecting of fuel into a combustion chamber of the engine and a connecting line extending between the electronic engine control unit and the injector for the transmission if signals therebetween, an intelligent electronic component is integrated into the injector including an electronic memory unit, a computation unit, an energy storage device forming an energy supply for the electronic component and also a measuring unit for opto-electronically detecting the movement of the fuel injector needle.

Abstract: In an arrangement and a method for controlling an internal combustion engine including a control unit, an injector for injecting fuel into the combustion chambers of the engine, connecting lines interconnecting the engine control unit and the injector for transmitting signals therebetween and an intelligent electronic component provided with the injector for an integral structure, the electronic component comprises an electronic storage unit for storing data, a computing unit, a measuring unit for determining momentary actual injector values and an energy storage device for storing electric energy which is supplied to the electronic components and to the injector unit during engine operation via the connecting lines either constantly or only during the fuel injection procedure.

Abstract: In a method of controlling an internal combustion engine wherein an injection begin is calculated depending at least on an actual engine speed and the injection begin is corrected, the injection begin correction is calculated from a deviation of a desired air mass flow from an actual air mass flow.