Abstract: To rapidly determine the position of the crankshaft of a four-cycle engine with an equal number n of cylinders in relation to its cylinders it is proposed that a signal generator attached to the crankshaft be divided along its circumference into n/2 equal signal-mark sections, each with one identification mark, and that a signal generator attached to the camshaft be divided into n/2 or n equal signal sections with equal graduations that differ from one another. The identification marks differ when the number of signal-mark sections differs and can be identical when the number of these sections is different. Comparison of the pulses from the two signal generators and synchronized by the indentification marks makes it possible to directly associate the position of the crankshaft with the cylinders even immediately after the engine starts.

Abstract: A timing arrangement incorporates a timing disk having absolute marks arranged about a circle and serving for the identification of the angular position of the shaft of an internal combustion engine. The marks include a code track havig code marks and absolute marks, each absolute marks being preceded by a code element comprising a number of code marks. Each absolute mark is identified by a code section preceding and consisting of two or more code elements.

Abstract: A device for controlling ignition or fuel injection and the like of an internal combustion engine includes an angular position sensor of a shaft of the engine. The sensor is in the form of a disc rotating together with the shaft and being provided on its periphery with as many radially projecting segments separated by gaps as many cylinders has the engine. A gap between the segments is provided with a single sloping ramp terminating with a steep flank. The flank of one segment and the steep flank of the ramp cooperate with a detector which generates a marking pulse coordinating during single rotation of the shaft the distribution of control pulses to respective cylinders.

Abstract: A device for controlling an internal combustion engine of a motor vehicle comprises a sensor disk rotating with the shaft of the engine and a stationary signal receiving element scanning signals from the sensor disk. Sensing elements are positioned on the sensor disk. The number of these elements is proportional to the number of cylinders of the engine. Each sensing element includes a sickle-shaped portion and a lug coordinated with the signal receiving element. The control system is formed as an assembly of prefabricated structural components.

Abstract: A multicylinder internal combustion engine includes a pair of camshafts, a pair of driven pulleys fixed to ends of the camshafts, a crankshaft, a driver pulley fixed to an end of the crankshaft, and a single endless belt trained around the driven pulleys and the driver pulley. A rotation sensor for detecting the rotation of the engine is disposed between a fixed engine member and the one of the driven pulleys around which a portion of the endless belt subject to greater tension is trained. A distributor is coupled coaxially to an opposite end of the camshaft to which said one driven pulley is fixed.

Abstract: Improved magnetic pulse timer components provide increased timer voltages with steeper bipolar waveforms. Such improvements are residual in terms of a permanently magnetized timer rotor (30, 40, 60, 70, 80). Rotors (30, 40, 60) have regularly spaced protrusions at the rotor's outer periphery and are permanently magnetized. Rotors (70, 80) have regularly spaced slots in their outer peripheries and may also be permanently magnetized. Such slotted rotors provide the capability of high level and steep bipolar voltage waveforms. Additional magnetic flux switching capability in the timer may be provided by utilizing a permanently magnetized component mounting base plate (90, 100, 110).

Abstract: In an electronic fuel injecting method for an internal combustion engine, wherein fuel injection timings for every groups are controlled in accordance with reference signals variable in the proximity of intake top dead center of a predetermined cylinder and the angle signals variable at every predetermined rotary angles, during a low rotational speed operation of the engine, all of the cylinders perform injections simultaneously in accordance with the angle signals according to the necessity, during a medium rotational speed operation of the engine, group injections with the cylinders being discriminated by the reference signal are performed in accordance with the reference signals and the angle signals, and, during a high rotational speed operation of the engine, group injections with the cylinders being not discriminated by the reference signal are performed in accordance with the angle signals according to the necessity.

Abstract: An illustrative embodiment of the invention provides a four cycle internal combustion engine that produces one power stroke for each full rotation of the crankshaft. Direct fuel and oxidizer injection into the cylinder permits engine speed and power to be controlled by varying the duration of the intake stroke. This duration is controlled, moreover, by moving the distributor housing in relation to piston top dead center position.

Abstract: An ignition position controlling apparatus for a multicylinder internal combustion engine is disclosed which is capable of generating clock pulses and cylinder discriminating signals for detecting proper angular positions necessary to determine the ignition positions of cylinders of the engine using an inductor-type signal generator simple in construction which includes signal generating means in number corresponding to the number of cylinders of the engine and a single disc-like toothed inductor.

Abstract: This invention discloses an engine rotation sensor which can generate angle- and timing-pulses from one sensor. The ratio of the intervals between these pulses generated by the rotation sensor is determined. The crank angle pulses and the timing pulses are discriminated depending on whether this ratio is less than or equal to a predetermined value, or not. The injection of fuel of each injector is controlled by a pulse which is discriminated as a timing pulse.

Abstract: A four-cylinder engine control system (10) for controlling the functions of ignition or fuel injection is disclosed. The control system includes cylinder identification apparatus (30, 50, 60) which operates in conjunction with a rotary member (11) rotated by the engine crankshaft having timing projections (14, 17) corresponding to specific rotational positions of the crankshaft. A pair of fixed sensors (20, 21) sense the passage of the timing projections and provide corresponding signals to an engine timing calculation and control circuit (40) which provides control signals that are sequentially selectively routed to control ignition and/or fuel injection of the engine cylinders in a predetermined sequence. One timing projection (14) comprises two individual radial extensions (15, 16) whereas another comprises a single extension (17).

Abstract: A quadrature trigger system for a sequential fuel injection system utilizes a single lobe timing cam connected to the camshaft of a four cylinder internal combustion engine as illustrated in FIG. 2. Positioned in a sensing relationship to the cam are two proximity sensors which generate bilevel electrical signals having a fifty percent duty cycle and which are spaced ninety electrical degrees apart. These electrical signals are decoded in a logic network to direct fuel injection pulses from either of two pulse generators to the proper sequenced fuel injector.

Abstract: An apparatus for generating signals to control the firing of spark plugs or the operation of a fuel injection distributor for an internal combustion engine having multiple cylinders utilizes sensors that scan markings on the crankshaft and camshaft and an evaluating circuit to develop such control signals.

Abstract: An electronic cylinder identification system is disclosed for identifying the occurrence of a predetermined cycle position for a reference cylinder and synchronizing fuel injection for a multi-cylinder engine in accordance thereto. A four cylinder engine rotates a rotary body having two 90 degree spaced peripheral projections and two stationary reluctance sensors are positioned 180 degrees apart about the body and sense the passage of the rotary body projections. Logic circuitry receives signals from the two sensors and determines which sensor is currently providing a logic pulse indicating the passage of a projection and which sensor previously provided such a pulse. The logic circuitry utilizes this information to identify the rotational position of the rotary body by differentiating between occurring identical sensor pulses based upon which sensor previously produced a pulse.

Abstract: An actuation timing apparatus is disclosed for providing triggering and steering control signals to an electronic control unit regulating a plurality of solenoid fuel injectors of a sequential injection system. The apparatus includes a rotatable member which is rotated in synchronism with the engine at the speed of its camshaft. The rotatable member has a plurality of spaced sensible elements geometrically disposed thereon and divided into groups identifying individual cylinders. Each group has at least one sensible element which defines a reference element having a recognizable characteristic distinguishing it from the other sensible elements in the group. A single sensor senses the spaced sensible elements of each group as they rotate past a fixed sensing location and generates corresponding electrical pulses to a pulse processing circuit. The pulse processing circuit decodes each group of pulses to provide the identity of the injector to be next actuated.

Abstract: Electric control apparatus for providing an enabling control signal and a steering control signal to control the electronic fuel injectors of a sequential fuel injection system of an internal combustion engine is disclosed. The apparatus includes a rotatable disc which rotates in synchronism with the engine. The disc has a plurality of spaced sensible elements contained thereon, one of the sensible elements defining a reference element which has a recognizable characteristic distinguishing it from the other sensible elements. The distance between the reference element and an adjacent element defines a predetermined distance different than the distance between any two adjacent nonreference elements. A single sensor senses the spaced sensible elements and provides corresponding electrical pulses. A pulse processing circuit electrically connected to the output of the sensor processes the pulses.