EP0443175A2 - Ignition device for combustion engines - Google Patents

Abstract

The invention relates to an ignition system for internal combustion engines, having a crankshaft signal generator (KW signal generator) which supplies per crankshaft rotation a reference mark assigned to a specific crankshaft angular position and having a phase signal generator, in particular a camshaft signal generator (NW signal generator) which within two crankshaft rotations generates a number of phase signals assigned to the camshaft position, which number corresponds to the number of cylinders of the internal combustion engine, one of the phase signals being used to form a cycle signal which characterises the start of an ignition cycle. In order to be able to constantly perform a reliable cylinder identification (cylinder 1 recognition) in emergency operation occurring in the event of a failure of the KW signal generator, an identification signal (K) which forms the cycle signal (Z) together with the associated first phase signal (P) is applied between a first phase signal (PE) assigned to a specific cylinder (cylinder 1) and the adjacent phase signal (P) which follows said signal. <IMAGE>

Description

State of the art

The invention relates to an ignition system for internal combustion engines, with a reference mark transmitter, in particular a crankshaft transmitter (KW transmitter), which supplies a reference mark assigned to a specific crankshaft angular position per crankshaft revolution, and with a phase transmitter, which in particular as a camshaft transmitter interacting with the camshaft of the internal combustion engine (NW- Encoder) is formed and which generates a number of phase signals assigned to the number of cylinders of the internal combustion engine from the camshaft position within two crankshaft revolutions, one of the phase signals being used to form a cycle signal which indicates the start of an ignition cycle.

From DE-OS 36 34 587 an ignition system for internal combustion engines is known, which is synchronous with the Camshaft of the engine has driven Hall diaphragm, the Hall diaphragm having a recess assigned to each cylinder, whereby a corresponding number of phase pulses is generated. One of the recesses is wider than the other, whereby a phase pulse is generated which marks the beginning of an ignition cycle in cooperation with a reference mark. This comes from a KW encoder that delivers a signal assigned to a specific crankshaft angular position for each crankshaft revolution. If the KW transmitter fails, emergency operation can take place on the basis of the phase signals of the Hall sensor provided with a Hall diaphragm, since a control unit of the internal combustion engine can recognize the start of an ignition cycle on the basis of the broader phase signal. A fixed emergency running ignition angle is defined, the ignition coil being charged when the leading edge of each phase signal occurs and the ignition being triggered when the respective trailing edge of the phase signals occurs. With a rotating ignition distribution, the detection of the ignition cycle is not important, since the distribution is carried out by a high-voltage distributor. When the distribution is at rest, however, the start of the ignition cycle must be reliably recognized. Since the running internal combustion engine is a dynamic system, the detection of the phase signal characterizing the start of the ignition cycle at certain operating points with the above-mentioned method is not always possible with certainty, so that incorrect control and thus damaging and / or overloading operating states can occur.

From the literature reference "SAE Technical Paper Series, 820256," A Low Cost Electronic Ignition Control System With A 4-Bit Microcontroller ", Richard W. Kovener, 1982, it is known to have a recess on the crankshaft of an internal combustion engine which is distributed over the circumference to attach the provided sensor disc, wherein a double recess is provided in order to be able to detect the position of the crankshaft by a detector. The arrangement thus has the function of a reference mark transmitter known per se.

In contrast, the ignition system according to the invention with the features mentioned in the main claim has the advantage that in the event of a failure of the KW transmitter in systems with a stationary or rotating ignition distribution, emergency operation is possible at any operating point, since the start of an ignition cycle is flawless, even with dynamic changes in state is recognized by the computer of a control unit of the internal combustion engine. For this purpose, an identification signal is arranged between a first phase signal assigned to a specific cylinder and the adjacent phase signal following it, which together with the associated first phase signal forms the cycle signal. As a result, the phase encoder supplies a cycle signal every 720 ° crankshaft angle, which consists of a phase signal and an identification signal, which enables absolutely reliable detection of the start of the ignition cycle. Even taking dynamic changes into account, the start of the ignition cycle can be reliably detected since, as in the prior art, it does not indicate an increased signal width, but is switched to a "double signal" during emergency operation.

In normal operation, that is, when the KW transmitter is working properly, cylinder detection is possible after a crankshaft revolution at the latest if the phase signal assigned to the cycle signal has a larger signal width than the other phase signals. The reference mark then coincides in time with the broader phase signal. This occurs every 720 °, so that in the event of a collapse within a 360 ° period, either the cylinder starting the ignition cycle (e.g. cylinder 1) is recognized or is not recognized due to non-collapse, which means that in the latter case a cylinder definition is also perfectly possible.

The identification signal is preferably an identification pulse which immediately follows the assigned phase signal.

The phase signals are preferably formed by negative pulses. This means that an existing signal amplitude reduces its value in the area of the phase signals.

According to a preferred exemplary embodiment, the identification pulse has a pulse width which corresponds to 10 ° crankshaft rotation (crankshaft angle). In order to be able to clearly detect the end of the identification pulse, a pulse pause follows this. The pulse pause preferably corresponds to 10 ° crankshaft rotation.

The signal width of the phase signals preferably decreases as the number of cylinders increases. In particular, in an internal combustion engine with four cylinders, the signal width of the phase signal assigned to the identification signal corresponds to approximately 90 ° and the other phase signals to approximately 40 ° crankshaft angle. In the case of an internal combustion engine with six cylinders, the signal width of the phase signal associated with the identification signal corresponds to approximately 80 ° and the other phase signals to approximately 30 ° crankshaft angle. In the case of an internal combustion engine with five cylinders, the signal width of the phase signal associated with the identification signal corresponds to approximately 70 ° and the other phase signals to approximately 40 °. An eight-cylinder internal combustion engine provides that the signal width of the phase signal assigned to the identification signal corresponds to approximately 70 ° and the other phase signals to approximately 30 ° crankshaft angle.

It is envisaged that in emergency operation, so if the KW transmitter fails, the leading edges of the phase signals start the charging time for the ignition coil, the trailing edges of the phase signals triggering the ignition. At low speeds, in contrast, the charging time can begin with the trailing edges of the phase signals and the ignition can take place after a fixed charging time. This avoids excessive charging times, which could lead to the destruction of the ignition coil or output stage.

Finally, in emergency operation, the identification signal is masked out by the control unit of the internal combustion engine after cylinder identification (cylinder 1 detection) has been carried out using the cycle signal.

This blanking, that is to say non-processing, is necessary so that the edges of the identification signal do not lead to the ignition coil being charged here or the ignition pulse being emitted.

drawing

The invention is explained in more detail below with reference to the drawing. 1 shows various diagrams for four, six, eight and five-cylinder internal combustion engines and in FIG. 2 a block diagram of a circuit arrangement.

Description of exemplary embodiments

In the following, an ignition system for internal combustion engines is discussed, which has a crankshaft encoder (KW encoder) and a phase encoder. The ignition of this internal combustion engine is controlled by means of an engine control unit, taking engine and operating data into account. The KW transmitter preferably works together with a ring gear of the crankshaft of the internal combustion engine, the individual teeth of the ring gear causing a change in the electrical signal supplied by the KW generator. Since teeth and tooth gaps of the ring gear alternate when the motor rotates, the KW transmitter emits a type of alternating voltage, from which, for. B. the speed of the internal combustion engine can be determined by the control unit. At one point on its circumference, the ring gear has a particularly large tooth gap (e.g. due to the lack of a tooth), so that the KW generator AC voltage also shows a corresponding gap, which is a Reference mark BM forms. The reference mark BM thus occurs for each crankshaft revolution of the internal combustion engine. It is preferably before the top dead center TDC of a specific cylinder (e.g. cylinder 1). In particular, it is provided that in four-cylinder internal combustion engines, the reference mark approximately 80 ° before top dead center TDC, in six-cylinder internal combustion engines about 70 ° before top dead center TDC, in eight-cylinder internal combustion engines approximately 60 ° before top dead center TDC and in five-cylinder internal combustion engines is approximately 60 ° before top dead center TDC of cylinder 1. This is indicated in FIG. 1 and can be seen from the diagrams shown there.

The reference mark BM (in ° crankshaft angle (KW)) is shown at the top on the abscissa of the diagram. Below this, the course of the t _R pulses is shown in area I for a four-cylinder internal combustion engine. Underneath is the top dead center OT with the associated cylinder number. The phase signal curve then follows. Finally, the start of the ignition on the trailing edge 10 ° before top dead center is shown below. The reference mark BM is approximately 80 ° before top dead center.

A corresponding structure is shown in area II of the diagram, which applies to a six-cylinder internal combustion engine. The reference mark BM is approximately 70 ° before top dead center OT.

In area III there follows the representation for an eight-cylinder internal combustion engine and in area IV a corresponding signal curve for a five-cylinder internal combustion engine. In the eight-cylinder internal combustion engine, the reference mark is approximately 60 ° before top dead center OT; in the five-cylinder internal combustion engine, the reference mark is approximately 60 ° before top dead center OT. In all engine versions of the diagram, the ignition starts on the trailing edge 10 ° before top dead center.

The phase signal curve shown in the diagram for each engine version of a phase generator which interacts with the camshaft of the associated internal combustion engine has phase signals assigned to each cylinder, which are formed by negative pulses. Negative pulses mean that there is an amplitude reduction in the area of each phase signal. Since the crankshaft of the internal combustion engine runs twice as fast as the camshaft, the phase generator supplies the phase signals within an ignition cycle of 720 °. According to the invention, the beginning of an ignition cycle is formed by a cycle signal Z which is assigned to the specific cylinder (eg cylinder 1) already mentioned. The cycle signal Z is composed of a first phase signal assigned to the specific cylinder and an identification signal. In the figure, the phase signals are denoted by P and the identification signal by K. In order to distinguish the first phase signal from the other phase signals, it is given the identification PE. The identification signal K is designed as an identification pulse, which immediately follows the assigned, first phase signal PE. It is followed by an impulse pause L.

FIG. 1 also shows t _R pulses. These are crankshaft angle synchronous pulses that the computer of the control unit generates as a reference. The basis for this is the AC signal from the KW encoder.

The arrangement is such that the reference mark BM is at 0 ° crankshaft position (KW), 360 ° crankshaft position (KW), 720 ° crankshaft position (KW) etc. The first phase signal PE belonging to the respective cycle signal Z is located in relation to the reference mark BM assigned to the 0 ° and 720 ° crankshaft position (KW) such that the latter lies in time within the length of the corresponding first phase signals PE. To take tolerances into account, the first phase signal PE is therefore wider than the other phase signals P. The reference mark BM assigned to the 360 ° crankshaft position (KW) does not fall into a phase signal P. This enables a clear cylinder assignment.

In particular, it is provided for a 4-cylinder internal combustion engine that the signal width of the first phase signal PE corresponds to 90 ° crankshaft angle. This is followed by the identification signal K, which has a pulse width of 10 ° crankshaft angle (crankshaft rotation). The subsequent pulse pause L corresponds to 10 ° crankshaft angle. The individual phase signals P have a width of 40 ° crankshaft rotation. The distance between the reference mark BM assigned to the 360 ° crankshaft position (KW) and the leading edge of the following phase signal P is 30 ° crankshaft rotation.

A first phase signal with a width of 80 ° crankshaft angle is provided for an internal combustion engine with six cylinders. In the case of an eight-cylinder internal combustion engine or five-cylinder internal combustion engine, this signal width is 70 ° crankshaft angle in each case. In the case of six, eight and five-cylinder internal combustion engines, identification signal K and pulse pause L are formed in the same way as in a four-cylinder internal combustion engine. The six-cylinder internal combustion engine has phase signals P with a width of 30 ° crankshaft angle. This also applies to an eight-cylinder internal combustion engine. In a five-cylinder internal combustion engine, the signal width mentioned is 40 ° crankshaft angle. The distance from the reference mark belonging to the 360 ° crankshaft position (KW) to the front flank of the following phase signal is 20 ° crankshaft angle in the case of the six and eight-cylinder internal combustion engines. In the five-cylinder internal combustion engine, this distance is 22 ° crankshaft angle.

In normal operation of the internal combustion engine, that is to say a perfectly functioning KW and phase transmitter, a clear cylinder assignment / identification is possible even after a crankshaft angle of 360 °, since either a reference mark BM is detected within a first phase signal PE or a reference mark BM which lies outside a phase signal P. The t _R pulse output is carried out by the control unit using the signal supplied by the KW encoder. The t _R pulses serve to determine the injection times of the fuel (Ti signals).

In emergency operation mode, ie if the KW transmitter fails, cylinder identification is possible on the basis of the identification signal K. By comparing the pulse durations of the phase signal PE, the identification signal K and possibly additionally from the pulse pause L, the cycle signal Z, which characterizes the start of an ignition cycle, can always be found unambiguously — even in dynamic operating cases. The cylinder 1 can therefore be correctly recognized within 720 ° crankshaft angle.

If the internal combustion engine has a rotating distribution, the ignition output is controlled via the phase signals of the phase generator in emergency operation. The t _R pulses can no longer be used because they depend on the failed KW transmitter. The procedure is such that the ignition coil current is switched on at each leading edge of a phase signal PE, P and the ignition occurs with the trailing edge of each phase signal PE, P. At low speeds, a fixed switch-on time of the ignition coil can be output, starting with the trailing edge, which is preferably dependent on the battery voltage. This is shown in the figure by the high-voltage arrow. A cylinder identification is not necessary for the rotating distribution, since there is a fixed assignment between the distributor finger and the cylinder.

If the internal combustion engine under consideration has a stationary distribution and emergency operation occurs due to the failure of the KW transmitter, the ignition output is also via the phase signals PE, P controlled. The position of the start of the charging time of the ignition coil and the delivery of the ignition pulses take place in the same way as in the rotating distribution described above. Furthermore, cylinder identification (cylinder 1 detection) is required. First of all, therefore, a cylinder-1 identification is carried out on the basis of the detection signal K according to the invention, and then the ignition — as already described — is carried out. The pulse pause L that follows the identification signal K is then hidden so that no counting error occurs due to the pulse edges, which would lead to the delivery of ignition pulses at wrong times. The emergency operation described is possible for internal combustion engines of any number of cylinders.

Since modern internal combustion engines are equipped with injections that work in dependence on the reference signal (t _R pulses) already mentioned, special measures must be taken in emergency mode (i.e. in the event of the KW transmitter failure), since the t _R pulses are also eliminated .

In a so-called SEFI injection (sequential fuel injection), certain variables (e.g. speed, upstream, injection time, etc.) are transmitted from the master microcontroller of the control unit to a slave microcontroller (SEFI-µC). In normal operation, this transmission takes place synchronously with the tR pulses. Since the t _R pulses are missing in emergency operation, replacement t _R pulses are output on the positive edges of the phase signals PE, P, which are used as the basis for the injection pulses (Ti pulses). For this purpose, it is necessary that the edges of the pulse pause are suppressed after the identification signal K so that they do not serve incorrectly as a substitute t _R pulse edge. The change in angle (crankshaft angle) of the t _R pulses compared to normal operation in emergency mode must be accepted.

If the internal combustion engine has simultaneous injection, the start of injection (Ti pulses) is also placed on the positive segment flank after each (number of cylinders / 2) phase signals. An exact cylinder assignment of the Ti position cannot be maintained if there is no cylinder detection.

In the case of group injection, if there is no cylinder assignment in emergency operation, the system switches to simultaneous injection or the wrong cylinder assignment is used, which is permissible for emergency operation. If cylinder detection can take place, group injection can be maintained. It then makes sense to assign the Ti start for the first group to the phase signal p, which follows the phase signal PE at a distance (number of cylinders / 2) -1. This assignment is useful for four, six and eight-cylinder internal combustion engines.

It is also useful to limit the speed by switching off the injection above a speed from which sufficient charging of the coil is not ensured due to the predetermined angularly rigid switch-on duration of the ignition coil. This speed threshold can preferably be dependent on the battery voltage. Alternatively, at high speeds, counting a time from the trailing edge of the previous cylinder, the duty cycle of the coil can be extended to the necessary time (quasi segment system).

FIG. 2 shows a block diagram of the arrangement described. The internal combustion engine 10 has a camshaft NW and a crankshaft KW. Crankshaft KW and camshaft NW are coupled to one another via a toothed belt transmission 11. On the camshaft NW there is a sensor element 12 which interacts with the camshaft sensor (NW sensor) 13. On the crankshaft KW a further encoder element 14 is fastened in a rotationally fixed manner, which works together with a crankshaft encoder 15 (KW encoder).

The KW encoder 15, which supplies a crankshaft signal, is connected to an interface circuit 16; the NW transmitter 13 is connected to a further interface circuit 17. The output of the interface circuit 16 is connected to an input of a reference mark detection circuit 18 and to a further input of a KW sensor failure detection circuit 19. Furthermore, the output mentioned leads to a first evaluation circuit 20. The latter performs a closing time and ignition angle calculation and is responsible for a quiescent distribution in normal operation.

Said output of the interface circuit 16 is also connected via a first changeover switch 21 to an input of a second evaluation circuit 22 which carries out the injection time calculation and is optionally used for an SEFI injection.

The output of the interface circuit 17 also leads to the KW sensor failure detection circuit 19 and to a further pole of the first switch 21 and to an input of a third evaluation circuit 23 which carries out a closing time and ignition angle calculation and, if necessary, a quiescent distribution in emergency operation. The output of the interface circuit 17 is also connected to an input of a cylinder 1 detection circuit 24 for normal operation and to an input of a cylinder 1 detection circuit 25 for emergency operation. In emergency operation mode, the cycle signal Z is obtained by comparing the pulse durations of phase signal PE; Identification pulse K and possibly the pulse pause L. The output of the reference mark detection circuit 18 is also connected to an input of the cylinder 1 detection circuit 24.

The output of the cylinder 1 detection circuit 24 leads to an input of the first evaluation circuit and to a second changeover switch 26, which in the position shown in FIG. 2 establishes a connection to an input of the second evaluation circuit 22. The output of the cylinder 1 detection circuit 25 leads to a further pole of the second switch 26 and further to a further input of the third evaluation circuit 23. The output of the first evaluation circuit 20 leads to a third switch 27, the position shown in FIG connects the first evaluation circuit 20 to the ignition coil or the ignition coils 28 (not shown in more detail). A signal is provided at the output of the second evaluation circuit 22 Control of the injection valves 29 (not shown in detail) of the internal combustion engine 10 is available. The output of the third evaluation circuit 23 is connected to a further pole of the third switch 27.

An active connection 30 originates from the KW sensor failure detection circuit 19 and acts on the first, second and third changeover switches 21, 26, 27. In the position of the changeover switches 21, 26 and 27 shown in FIG. 2, normal operation of the internal combustion engine 10 is present. The switchover position that is carried out in emergency operation mode is entered with a dashed line; it is brought about by means of the KW sensor failure detection circuit 19.

The internal combustion engine 10 also has a load transmitter 31, which supplies a corresponding load signal to an input of the first evaluation circuit 20 and an input of the second evaluation circuit 22.

Finally, the reference mark detection circuit 18, the KW sensor failure detection circuit 19, the first evaluation circuit 20, the second evaluation circuit 22 and the third evaluation circuit 23, the cylinder 1 detection circuit 24 and the cylinder 1 detection circuit 25 are in a micro- Controller µC summarized.

In normal operation of the internal combustion engine, both the KW signal and the NW signal of the internal combustion engine are correspondingly evaluated and processed in accordance with the circuit arrangement in FIG. If the KW transmitter failure detection circuit 19 detects a malfunction of the KW transmitter 15, the changeover switches 21, 26 and 27 are brought into the position shown in dashed lines in FIG. 2 and the emergency operation mode - as already stated above - is started.

Claims (20)

Ignition system for internal combustion engines, with a reference mark transmitter, in particular crankshaft transmitter (KW transmitter), which supplies a reference mark assigned to a specific crankshaft angular position per crankshaft revolution and with a phase transmitter, in particular camshaft transmitter (NW transmitter), which, within two crankshaft revolutions, one of the number of cylinders the internal combustion engine generates a corresponding number of phase signals assigned to the camshaft position, one of the phase signals being used to form a cycle signal which indicates the start of an ignition cycle, characterized in that between a first phase signal (PE) assigned to a specific cylinder (cylinder 1) and the adjacent phase signal (P) following this is an identification signal (K) which, together with the associated first phase signal (PE), forms the cycle signal (Z) in the emergency mode that occurs when the KW transmitter fails. Ignition system according to Claim 1, characterized in that the phase signal (PE) assigned to the cycle signal has a larger signal width than the other phase signals (P). Ignition system according to one of the preceding claims, characterized in that the reference mark (BM) is assigned in time to the phase signal (PE) of the cycle signal (Z). Ignition system according to one of the preceding claims, characterized in that the identification signal (K) is an identification pulse which immediately follows the assigned phase signal (PE). Ignition system according to one of the preceding claims, characterized in that the phase signals (PE, P) are formed by negative pulses. Ignition system according to one of the preceding claims, characterized in that the identification pulse (K) has a pulse width which corresponds to 10 ° crankshaft rotation (crankshaft angle). Ignition system according to one of the preceding claims, characterized in that the identification pulse is followed by a pulse pause (L). Ignition system according to one of the preceding claims, characterized in that the pulse pause (L) corresponds to 10 ° crankshaft rotation. Ignition system according to one of the preceding claims, characterized in that the cycle signal (Z) by comparing the pulse durations of the phase signal (PE), identification pulse (K) and possibly the pulse pause (L) is generated. Ignition system according to one of the preceding claims, characterized in that the signal width of the phase signals (PE, P) decreases as the number of cylinders increases. Ignition system according to one of the preceding claims, characterized in that in an internal combustion engine with four cylinders the signal width of the phase signal (PE) assigned to the identification signal (K) corresponds to approximately 90 ° and the other phase signals (P) corresponds to approximately 40 ° crankshaft angle. Ignition system according to one of the preceding claims, characterized in that in an internal combustion engine with six cylinders, the signal width of the phase signal (PE) associated with the identification signal (K) corresponds to approximately 80 ° and the other phase signals (PE) to approximately 30 ° crankshaft angle. Ignition system according to one of the preceding claims, characterized in that in an internal combustion engine with five cylinders the signal width of the phase signal (PE) assigned to the identification signal (K) corresponds to approximately 70 ° and the other phase signals (P) corresponds to approximately 40 ° crankshaft angle. Ignition system according to one of the preceding claims, characterized in that, in an internal combustion engine with eight cylinders, the signal width associated with the identification signal (K) Phase signal (PE) corresponds to approximately 70 ° and the other phase signals (P) corresponds to approximately 30 ° crankshaft angle. Ignition system according to one of the preceding claims, characterized in that the charging time for the ignition coil begins in emergency operation if the KW transmitter fails due to the leading edges of the phase signals (PE, P). Ignition system according to one of the preceding claims, characterized in that the ignition is triggered in emergency operation by the trailing edge of the phase signals (PE, P). Ignition system according to one of the preceding claims, characterized in that in emergency operation at low speeds starting with the trailing edge of the phase signals (PE, P) a fixed charging time is output depending on the battery voltage for the ignition coil, at the end of which the ignition takes place. Ignition system according to one of the preceding claims, characterized in that in emergency operation after the cylinder identification (cylinder 1 detection) by means of the cycle signal (Z) by the control unit of the internal combustion engine, the pulse pause (L) which follows the identification signal (K) is suppressed becomes. Ignition system according to one of the preceding claims, characterized in that above a speed from which a reliable charging of the ignition coil is no longer guaranteed, the speed is limited by switching off the injection. Ignition system according to one of the preceding claims, characterized in that at high speeds a sufficient closing duration of the ignition coil is achieved by switching on the ignition coil from a certain time after the trailing edge of the phase signal assigned to the preceding cylinder, instead of with the leading edge of the phase signal assigned to the current cylinder.

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