EP0932751A1 - Method for synchronising the electronic control system of an internal combustion engine - Google Patents

Abstract

The invention concerns a method for producing a synchronising signal for the electronic control system of an internal combustion engine, characterised in that it comprises the following steps: a) working out a synchronising signal in phase with a signal locating the passage of the pistons in a predetermined position, said synchronising signal being arbitrarily initialised; b) monitoring the operation of the engine when the predetermined conditions are fulfilled; c) modifying the control parameters of the engine for at least two given cylinders of which the operating cycles are out-of-phase by two working strokes; d) computing for the cylinders concerned an algebraic quantity representing the variations in combustion levels; e) deducing from this algebraic quantity the exactitude of the synchronising signal and correcting it if the arbitrary initialisation turns out to be erroneous.

Description

 METHOD FOR SYNCHRONIZING THE ELECTRONIC CONTROL SYSTEM OF AN INTERNAL COMBUSTION ENGINE

The present invention relates to a method for synchronizing the electronic control system of a four-stroke type multi-cylinder internal combustion engine and electronic multipoint fuel injection.

The invention relates more precisely to a method capable of generating a synchronization signal making it possible to follow the progress of the operating cycle (succession of the different engine times) in each of the engine cylinders, this synchronization signal allowing the location of a predetermined instant. in the course of the cycle, such as the transition to Neutral High Admission or to Neutral Low Admission.

In order to improve the operation of internal combustion engines both from the performance point of view and from the point of view of the emission of pollutants, numerous fuel injection systems have been developed. Among these, mention may be made of electronically controlled multipoint indirect injection systems, such as the RENIX system designed by the applicant. •

One of the important characteristics of multi-point electronic injection is its intermittent operation, the injectors are in fact actuated periodically: at least once per engine cycle, or again in the case of a four-stroke engine once for two crankshaft turns or 720 ° angle.

Among the main modes of opening the injectors is ^" sequential actuation which consists in operating the injection of fuel by actuating successively and in a given order, the different injectors so as to inject into each cylinder as best as possible with respect to the phase The sequential injection is preferably phased so that the opening of each injector ends before the opening of the intake valve of the corresponding cylinder, opening which begins just before shifting to Neutral Top Admission of the corresponding cylinder.

However, the systems making it possible to operate a multipoint electronic injection of the sequential phased type have the disadvantage of generating a significant additional cost compared to a conventional electronic injection installation of the "Full Group" type, where all the injectors are activated simultaneously. .

In fact, such injection systems in particular need to have very precise means of locating the progress of the engine cycle in each of the cylinders, to enable the electronic engine control unit to calculate and control the flow rate of each injector at a suitable predetermined time, outside the opening period of the corresponding valve. It is customary, as disclosed in French patent application FR-A-2,441,829, to locate, on a disk (or target) integral with the crankshaft, the angular position zones corresponding to a determined phase of the stroke of the different pistons. The disc has locating elements arranged along its periphery, such as teeth of different length, and which when passing in front of a fixed receiving member, generate electrical pulses making it possible to produce a signal locating the transition to the top dead center position. of a specific piston.

However, such a tracking device is insufficient to control a phased sequential injection. Indeed, for a four-stroke internal combustion engine, the crankshaft performs two full turns (or 720 ° angle), before a given piston is found in the same operating position in the engine cycle. It follows that from the sole observation of the rotation of the target integral with the crankshaft, it is not a priori possible to provide information on each cylinder without an indetermination of two engine times in the cycle (the identification of the Top Dead Center position covering both the Admission ^' phase and the Relaxation phase).

The precise determination of the position of each cylinder in the cycle, also called cylinder coding, cannot be deduced from the mere observation of the position of the crankshaft, the search for additional information is therefore necessary to know if the cylinder is in the first or in the second half of the engine cycle (Intake then Compression phases during the first crankshaft turn, Relaxation then Exhaust phases during the second turn).

In order to obtain such additional information, conventionally, tracking elements are used, carried by a transmitting disc which rotates twice as slowly as the crankshaft. For this purpose, this emitting disc can be placed on the camshaft or else on the shaft of the ignition distributor which is driven by means of a reduction gear 1/2 from the crankshaft.

Conventionally therefore, the camshaft (or even the camshaft drive pulley) is equipped with a target bearing a mark which cooperates with a fixed sensor to deliver a frequency signal worth "1" during the first half of the cycle and "0" during the second half. It is the combination of signals from the crankshaft sensor and the camshaft sensor that allows the electronic control system to have a synchronization signal allowing, thanks to the identification of a predetermined instant of the operating cycle in each. cylinders, to operate a sequential phased injection.

Such angular tracking systems using both a crankshaft sensor and a camshaft sensor are relatively bulky, expensive and difficult to assemble. In addition, in the event that one of the sensors falls into failure, that is to say in degraded engine operating mode, conventional measurement systems do not provide sufficient information to the electronic engine control system driving the injection, hence a risk of imbalance of the latter.

The object of the present invention is to remedy the drawbacks of the known tracking systems used to operate the electronic control systems of the motors operating a sequential phased injection, by proposing a method of synchronization of the electronic control system which is simple and effective and which does not require any specific position sensor apart from the one used to identify the angular position of the crankshaft.

The method for synchronizing the electronic control system of a multicylinder internal combustion engine, according to the invention, consists in producing a synchronization signal, intended in particular for the phasing of the injection, which allows the identification of a predetermined instant in the course of the operating cycle of each of the cylinders, such as the change to Neutral High Admission (or change to Neutral Low Admission, etc.).

This synchronization signal according to the invention is deduced from two distinct signals produced by suitable processing means exploiting in particular the information provided by an angular position sensor cooperating with a ring gear carried by the crankshaft of the engine. The first signal provides an estimate of the level of successive combustions occurring in the engine cylinders and the second signal follows the displacement of the pistons and in particular their passage into a predetermined position such as Top Dead Center.

According to the invention, the method for synchronizing the electronic control system is characterized in that it comprises the following steps: a) generation of a phase synchronization signal with the second signal identifying the passage of the pistons in a predetermined position such that at Top Dead Center, this synchronization signal being arbitrarily initialized so that the identification of a predetermined instant in the course of the cycle of each of the cylinders is effected with an indeterminacy of two times in the course of the engine cycle; b) monitoring the operation of the engine and when predetermined conditions are met; c) modifications to the engine control parameters relating to at least two given cylinders whose operating cycles are offset by two engine times, • this modification to the control parameters causing suitable and opposite variations in the level of combustion in these cylinders; d) calculation for the cylinders concerned by the modifications of step c) of an algebraic quantity representative of the variations in the combustion levels, the assignment to each of the cylinders of the corresponding values of the combustion levels deduced from the first signal being operated by exploiting said synchronization signal as defined in step a); e) deduction from the sign of the algebraic quantity representative of the variations in combustion levels between the cylinders, from the accuracy of the synchronization signal and correction of the signal if the initialization arbitrarily carried out in step a) turns out to be erroneous .

According to the invention, the method of developing a synchronization signal is based on the principle of action and reaction.

The action consists in making suitable modifications to the engine control parameters so as to generate opposite direction variations in the combustion level in two cylinders whose cycles are offset by 360 ° crankshaft (or two engine times).

The engine's reaction to these changes in the control parameters results in corresponding changes in the level of combustion which can be identified, for example, by falls and increases in the gas torque (or even variations in instantaneous speed or intake pressure). depending on the engine operating mode.

It is therefore sufficient to match the torque values measured by each of the cylinders concerned by exploiting an arbitrarily defined synchronization signal and to deduce the sign of the difference between the combustion levels of these cylinders if this arbitrarily defined synchronization signal is correct or not, and therefore to correct it if it is erroneous.

Indeed, if the action consists for example (for an engine with four cylinders in line) to enrich the cylinder n ° l and to deplete the cylinder n ° 4 one must therefore observe, all other things being equal, that the new values the torque of cylinder n ° l are greater than the new torque values of cylinder n ° 4. It follows that if the torque values assigned to cylinder no. 1 are indeed much greater than the torque values assigned to cylinder no. 4, it is because the synchronization signal, although arbitrarily initialized, is correctly phase. If, on the other hand, the new torque values assigned to cylinder n ° l are lower than the new torque values assigned to cylinder n ° 4, it is because the synchronization signal used is incorrectly phase, it is then easy to correct it by shifting it by two engine times.

According to another characteristic of the synchronization method which is the subject of the present invention, the calculation provided for in step d) consists in positively counting the combustion levels corresponding to the cylinders for which the modifications of the control parameters must lead to an increase in the combustion levels and negatively the combustion levels corresponding to the cylinders for which the modifications of the parameters of control must result in a decrease in combustion levels.

According to another characteristic of the synchronization method which is the subject of the present invention, the calculation provided for in step d) of the quantity representative of the variations in the combustion levels for the cylinders concerned is carried out by taking into account a given number of engine cycles.

The distribution of the action over several engine cycles consequently limits the amplitude of the variations in the combustion level and therefore makes the progress of the synchronization process undetectable by the driver (absence of jerks in the operation of the engine ). This number of cycles, which can be constant or even depend on the engine operating point, is determined so as to limit variations in combustion levels while allowing rapid implementation of the process.

According to another characteristic of the synchronization method which is the subject of the present invention, the predetermined conditions required in step b) for operating the modification of the control parameters are adapted so that variations in combustion levels cannot be felt by the driver. , these conditions being for example the value of the transmission ratio and / or the maintenance of the engine rotation speed or of the intake pressure within predetermined value ranges. According to another characteristic of the synchronization method which is the subject of the present invention, the predetermined conditions required in step b) to effect the modification of the combustion parameters include stability conditions for all or part of the parameters acting on the combustion level of the engine, such as the engine rotation speed, or the ignition advance, or the intake pressure, or even the stable state of the auxiliary members driven by the engine.

According to another characteristic of the synchronization method which is the subject of the present invention, the modifications to the control parameters provided for in step c) consist of modifications to the quantities of fuel injected into the cylinders concerned.

Changes in the quantities of fuel injected into the cylinders can be carried out by applying, in the formulas for calculating the injection times, a multiplicative correction coefficient mapped according to the engine operating conditions, said coefficient preferably being between 0.7 and 0.99 for one cylinder and between 1.01 and 1.3 for the other.

According to another characteristic of the synchronization process which is the subject of the present invention, the modifications to the quantities of fuel injected into the cylinders concerned are adapted to the operating conditions of the engine and in particular to the pressure of the intake air, so as to produce a variation in the level of combustion in the cylinders which is substantially identical whatever the operating point of the engine.

According to another characteristic of the synchronization method which is the subject of the present invention, the first signal making it possible to follow the level of the combustions in each cylinder uses a quantity representative of the gas torque generated by each of the combustions of the engine.

According to another characteristic of the synchronization method which is the subject of the present invention, the calculation provided for in step d) consists in counting the combustion levels after a delay period adapted according to the modifications of the control parameters operated in step c) .

According to another characteristic of the synchronization method which is the subject of the present invention, the modifications to the engine control parameters provided for in step c) are adapted to generate at least one cyclic variation in the combustion levels in each of the cylinders concerned, each cycle. consisting of a first period during which the combustion level is improved for one cylinder and degraded for the other, and a second period of the same duration as the first period and during which these variations are reversed while keeping substantially the same amplitudes.

Step d) then consists of a: calculation for the cylinders concerned by the modifications of step c) of a quantity algebraic representative of the variations in combustion levels for all of the two periods, the assignment to each of the cylinders of the corresponding values of the combustion levels deduced from the first signal being operated by exploiting the synchronization signal as defined in step a ).

This reversal of the action carried out on each of the two cylinders concerned makes it possible to completely overcome the average combustion level of these cylinders since only the difference between the "high" level and the "low" level is retained. combustions. This therefore makes it possible to overcome the differences in combustion level between the cylinders, differences which can take on significant values in particular with the aging of the engine and could call into question the cylinder keying strategy.

According to another characteristic of the synchronization method which is the subject of the present invention, the modifications to the control parameters provided for in step c) are carried out in a similar manner on several groups of two cylinders (n ° l, n ° 4; n ° 2 , n ° 3) shifted by two engine times.

The greater the number of pairs of cylinders on which variations in combustion levels are operated in the opposite direction, the more quickly we are able to obtain a difference, the sign of which is significant, thereby reducing the time taken to execution of the synchronization process. The aims, aspects and advantages of the present invention will be better understood from the description given below of embodiments of the invention applied to a four-stroke and four-cylinder engine, these embodiments being given by way of non-limiting example, with particular reference to the accompanying drawings, in which:

Figure 1 is a schematic view of the engine control device incorporating the method of the present invention;

FIG. 2 shows the different timing diagrams characterizing the process which is the subject of the present invention.

Referring to Figure 1, we see, presented in a simplified manner, the configuration of an electronic control system of an internal combustion engine implementing the synchronization process object of the present invention. Only the constituent parts necessary for understanding the invention have been detailed.

The internal combustion engine, which is marked 1, is more particularly intended to equip a motor or road vehicle. This four-stroke in-line four-cylinder engine is equipped with an electronically controlled multipoint type fuel injection device by means of which each cylinder is supplied with fuel from a specific electro-injector 5. The opening of each electro-injector 5 is controlled by the electronic control system 7 also called an injection computer. The injection computer 7 determines the quantity of fuel injected and the instant of injection in the cycle according to the operating conditions of the engine on the basis of suitable strategies known moreover such as for example the control of the richness of the fuel air mixture. - fuel admitted into the cylinders at a predetermined set value.

The injection computer 7 conventionally comprises a microprocessor (CPU), random access memories (RAM), read-only memories (ROM), as well as analog-digital converters (A / D), and various interfaces of inputs and outputs .

The microprocessor integrates electronic circuits and appropriate software to process the signals coming from adapted sensors, to determine the states of the engine and to implement predefined operations in order to generate control signals intended in particular for injectors (and coils of ignition in the case of a positive-ignition engine) according to the adapted strategies adopted.

The injection computer 7 is more particularly adapted to operate an indirect injection of fuel of the sequential phased type which consists in triggering each injector 5 in isolation so that the injection of fuel is completed before the opening of the corresponding intake valve (s).

Among the microprocessor input signals include in particular those sent by a crankshaft sensor 22. This sensor 22, for example with variable reluctance, is fixedly mounted on the engine frame to be positioned in front of a measuring crown 12 secured to the flywheel. inertia attached to one end of the crankshaft. This crown 12 is provided at its periphery with a succession of identical teeth and hollows with the exception of a tooth which has been removed so as to define an absolute reference point making it possible to deduce the instant of passage at the Top Dead Center of the piston of a given cylinder of reference, in this case cylinder n ° l.

The sensor 22 therefore delivers a signal Dn corresponding to the movement of the teeth of the crown 12. This signal Dn makes it possible, after processing by suitable calculation means, to generate a TDC signal identifying at each crankshaft half-turn the simultaneous passages in Neutral Top of the pistons of cylinders n ° l and n ° 4 then alternatively the simultaneous passages in Neutral Top of the pistons of cylinders n ° 2 and n ° 3 (The cylinder n ° l being for example the cylinder ie closest to the crown 12 And so on) .

It should be noted that, in the example shown of an engine with four cylinders in line, having an ignition order according to the sequence 1- 3-4-2, the pistons of cylinders n ° l and n ° 4 ( resp. n ° 2 and n ° 3) pass simultaneously to the position Top dead center but at different phases of the engine cycle, one entering the intake phase and the other in the relaxation phase.

The processing of the signal Dn emitted by the sensor 22 also makes it possible to measure the speed of travel of the teeth of the crown 12, and thus to obtain the instantaneous engine rotation speed. This signal Dn is further processed by calculation means described below to produce a signal Cg for measuring the gas torque generated by each of the combustions.

In accordance with FIG. 2, the principle of the method for producing the synchronization signal according to the invention will be described.

The first step of the method which is the subject of the invention consists in creating a NOCYL synchronization signal. This NOCYL signal is more particularly adapted to locate a predetermined instant in the course of the engine cycle used for the phasing of the injection of each of the cylinders, which in the example illustrated is the shift to Neutral High Admission but which could be the shift at the Neutral Low Admission point, or any other time that can be used for the phasing of the injection.

This synchronization signal NOCYL is phase with the TDC signal and it is arbitrarily initialized at 1 (or 0), at the first detection of the passage to Top Dead Center of a reference cylinder, such as cylinder n ° l, which is therefore arbitrarily considered as a Top Dead Center Admission, then it is incremented (modulo four) at each passage to Top Dead Center of a cylinder in the order of succession of combustions in the cylinders.

Given the arbitrary choice made during the initialization of the NOCYL signal, two scenarios arise:

- either the NOCYL signal is correctly initialized, the reference Top Dead Center having been used for the initialization of the NOCYL signal effectively corresponding to an Admission Top Dead Center for cylinder n ° l;

- either the NOCYL signal is poorly phase, the Reference Top Dead Center corresponding to a

Top Dead Center Relaxation for cylinder n ° l (and therefore a Top Dead Center Admission for cylinder n ° 4).

The other stages of the process object of

1 invention will overcome this indeterminacy. To do this, the engine having been started and operating under predetermined conditions for a certain number of cycles, a voluntary modification of the engine control parameters is brought about, and more particularly a modification of the quantity of fuel injected into the cylinders (and therefore of the richness of the fuel mixture injected) by correcting the injection time Ti accordingly.

The modification made which consists in enriching certain cylinders and impoverishing the others is adapted to cause variations in the level of torque in opposite directions between the cylinders shifted in the cycle, by two engine times. It is sufficient to assign the torque values to the corresponding cylinders using the predefined NOCYL signal and to sum them up to deduce from the sign the value thus obtained if the NOCYL signal is indeed phase or not.

The operating conditions required to operate the richness modifications as well as the amplitudes of these modifications are chosen so as to limit the impact of the implementation of the method on the operation of the engine and avoid any phenomenon of jolting of the vehicle. which can be felt by the driver, while allowing safe and indisputable location by analyzing the torque values provided by signal Cg.

The second step of the method therefore consists in determining whether the engine operating conditions allow the richness modifications necessary for the implementation of the invention.

The operating conditions required to limit the impact on engine operation of variations in richness, relate more particularly to the transmission ratio, which must preferably be above a predetermined value, as well as the operating parameters. of the engine and in particular the pressure and the speed which must be within predetermined value ranges. In fact, the longer the transmission ratio, the less the impact of a change in wealth is felt, the inertia of the vehicle filtering for the driver 1 'jerk produced by the sudden change in wealth on the cylinders. Conversely, the shorter the gear, the lower the inertia seen from the engine.

It is therefore preferable to make the wealth modifications outside the short relationships that constitute the first or the reverse gear. On the other hand, at too low speed (idle) any change in richness has a significant impact on the operation and noise of the engine, and the same applies to the intake pressure factor. This results in the development of pressure-rpm operating ranges, adapted to each type of engine by measurements on test benches, within which the process which is the subject of the present invention is preferably operated. .

The operating conditions required must also allow a reliable and indisputable identification of the torque changes resulting from the changes in wealth made. It is therefore appropriate that the alterations detected by means of the gas torque signal Cg result from changes in the richness generated according to the process which is the subject of the present invention and not from the noise affecting the gas torque measurement signal Cg.

To do this, it is preferable to wait for a stabilized operation of the engine defined by stability conditions on the> parameters acting directly on the torque: the engine rotation speed, the intake pressure, the advance to ignition, and maintaining in the same condition of all torque consumers driven by the engine (air conditioning, power steering pump, heated windshield, etc.).

The stability criterion retained can be defined by maintaining the values of the parameters selected within a range of values for a given duration. The ranges of values can then be fixed or else given by function tables of the values taken by these parameters.

The amplitude of the modifications of richness carried out on the various cylinders, is also adjusted according to the operating conditions of the engine to limit the impact of these modifications on the operation of the engine and to avoid any phenomenon of jerk of the vehicle which can be felt by the driver, while allowing a sure and indisputable location through the analysis of the signal Cg of the resulting torque changes.

The operating conditions necessary for the process according to the invention being met, the third step of the process is launched.

It consists, according to the example illustrated in Figure 2, by a modification of the richness of the different cylinders. The modification of the richness is adapted to cause variations in torque in the opposite direction for the cylinders offset by 360 ° crankshaft or even by two engine times in the cycle. One cylinder is therefore enriched while the other is depleted. These modifications are made by applying multiplicative correction coefficients in the formula for calculating the injection time of each of the cylinders, the enrichment coefficient being of type 1 + PARTINJ and the depletion coefficient 1 - PARTINJ, with PARTINJ between 0.01 and 0.30 and calibrated in an appropriate table depending on the engine operating conditions and in particular the intake pressure.

Preferably, the PARTINJ correction coefficient is chosen so that the alteration of the corresponding gas torque is between predetermined threshold values Smin and Smax, Smin corresponding to the minimum value below which the reduction in torque is not discernible of the noise affecting the signal Cg, this threshold Smin therefore has a predetermined value as a function of the noise level observed and of an adjustable margin, and Smax corresponding to the maximum value above which the decrease in torque causes a jerk.

More preferably, the values of the correction coefficient are chosen to produce a comparable effect over the entire pressure range, which is obtained by choosing values of the PARTINJ coefficient according to a function of the intake pressure.

The richness modifications are preferably carried out according to a two-stroke cycle. During a first period of given duration (N engine cycles) one depletes (Ti x (1- PARTINJ)) the cylinders n ° 1 and n ° 2 while one enriches (Ti (1 + PARTINJ)) the phase-shifted cylinders by two-stroke engine n ° 4 and n ° 3. Then for a second period of the same duration, the reverse modification is effected, namely, we enrich (Ti x (1 + PARTINJ)) the cylinders n ° 1 and n ° 2 while we deplete (Ti x (1-PARTINJ) ) the phase-shifted cylinders of two-stroke engine no. 4 and no. 3.

The choice of the number N is predetermined. Its value results from a compromise between the speed of implementation of the synchronization process and the amplitude of the torque variations (ie again the amplitude of the PARTINJ coefficient).

Simultaneously with the richness modifications carried out during this third step, the method which is the subject of the invention operates in a fourth step the summations of the gas torque measurements provided by the signal Cg corresponding to each of the cylinders. The assignment of the torque values supplied by the signal Cg to the corresponding cylinders is effected by using the predefined NOCYL signal.

The summations to be representative of the algebraic variation of the level of torque of each of the cylinders, take into account positively the torque corresponding to an enrichment and negatively that corresponding to a depletion. These summations are then combined to constitute an algebraic quantity representative of the difference in torque between the cylinders.

It then suffices in a last step to know the sign of this last quantity representative of the torque difference between the cylinders to deduce therefrom the phasing accuracy of the NOCYL signal.

Indeed, let SI be the sum for the first period of the gas couples corresponding to the different cylinders. The sum SI is operated by positively accounting for the torque values corresponding to the rich cylinders and negatively for the torque values corresponding to the poor cylinders.

So we have :

N (I) SI = ^ Cg "4, i + 0 ^ ^* 3.1 -Cg" l, i -Cg'2, ii≈n with Cg 'j, i value of the torque generated by combustion in the identified cylinder as being

• • • ièms cylinder n ° j by the NOCYL signal during the i engine cycle following the start of the first period. The summation begins with a time delay of n-1 cycles (at least one cycle) so that the torque measurements taken into account effectively correspond to the new wealth.

Given the indeterminacy of two engine times linked to the signal NOCYL, there are therefore two possible cases, either the signal NOCYL is correctly phase and the value Cg 'j, i really corresponds to the value of torque Cgj, i of the cylinder j, or the signal NOCYL is incorrectly phase and the value Cg 'j, i corresponds to the torque value of the cylinder k two phase shifted with respect to the cylinder j.

As a first approximation, we can consider that the excess or withdrawal of fuel (+/- Ti x PARTINJ) operated on the cylinders causes alterations in torque of the same value but of opposite sign between the cylinders. We then have:

Cgl, i = Cgi - ΔCg

Cg2, i = Cg2 - ΔCg

Cg3, i = Cg3 + ΔCg Cg4, i = Cg4 + ΔCg with Cgj mean value of the torque at the operating point considered for cylinder n ° j and ΔCg torque correction value strictly positive.

The formula (I) therefore becomes:

if the NOCYL signal is indeed phase

NOT

(1.1) IF = (∑Cg4 + Cg3-Cgl-Cg2) + (N-n) xΔCg; ι-n or SI = (N-n) x ((Cg4 + Cg3-Cgl-Cg2) + ΔCg)

and if the NOCYL signal is out of phase -

NOT

(1.2) IF = (Tcgl + Cg2-Cg4-Cg3) - (N-n) xΔCg.

let SI = (N-n) x ((Cgl + Cg2-Cg3-Cg4) - ΔCg)

The sum S2 of the gas couples corresponding to the different cylinders is produced in parallel for the second period, the sum S2 being operated by positively accounting for the torque values corresponding to rich cylinders and negatively the torque values corresponding to poor cylinders.

We thus have:

NOT

(II) S2 = ∑Cg'l.i + C ^ i-Cg ^ i-Cg ^ i with Cg 'j, i value of the torque generated by combustion in the cylinder identified as being cylinder n j by the NOCYL signal during the i ¹¹²¹ ™ ³ engine cycle following the start of the second period.

This second summation begins with the same timing of n-1 cycles (at least one cycle) so that, on the one hand, the recorded torque measurements effectively take into account the new wealth modifications and, on the other hand, that the sums SI and S2 have the same number (Nn) of terms.

Similarly, taking into account the indeterminacy of two engine times linked to the signal NOCYL, there are therefore two possible cases, either the signal NOCYL is correctly phase and the value Cg 'j, i really corresponds to the torque value Cgj, i of cylinder j, that is to say the signal NOCYL is incorrectly phase and the value Cg 'j, i corresponds to the torque value of cylinder k two phase shifted with respect to cylinder j.

We can also and similarly consider that the excess or withdrawal of fuel (+/- Ti x PARTINJ) operated on the cylinders during this second period causes changes in torque of the same value but of opposite sign between the cylinders and corresponding to the changes in the first period. We then have:

Cgl, i = Cgi + ΔCg;

Cg2, i = Cg2 + ΔCg;

Cg3, i = Cg3 - ΔCg;

Cg4, i = Cg4 - Δ Cg; with Cgj mean value of the torque at the operating point considered for cylinder n ° j.

Formula (II) therefore becomes:

if the NOCYL signal is indeed phase

NOT

(II.1) S2 = (TCgl + Cg2-Cg4-Cg3) + (N-n) xΔCg

either S2 = (N-n) x ((Cgl + Cg2-Cg3-Cg4) + ΔCg)

and if the NOCYL signal is out of phase

N (II- 2) S2 = (Cg4 + Cg3-Cgl-Cg2) - (N-n) xΔCg.

let S2 = (N-n) x ((Cg4 + Cg3-Cgl-Cg2) - ΔCg)

One then operates the addition of the two sums SI and S2 so one obtains the total S: (III) S = SI + S2

if the NOCYL signal is indeed phase

(111.1) S = 2 x (N-n) x ΔCg

if the NOCYL signal is out of phase

(111.2) S = - 2 x (Nn) x ΔCg We therefore see that the sign of the sum S provides direct information on the accuracy of the signal NOCYL: if S> 0 then NOCYL is indeed phase, and if S <0 then NOCYL is badly phase, it is then possible to correct it by two-stroke engine phase shift.

To improve the performance of the strategy implemented, the decision criterion indicating whether the NOCY1 signal good or bad phase consists not in comparing S with 0 but with a threshold value e (e being a strictly positive calibrated value). Then: if S> e then NOCYL is well phase, and if S <-e then NOCYL is badly phase.

The introduction of e gives a safety margin to the strategy. In the case where S would be between -e and e then no decision is made and the request is made to make a new attempt at cylinder keying.

According to the method described, the sum S is independent of the mean torque values of the different cylinders. It only depends on the change in torque resulting from the correction coefficient applied 1 +/- PARTINJ and the number of engine cycles taken into account. Torque dispersions between the cylinders are not involved in the implementation of the method according to one ^• invention.

This method has many advantages. The calculation of the sum S being calculated with a large number of torque values, the influence of noise on the torque measurement decreases, the errors compensating each other. Furthermore, since the calculation is based on a large number of torque values, it is possible to operate with a small torque deviation ΔCg and in particular less than the noise affecting the signal Cg, which further limits the impact of the strategy on the engine behavior.

Similarly, the strategy implemented is freed from the error made in the calculation of the gas torque Cgj, i. Indeed, the rich-poor permutation partially compensates for the error made on the estimation of the torque, we add the error when the cylinder is rich, we subtract the error when the cylinder is poor. This strategy overcomes instabilities on the couple that may exist. The impact of poor combustion is diluted by the large number of torque values taken into account.

Furthermore, the symmetry between the depletion and the enrichment of the cylinders makes it possible to maintain a substantially constant overall richness and therefore not to affect the depollution of exhaust gases by catalytic conversion.

Of course, the invention is in no way limited to the embodiment described and illustrated, which has been given only by way of example.

On the contrary, the invention includes all the technical equivalents of the means described as well as their combinations if these are carried out according to his spirit.

Thus, it is possible to disarm the NOCYL signal by only modifying the richness ^" of a single pair of cylinders whose operating cycles are offset by two engine times such as cylinders n ° l and n ° 4 (or n ° 2 and No. 3) This variant limits the modifications made to the engine control parameters and therefore the impact on the behavior of the latter.

The previous formulas then become

NOT

(I ') IF = (∑Cg'4, i-Cg'l, i) ι-n

N (II ') S2 = (∑Cg'l, i-Cg'4, i) i = n

(III ¹ ) S = SI + S2 with: if the signal NOCYL is indeed phase (III '.1) S = (Nn) x ΔCg that is to say S °>e; and if the NOCYL signal is badly phase (III '.2) S = - (Nn) x ΔCg, that is to say S ° <-e.

Thus, it is possible in a second variant to disarm the NOCYL signal without directly eliminating the average torque values by reversing the wealth modifications for each of the cylinders concerned (a rich period then a lean period or vice versa), the modification cycle does not counts more then just one period.

We then have the formulas: (I ") IF = (∑Cg'4, i + Cg'3, .- Cg ^, l _f ι-Cg ^, 2, i)

and

(III ") S = SI

if the NOCYL signal is indeed phase:

NOT

(I ".l) IF = (∑Cg4 + Cg3-Cgl-Cg2) + (N-n) xΔCg ι = n and if the NOCYL signal is badly phase:

NOT

(I ".2) IF = (Cgl + Cg2-Cg4-Cg3) - (N-n) xΔCg.

If we consider as a first approximation that Cgi # Cg2 # Cg3 # Cg4 we therefore have:

S = (N-n) x ΔCg if the NOCYL signal is indeed phase and S = - (N-n) x ΔCg if the NOCYL signal is badly phase.

The performance of this second variant therefore rests on the similarity of the values of mean torque between the cylinders. The greater the dispersions between the average torque values of the cylinders, the less effective such a strategy is. If on the other hand the dispersions are small, this strategy is effective and quick to implement.

Obviously we can combine the two variants between them. Likewise, the strategy initially presented for a cycle of modifications breaking down into two distinct periods of opposite direction can be extended over several successive cycles.

As technical equivalents of the means described, changes in wealth may be replaced by any other action on the engine control parameters likely to cause a measurable deterioration in the quality of combustion. This is the case with the ignition advance in the case of a spark-ignition engine, withdrawal of the ignition advance has an effect on the gas torque which is similar to a depletion. To do this, the ignition device must be of the static ignition type (one ignition control per cylinder).

Likewise, the process which is the subject of the present invention can be used with a NOCYL signal for controlling the injectors, no longer using the tracking of the top admission neutral gear shifts of the various cylinders but any other predetermined instant in the course of the engine cycle which may constitute a marks such as the transition to the Top Relaxation Neutral Center (or even the Low Admission Neutral Center, etc.).

Thus, it is possible to monitor the variations in the combustion levels corresponding to the modification of the engine control parameters independently of the measurement of the average gas torque, for example by simple analysis of the instantaneous engine rotation speed, or by means for analyzing the pressure ^"the intake air, or by means for analyzing the candles ionisation current (for spark ignition engines), or by means of composition analysis exhaust gases using a richness sensor, etc. As regards the implementation of the device for measuring the gas torque resulting from combustion, whatever the embodiment chosen, it can be produced in various forms: either with analog electronic components for which the summers, comparators and other filters are made using operational amplifiers; - either with digital electronic components that would perform the function in wired logic; or by a signal processing algorithm implemented in the form of a software module component of an engine control software system operating the microprocessor of an electronic computer. or again, by a specific (custom) chip, the hardware and software resources of which have been optimized to carry out the functions which are the subject of the invention: microprogrammable chip or not, encapsulated separately or else all or part of a coprocessor installed in a microcontroller or microprocessor etc.

Likewise, the invention includes all the technical equivalents applied to an internal combustion engine whatever its type of injection, the fuel used diesel or petrol or even, the number of its cylinders.

Claims

[1] Method for producing a synchronization signal (NOCYL) for the electronic control system (7) of a multi-cylinder four-stroke cycle internal combustion engine (1), this synchronization signal (NOCYL) allowing the identification of a predetermined instant in the progress of the engine cycle in each of the engine cylinders, such as the passage to the Intake Top Dead Center, said NOCYL signal being deduced from a first signal (Cg) and a second signal (PMH) produced by suitable processing means using in particular the information provided by an angular position sensor (22) cooperating with a toothed ring gear (12) carried by the crankshaft of the engine, said first signal (Cg) providing an estimate of the level of successive combustions occurring in the cylinders of the engine and said second signal (TDC) identifying the movement of the pistons and in particular their passage into a predetermined position of the operating cycle such as at Top Dead Center, characterized in that it comprises the following steps: a) development of a synchronization signal (NOCYL) in phase with the second signal (PMH) identifying the passage of the pistons in a predetermined position such as Top Dead Center, said synchronization signal (NOCYL) being initialized arbitrarily so that the identification of a predetermined moment in the progress of the cycle of each of the cylinders, such as the passage to the Inlet Top Dead Center, or operated with an indeterminacy of two times in the progress of the engine cycle; b) monitoring of engine operation and when predetermined conditions are met; c) modifications of the control parameters (Ti) of the engine concerning at least two given cylinders (n°1 and n°4) whose operating cycles are offset by two engine strokes, said modification of the control parameters causing suitable variations and in opposite direction to the level of combustion in these cylinders; d) calculation for the cylinders (n°1, n°4) concerned by the modifications of step c) of an algebraic quantity (S) representative of the variations in the combustion levels, the allocation to each of the cylinders (n °l,n°4) corresponding values of the combustion levels deduced from the first signal being operated by exploiting said synchronization signal (NOCYL) as defined in step a); e) deduction from the sign of said algebraic quantity (S) representative of the variations in combustion levels between the cylinders (n°1, n°4), of the accuracy of the synchronization signal (NOCYL), and correction of said signal if the initialization arbitrarily carried out in step a) turns out to be erroneous.

[2] Method for producing a synchronization signal (NOCYL) according to claim 1, characterized in that the calculation provided for in step d) consists of counting positively the combustion levels corresponding to the cylinders for for which changes in the control parameters should result in an increase in combustion levels and negatively the combustion levels corresponding to the cylinders for which changes in the control parameters should result in a decrease in combustion levels.

[3] Method for producing a synchronization signal (NOCYL) according to any one of claims 1 to 2, characterized in that the calculation provided for in step d) of the quantity (S) representative of the variations in the combustion levels , is operated by taking into account a given number of engine cycles (N-n; 2 x (N-n)).

[4] Method for producing a synchronization signal (NOCYL) according to any one of claims 1 to 3, characterized in that the predetermined conditions required in step b) to carry out the modification of the control parameters are adapted so that variations in combustion levels cannot be felt by the driver, said conditions being for example the value of the transmission ratio and/or maintaining the engine rotation speed or the inlet pressure within predetermined value ranges .

[5] Method for producing a synchronization signal (NOCYL) according to any one of claims 1 to 4, characterized in that the predetermined conditions required in step b) to carry out the modification of the parameters of combustion include conditions of stability of all or part of the parameters acting on the combustion level of the engine, such as the engine rotation speed, or the ignition advance, or the inlet pressure, or even the stable state of the auxiliary organs driven by the engine.

[6] Method for producing a synchronization signal (NOCYL) according to any one of claims 1 to 5, characterized in that the modifications of the control parameters provided for in step c), consist of modifications of the quantities of fuel injected (Ti) into the cylinders concerned (n°1, n°4).

[7] Method for producing a synchronization signal (NOCYL) according to claim 6, characterized in that the modifications of the quantities of fuel injected (Ti) in the cylinders concerned (n°1, n°4) are adapted to the conditions of operation of the engine and in particular to the pressure of the intake air, so as to produce a variation (ΔCg) of the level of combustion in the cylinders which is substantially identical whatever the operating point of the engine.

[8] Method for producing a synchronization signal (NOCYL) according to any one of claims 1 to 7, characterized in that the first signal (Cg) making it possible to monitor the level of combustion in each cylinder uses a quantity representative of the torque gas generated by each combustion of the engine.

[9] Method for producing a synchronization signal (NOCYL) according to any one of claims 1 to 8, characterized in that the calculation provided for in step d) consists of counting the combustion levels after a suitable delay period (n-1 cycles) following the modifications of the control parameters made in step c).

[10] Method for producing a synchronization signal (NOCYL) according to any one of claims 1 to 9, characterized in that the modifications of the motor control parameters provided for in step c) are adapted to generate at least one cyclic variation of the combustion levels in the cylinders concerned (n°1, n°4), each cycle consisting of a first period during which the level of combustion is improved (+ΔCg) for a cylinder (n°4) and degraded (-ΔCg) for the other (n°l), and a second period of the same duration as said first period and during which these variations are reversed while maintaining substantially the same amplitudes (ΔCg).

[11] Method for producing a synchronization signal (NOCYL) according to claim 10, characterized in that step d) then consists of: calculation for the cylinders (n°1, n°4) affected by the modifications of step c) of an algebraic quantity (S) representative of the variations in the combustion levels for all of the two periods, the assignment to each of the cylinders (n°1, n°4) of the values corresponding combustion levels deduced from the first signal being operated by exploiting said synchronization signal (NOCYL) as defined in step a).

[12] Method for producing a synchronization signal (NOCYL) according to any one of claims 1 to 11, characterized in that the modifications of the control parameters provided for in step c) are carried out in a similar manner on several groups of two cylinders (n°1, n°4; n°2, n°3) offset by two engine strokes.