EP1169629A1

EP1169629A1 - Method for engine misfire detection in multi-cylinder internal combustion engines with multi-cylinder spark ignition

Info

Publication number: EP1169629A1
Application number: EP01909516A
Authority: EP
Inventors: Michael Lehner; Heiko Oertel; Klaus Ries-Mueller
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2000-02-11
Filing date: 2001-01-24
Publication date: 2002-01-09
Also published as: AU780071B2; WO2001059422A1; KR20020000872A; CN1363034A; JP2003522887A; DE10006004C1; CN1174233C; US20020157459A1; AU3723601A; US6918288B2

Abstract

The invention relates to a method for engine misfire detection in multi-cylinder internal combustion engines with multi-cylinder spark ignition. According to the inventive method, rough running values are detected during every crankshaft rotation by measuring the segment times. Said segment times comprise the piston movement of individual cylinders according to intervals that correspond to their ignition intervals in which the crankshaft covers a pertaining angle of the circular segment. The inventive method allows detection of a misfire in the corresponding circular segment zones of the crankshaft on the basis of the detected rough running values (LUT) by comparing a desired value with a threshold value (SW2). If a misfire in a crankshaft segment zone with multi-cylinder spark ignition is detected, a misfire operation is produced in one of these cylinders. Once the misfire operation is carried out by the engine intervention, the cylinder is detected which has a misfire without engine intervention by measuring the change in the rough running values in the crankshaft segment zone with multi-cylinder spark ignition.

Description

Process for misfiring in multi-cylinder internal combustion engines with several cylinders firing simultaneously

The invention relates to a method for misfire detection in multi-cylinder internal combustion engines with several cylinders firing simultaneously with the features mentioned in the preamble of claim 1.

State of the art

Processes for misfiring detection are used both in gasoline engines in order to identify non-circular engine operation, which can be caused by valve coking or, for example, in the case of direct-injection engines due to quality variations in the characteristics of injection valves, and to minimize them by suitable control devices, and especially by misfires to avoid deterioration of the exhaust gas values due to an engine defect and to protect the exhaust gas catalytic converter. If a motor defect visible through misfiring is recognized, the driver can be warned, for example, by a warning lamp. -? -

be advised to arrange for the fastest possible repair.

Such methods make use of the knowledge that a non-combustion within a cylinder of an internal combustion engine leads to characteristic changes in the torque curve of the engine compared to normal operation. By comparing the torque curves, a distinction can thus be made between normal operation of the engine without misfires and what is known as a misfire-prone operator. Intermittent operation of one or more cylinders contributes to the overall torque curve of the engine with a smaller contribution, this contribution being able to be determined by recording the actual torques of the cylinders by evaluating the time curve of the crankshaft or camshaft rotation. According to the generic method, a specific range of piston movement of each cylinder or other cylinders that ignite at the same time is assigned a crankshaft angle range known as a segment. The segments relating to each cylinder or cylinders are realized, for example, by markings on a sensor wheel coupled to the crankshaft. The segment time, ie the time in which the crankshaft sweeps over the corresponding range of the segment, depends essentially on the energy converted in the combustion cycle. Misfires spark due to the lack of torque contribution to an increase in ignition-synchronized summarized segment times, which are determined for each segment by scanning the markings on the sensor wheel by a suitable sensor. The smoother the engine runs, the smaller the differences between the individual segment times. According to methods already known from the prior art, for example DE-OS 4138765, a measure of the uneven running of the engine is calculated from differences in the segment times, additional basic conditions, such as the increase in engine speed during vehicle acceleration, being computationally compensated , The uneven running value calculated in this way for each ignition of a cylinder or a plurality of cylinders firing simultaneously is compared in a subsequent method step with a setpoint comparison with a threshold value. If the determined uneven running exceeds the threshold value, which may depend on operating parameters such as load and speed, this is evaluated as a misfire of the cylinder in question. If misfires have been determined, their number is added. If a certain misfire rate is exceeded, for example, a suitable warning device points to this irregularity hm.

The described method from the prior art has in principle been retained for internal combustion engines with individually firing cylinders. The problem arises with internal combustion engines with several cylinders firing simultaneously, that in the event of misfire detection for a crankshaft segment in which, for example, two cylinders ignite simultaneously, no recognition can be made as to which of the two cylinders has misfires. In addition, there is the problem with internal combustion engines with several cylinders that ignite at the same time that, if one of these cylinders is subject to misfiring, the resulting torque drop, which is measured on the crankshaft, is present, but is considerably less in contrast to the failure of an individually igniting cylinder , because the other cylinder in question has a normal combustion process.

The result of this is that when comparing the rough running values of crankshaft segments with several cylinders that ignite at the same time, misfires may not be recognized due to the threshold value that is required to be higher in the case of individual ignition.

Advantages of the invention

The method according to the invention for misfiring detection of combustion misfires offers the advantage that misfires can also be assigned when two cylinders ignite simultaneously and thus make a common torque contribution. In addition, it can be ensured that if several are ignited at the same time In spite of the fact that the distance between the uneven running values is smaller in this case, reliable detection of combustion misfires occurs. These advantages are achieved in that from the determined uneven running values for crankshaft segment segments with several cylinders firing at the same time, by comparing the target value with a threshold value that is ace lower than the speed for the misfire test with crankshaft cylinder zones with individual ignition segments. a misfire in the opening crankshaft segment areas can be determined, or it can first be assumed that there is a misfire in one of the simultaneously igniting cylinders. In order to determine which of the cylinders is affected by the misfire, misfire of the cylinders is brought about by a suitable engine intervention. This can be, for example, the suppression of the injection for the cylinder in question. After a cylinder has thus been switched off or blanked out, the cylinder which has a misfire without engine intervention is determined by measuring the change in the uneven running values in the relevant crankshaft range with the simultaneously igniting cylinders. If the uneven running values remain unchanged compared to the values determined before the engine intervention of the cylinder deactivation, the deactivated cylinder was not involved in the torque generation even before it was activated. changed After a cylinder has been switched off, the uneven running value can be assumed that the switched-off cylinder has no misfires and only through the induced switch-off does the crankshaft segment in question no longer provide any torque contribution at all. The measurement of the change in the uneven running value can be carried out on the one hand by comparing the values before and after the cylinder shutdown, but it has proven to be particularly advantageous to measure the uneven running value within the framework of a setpoint comparison with the threshold value for the misfire and delivery rate. The relevant threshold value permits reliable misfire detection and is already stored in the system as a characteristic value.

Further εpεziεllε embodiments of the method according to the invention result together with the technical teaching of claim 1 from the features of the subclaims.

In this connection, it has proven to be expedient that, for an additional check of the cylinder subject to misfire, the engine intervention is to be applied in a further process step to the cylinder that was not initially deactivated and not subject to misfire, wherein the cylinder previously identified as subject to misfire is simultaneously switched on. After this process step has been carried out, the measurement of the Funruhewertεs determined in the relevant crankshaft segment area. A corresponding increase in the uneven running value serves as a final indication that the cylinder which has already been identified as misfiring is really affected, since in this case both cylinders do not make any torque contribution due to the corresponding switchover.

The further measurement of the change in the uneven running values carried out as part of the check can also be carried out by comparing the setpoint value with the threshold value for misfire detection in the case of single cylinder ignition.

drawings

The method according to the invention is explained in more detail below with reference to the attached drawings. It shows:

FIG. 1: a schematic representation of the crankshaft circle segment around the ignition TDC in an 18-cylinder engine and FIG. 2: a flow chart of the method according to the invention.

Description of the execution example

The method according to the invention can be applied, for example, to an 18-cylinder engine, the engine being composed of three cylinder banks A, 3 and C stands. A crankshaft revolution of 360 degrees is divided into six crankshaft segments in FIG. There are therefore a total of six ignitions in different cylinders of the engine during a crankshaft revolution, the cylinders of cylinder bank A igniting individually, whereas each cylinder of cylinder banks B and C have a common ignition time. The ignition sequence for a crankshaft revolution shown in FIG. 1 is thus exemplified as follows:

1. Ignition process: cylinder 1 of bank A

2. Ignition process: cylinder 1 from bank B simultaneously with cylinder 1 from bank C

3rd ignition process: cylinder 2 from bank A 4th ignition process: cylinder 2 from bank B simultaneously with cylinder 2 from bank C

5. Ignition process: cylinder 3 of bank A

6. Ignition process: cylinder 3 from bank B at the same time m t cylinder 3 from bank C

The further ignitions of the other cylinders are constructed analogously to the ignition sequence listed above.

Within the crank segment shown in FIG. 1, the individual cylinders of the cylinder bank A therefore make a torque contribution with each ignition and, analogously, the jointly igniting cylinders of the cylinder banks B and C likewise make a common torque contribution during a crankshaft segment. The furdel shaft segment corresponds to the movement of a cylinder piston piston of cylinder bank A or cylinder banks B and C during the expansion phase of the internal combustion engine after the ignition point.

The values of the uneven running LUT which are decisive for the detection of combustion misfires result as a function of the segment times, ie. H. the times that the crankshafts, for example FIG. 1, schematically illustrate the six individual sub-segments of a total revolution. Incomplete combustion or misfiring within a crankshaft segment leads to a reduced torque output within this segment, and consequently to an increase in the time span by which the crankshaft covers the corresponding segment. The segment times can be scanned, for example, by a sensor wheel connected to a crankshaft or camshaft, on which the segment range limits are marked, which can be scanned by a suitable sensor. The rough running values LUT are formed therefrom in a manner known from the prior art and serve as a basic value for the misfire detection.

Before the ascertained uneven running values LUT are used for misfire detection, the presence of sensor wheel errors (inaccuracy of the marking) may be known by interposing corrective elements. B. corrected by Fuεlon adaptation. FIG. 2 shows the method for misfire detection in an 18-cylinder engine with three cylinder banks A, B and C as part of a block diagram. After calculating the rough running values LUT m of a calculation unit 1, these are fed to a comparison block 2. In comparison model 2, the incoming rough running value LUT is compared with a fixed threshold value SW _X. At the same time, a check is carried out as to whether the running values belong to a segment of the cylinder bank A., that is to say to an individually igniting cylinder, or whether the value is to be assigned to the cylinder banks 3 and C, ie two cylinders of this cylinder bank that ignite at the same time. For reasons of clarity, the query to which of these two segment types the respective uneven running value LUT is to be assigned is not shown in FIG. 2.

If the evaluation unit 2 determines that the uneven running value LUT of a segment of the cylinder bench A is greater than the threshold value SW _X , there is a misfire of the cylinder in question. This information can be sent to a control unit 7 which, on the basis of the determined running irregularities, calculates adjustment or correction factors individually for a change in the detection time or the ignition time of the cylinder affected by a misfire, so that after the ignition time has been corrected or E - peak time to avoid dropouts. As an alternative to the calculation of cylinder-specific equalization or correction factors, the misfires of the relevant cylinder can be paid in order to notify the driver of a possible defect in the engine, for example by lighting up a warning lamp, in the event of a corresponding number of misfires. With regard to the accuracy of its misfire detection, the method described so far is unproblematic for those segment areas which are assigned to the cylinder bench A with the individual igniting cylinders. If a combustion engine takes place in the simultaneously igniting cylinders of cylinder banks B and C, the torque delivered is reduced compared to the segments of cylinder bank A by only 50% of the torque reduction that would occur if one cylinder bank a cylinder failed. Since the comparative threshold value S _{x is selected} with a corresponding safety factor, it cannot be ruled out that a misfire due to the lower torque reduction and the resulting smaller values of the uneven running LUT may result in a misfire of one of the two simultaneously igniting cylinders of the cylinder banks B and C is not recognized as a misfire. For this reason, the uneven running value LUT determined is fed to a second comparison means 3, which is compared with a second threshold value SW ₂ . If the unsteady running LUT is less than the threshold SW _t , then, according to the evaluation module 3, none of the two are identical. a cylinder misfire occurs and the combustion misfire is terminated.

On the other hand, if the evaluation module 3 determines that the uneven running value LUT is greater than the second threshold value SW_, it can be assumed that one of the two simultaneously igniting cylinders has a combustion misfire. In this case, a control unit 4 switches off one of the two cylinders, in the present exemplary embodiment the cylinder of the cylinder bank B. The shutdown takes place, for example, by undermining the injection, which has the result that an artificial dropout is brought about for the cylinder in question. The cylinder deactivation results in two possibilities for the continuously determined uneven running LUT of the two simultaneously igniting cylinders. If the deactivated cylinder is at the same time the cylinder originally associated with dropouts, the uneven running value will not change, since in this case the moment released by the second cylinder is still provided. In this case, a dienendεs to weitεrεn hedge Prufungsvεrfahren zusatzlichε Sicherhεit may ben for ge ^¬ that is aussetzεroεhaftet in the present case, the cylinder dεr Zy lmderbank ^¬ B. Diesεs Prüfver ^¬ drive is explained below. The second possibility, which results from switching off the cylinder of cylinder bank B, is to increase the rough running values LUT of the corresponding crankshaft segment. Such an enlargement occurs when the switched-off cylinder, ie in this case the cylinder of cylinder bank B, was not subject to misfires before the switch-off. In this case, an increase in the uneven running values indicates that both the misfiring cylinder of the cylinder bank C and the deactivated cylinder of the cylinder bank B now make no torque contribution. From this it follows that misfires are present on the cylinder of the cylinder bank C, which can be eliminated either by means of equalization or correction factors for injection time or ignition point, calculated from the current uneven running values LUT, or can be counted with defects on the engine and with a corresponding number of drivers gεmεldεt, so that this can arrange a repair.

Thus, the fact that when a cylinder igniting at the same time ignites or does not increase the uneven running values takes place, a decision is made as to which cylinder cylinder B and C is at risk.

In FIG. 2, two additional process steps are additionally indicated, which can serve as additional safeguards as to whether the The previously described method of determining which cylinder cylmderoank C is really subject to exposure.

The additional method steps provide, after checking the change in the uneven running value as a result of the cylinder deactivation in the case where there is no increase in the uneven running value, the cylinder of the cylinder bank B which has been switched off by then is switched on again by a control unit 5, whereas the opposite the cylinder bench C is switched off. If there is then an increase in the uneven running values for the crankshaft segment in question, it can be concluded with absolute certainty that there is a misfiring operation on the cylinder B of the cylinder bank B that has been re-activated.

The checking of the uneven running value LUT to determine whether there is an increase after switching on a cylinder bank can expediently be carried out by carrying out a comparison of the uneven running values LUT with threshold values SW ₃ , the threshold values SW ₃ being of the order of magnitude that of the Threshold values SWi can correspond.

In addition to the use of internal combustion engines with cylinders that ignite at the same time, the described method according to the invention can also be used with internal combustion engines in which a cylinder for better combustion of the gas mix two spark plugs are used. Here the method can be used to sense the failure of a spark plug, since in this case too there is a loss of torque in the corresponding crankshaft segment. In appli ^¬ extension of the method, the threshold values SW_, SW ₂ and SW ₃ are adapted accordingly, since during menteinbußε fails over a spark plug, in contrast to the use of the above method at gεschildεrtεn two simultaneously firing cylinders only to a maximum torque of 20% leads , In addition, it is conceivable to calculate the uneven running LUT directly from the different torque values of the individual crankshaft segments, the torque values being determined by means of a torque sensor on the crankshaft without determining the uneven running values by detouring the determination of segment times have to.

Claims

1. Method for misfiring in multi-cylinder internal combustion engines with several cylinders firing at the same time, in which each crankshaft rotation occurs

- Uneven running values are determined by measuring gmentεgment times, the segment times comprising the times corresponding to the piston movement of individual cylinders after their ignition time, in which the crankshaft sweeps over an associated circular segment angle range, from the determined uneven running values for circular segment angle ranges of individually igniting cylinders by a desired value A misfire in these crankshaft circle segment areas is determined with a threshold value, characterized in that

- From the determined uneven running values (LUT) for crankshaft areas with honor simultaneously igniting cylinders by comparing the setpoint with a threshold value (SW ₂ ), which is lower in value than the threshold value (SW ^ for the crankshaft igniter areas with individually igniting the crankshaft ends the relevant crankshaft circuit ranges are assumed, - in the event of an assumed misfire in a crankshaft segment area with simultaneously igniting cylinders in one of these cylinders, a misfire is brought about by suitable engine intervention and

by measuring the change in the uneven running values in the crankshaft segment with the simultaneously igniting cylinders after the misfire operation caused by the engine intervention of the cylinder, which has a combustion misfire without engine intervention, is determined.

2. The method of combustion exposure according to claim 1, characterized in that the measurement of the change in the rough running values (LUT) in the crankshaft segment regions with simultaneously igniting cylinders is carried out by means of a setpoint comparison with the threshold value (SW _X ) for the misalignment in the case of single-cylinder ignition.

3. The method for combustion interruption according to claim 1 or 2, characterized in that for testing the intermittent combustion process of the engine intervention for guiding the misfire operation on the cylinder which is not subject to misfire, the cylinder is used and is used as the intermittent agent

- then by a further measurement of the change in the running unevenness in the respective one A crankshaft segment is carried out with the cylinders firing at the same time.

4. A method for combustion detection according to claim 3, characterized in that the further measurement of the change in the rough running values (LUT) in the crankshaft segment areas with simultaneously igniting cylinders is carried out by means of a setpoint comparison with the threshold value (SWi) for the misfire detection with single-cylinder ignition ,