The present invention relates to a method for making available an improved phase signal of a phase sensor at a camshaft of an internal combustion engine immediately after switching on the phase sensor and/or the internal combustion engine.
In multi-cylinder internal combustion engines having electronic injection, it is usually calculated in the engine control unit when and how much fuel is to be injected per cylinder, and when the optimal ignition point will occur. In order for these calculations to be able to be carried out correctly, the respective setting of the crankshaft and the camshaft have to be known. In published European patent document EP 0017933, for example, it is described that the crankshaft and camshaft are each connected to a disk on whose surface at least one reference mark has been applied, and on the crankshaft disk, in addition, a plurality of similar markings, also known as increments, have been applied.
The two rotating disks are scanned by stationary sensors. From the sequence in time of the signals supplied by the sensors in the form of pulses, one may gather a single-valued statement concerning the setting of the crankshaft and the camshaft, and appropriate control signals may be formed in the engine control unit for injection or ignition.
From published German patent document DE 41 41 713, it is known that one may provide a signal-generating wheel at the camshaft, in addition to the one at the crankshaft which has a disk having a plurality of markings and having a bench mark or reference mark formed by two missing markings. This signal-generating wheel at the camshaft has markings of different lengths, adjusted to the number of cylinders, which the phase signal of the phase sensor reproduces. The phase signal of the phase sensor is drawn upon for cylinder identification.
From published German patent document DE 43 10 460, it is known that one may carry out the synchronization of the engine control unit via specially developed camshaft signal-generating wheels, which permit a rapid synchronization using counting of the segment lengths based on the crankshaft signal.
The method according to the present invention has the advantage that an improved phase signal of the phase sensor is available after a renewed switching on of the phase sensor or after a renewed start of the internal combustion engine. This is achieved as follows:
a) After the first switching on of the phase sensor or the internal combustion engine, one proceeds as follows:
a.1) Ascertaining the start-up signal position of the phase signal during a calibrating procedure of the phase sensor, based on the crankshaft signal over several angle marks of the signal-forming wheel of the camshaft, during the calibrating procedure of the phase signal, a correction by adjustment values being made stepwise until a predefined setpoint signal position or a normal signal position has been achieved.
a.2) Ascertaining the normal signal position of the phase signal based on the crankshaft signal after the startup of the internal combustion engine, and based on the completed calibrating procedure in the phase signal generator.
a.3) Determining angle errors from the difference between the startup signal position and the normal signal position.
a.4) Storing the correcting values based on the angle errors in a nonvolatile memory, e.g., in the engine control unit.
b) During renewed switching on of the phase sensor or the internal combustion engine:
b.1) Correcting the phase signal recorded by the engine control unit during the calibration procedure of the phase signal generator by the correcting values particularly stored in the engine control unit, so that, after the renewed switching on, an improved phase signal is available.
Because of the nonvolatile storing of the correcting values, when there is a renewed start of the internal combustion engine, the correcting values are immediately available. The requirements for an accurate signal of the phase sensor are increasing, especially during the start of the internal combustion engine. An accurate angular position of the phase signal with respect to the crankshaft signal immediately after the start of the internal combustion engine leads to an improved and optimized control of the injection, ignition and angular camshaft control systems, which, in the last analysis, leads to a better exhaust gas behavior of the internal combustion engine in startup operation.
It has been shown that the deviation of the startup signal position of the phase signal based on the crankshaft signal from the normal signal position is based particularly on the following parameters: the air gap between the signal-forming wheel at the camshaft and the phase sensor, the temperature and rotational speed of the camshaft/crankshaft. In this context, the air gap has a particularly great influence and it depends on installation circumstances which may be different from one internal combustion engine to the next. Because of the method according to the present invention, the influence of the air gap may be corrected during a renewed switching on of the phase sensor or the internal combustion engine.
The method according to the present invention may be carried out when the crankshaft and the camshaft are running in synchronized fashion. Ideally, the correcting of the phase signal takes place according to above-noted step b.1) in such a way that, during the calibrating procedure, the corrected phase signal based on the crankshaft signal yields a corrected startup signal position which is essentially equivalent to the normal signal position.
In this context, the calibrating procedure or the adjustment during the calibrating procedure is not an active action starting from the engine control unit. The engine control unit is not able to influence this “adjustment.” The change in the signal position of the phase signal is exclusively a function of the calibrating procedure running in the phase sensor.
According to the present invention, it may be provided that the setpoint signal position or the normal signal position is achieved, according to above-noted step a.1), if the phase signal is based on a switching threshold of the phase sensor which lies in the range of a certain percentage of the maximum signal recorded by the phase sensor. The phase sensor used has a switch-on switching threshold, in this context, which is close to a comparatively low input signal of the sensor. This is required in order also to make possible an immediate switching of sensors after the switching on, in which a comparatively large air gap is present between the sensor and the angle mark of the signal-forming wheel. Since the air gap may be different depending on installation, it is provided that the phase sensor calibrates itself. In this context, the switching threshold is shifted step by step in a range depending on the maximum input signal level swing. It has been shown that, at approximately 70% of the maximum analogous signal level swing recorded by the sensor, there is a favorable switching threshold. As a result, during the calibrating procedure, the preset switching threshold of the sensor is shifted step by step to a value of approximately. 70% of the maximum detected value. If the switching threshold achieves the predefined value, the setpoint signal position or the normal signal position is achieved. The calibrating procedure is then terminated. The duration of the calibrating procedure, in this context, depends on the size of the air gap.
The calibrating procedure takes place during the startup of the internal combustion engine. The startup of the internal combustion engine is terminated after eight working cycles, for example. Advantageously, the calibrating procedure is then terminated at the latest also after eight working cycles, but it may also be terminated earlier, depending on the size of the air gap. This achieves that the startup signal position is brought in small steps to the normal signal position, which avoids undesired signal deviations that are too great. This results in a stable and systematic behavior.
A method according to the present invention provides that the correcting values are formed from a maximum angle error at the first scanned angle mark and from additional angle errors at additional scanned angle marks corrected by the adjustment values. In this context, the correcting values may correspond to the respective angle errors. However, the correcting values may also be values dependent on the angle errors, for instance, values corrected for temperature or rotational speed. Instead of the angle errors, values that are characteristic of the angle errors may also be used, for instance, it is conceivable that one might use straight lines based on the angle errors or approximated to the angle errors.
One method according to the present invention provides that, during multiple renewed switching on of the phase sensor or the internal combustion engine according to above-noted step b.1), the corrected startup signal position is compared to the startup signal position to be expected based on the already stored correcting values, and, in response to repeating the switching on several times, an average value formation, in particular, a moving average formation of the correcting values to be stored according to step a.4) takes place. With each renewed switching on of the phase sensor or the internal combustion engine, the correcting values are accordingly stored, adjusted and learned. The correcting values to be used upon the renewed switching on of the phase sensor or of the internal combustion engine are accordingly optimized by the respective average formation.
In particular, the angle marks on the signal-producing wheel of the camshaft may be designed as edges of segments for generating high-phase and low-phase signals. In particular, four segments may be provided which in each case have one positive and one negative edge. This makes possible a singular assignment of the rotational setting of the signal-producing wheel of the camshaft within one working cycle. It is then possible to determine the angle errors based on the deviation of the startup edge position from the normal edge position. In this context, only the negative or positive edges can be taken into consideration. Knowing the absolute position of these edges, such as at a separation of 90° NW (camshaft), the actual phase position may be determined at each edge.
As has already been discussed, it may be advantageous to carry out the adjustment during the calibration procedure in several small steps. In this context, the adjustment between two edges may be restricted to a maximum value, this maximum value being in the range of ±2° and ±0.1°, e.g., in the range of ±0.2° to ≅0.75°, and especially in the range of ±0.25°. In particular, the range of ≅0.25° has proven to be advantageous. If a difference of the startup edge position from the normal edge position of, for instance, 2.5° at the camshaft is to be corrected, this may take place over ten to fourteen negative or positive edge changes during a maximum adjustment of 0.25° between two edge changes. Typically, four negative edge changes are provided per working cycle; one adjustment is then made over three to four working cycles.
Storing the correcting values in a nonvolatile memory may take place in the engine control unit. The nonvolatile memory may, for example, be a permanent RAM memory, e.g., an EEPROM or a flash memory.
One example embodiment of the present invention provides that the correcting values are portrayed by a straight line that approximates the angle errors. This saves storage space, since it is not necessary to file a respective correcting value for each edge change in the nonvolatile memory. The straight line may, for instance, be specified by a linear regression or by two selected value pairs. This being the case, it is sufficient to keep only the two specified values in the nonvolatile memory. For the plausibility check of the respective values, additional mechanisms may also be used which, for instance, check admissible ranges of the values.
Advantageously, the adjustment and correction take place under specified conditions of the camshaft. In an angular camshaft control, this adjustment is taken into consideration.
Furthermore, the adjustment is made only if there are no detectable system interferences.
Another example embodiment of the present invention provides that a comparison is made of the ascertained angle errors or correcting values to the behavior that is typical for the phase sensor for the various air gaps. The air gap to be encountered at the respective engine specimen may then be ascertained by making a correlation of the two values. Thereby further air gap dependencies may be compensated for. Furthermore, from this, corresponding diagnosis functions and/or correcting functions are set up or supported. Because of this, based on the angle errors or correcting values, for example, it may be concluded that there is too big an air gap and corresponding suggestions may be given, for instance, at the end of the production line or in the service garage concerning an installation that was not performed according to the rules.
The present invention also provides a system for carrying out the method according to the present invention, an engine control unit for carrying out the method according to the present invention, as well as a computer program for such an engine control unit.
In
A second signal-generating wheel 14 is connected to camshaft 15 of the internal combustion engine and has at its circumference segments of different lengths, the shorter segments being designated as 17 and the longer segments are designated as 16. Between the angle marks or segments interstices are provided, the longer ones bearing reference numeral 18 and the shorter ones bearing reference numeral 19. Each segment 16, 17 is bordered by a positive edge 20 and a negative edge 21.
Signal-forming wheel 14 shown in
Signal-generating wheel 10 of crankshaft 11 is recorded by a crankshaft sensor 22, and that of signal-generating wheel 14 of camshaft 15 by a phase sensor 23. Sensor 22 may be, for example, an inductive sensor or Hall sensor, which generate signals as the angle marks run by them. Sensor 23 is an active sensor, such as a Hall sensor, which has the calibration behavior described above. The signals generated are supplied to engine control unit 24, and processed further there.
Via inputs 25, 26 and 27, engine control 24 receives additional input variables required for the control of the internal combustion engine, which are supplied by suitable sensors. At the output end, engine control 24 makes available signals for the ignition, injection and camshaft control for components of the internal combustion engine not described in greater detail; the outputs of engine control 24 are marked 28 and 29.
Going into detail, line a) of
Line b) of
Line c) of
In line d) of
Line e) of
When the internal combustion engine is started for the first time, at first an inaccurate signal SNW is emitted at the camshaft, particularly based on a varying air gap between phase sensor 23 and segments 16, 17 that is conditioned upon installation. During startup of the internal combustion engine, the startup signal position of the phase signal to the crankshaft signal is adjusted to a normal signal position, via a calibrating procedure of at most sixty-four edges of phase-generating wheel 14, that is, altogether over at most eight working cycles in the case of a 4-cylinder engine. The adjustment is made by changing the switching threshold of the phase sensor during the recording of the edge change.
Such a change in the switching threshold is shown, for example, in
In order to obtain an optimal and representative switching point in time, preset switching threshold SSW is shifted, in a step by step manner, by the phase sensor to a value of ca. 70% of the maximum detected signal. According to
The adjustment of the preset value SSW to the respective values SSW1, 2, . . . , that are particularly air-gap dependent, takes place as a function of the calibrating behavior of the phase sensor in small steps about angular values (adjustment values) χ, until the provided switching threshold has been reached. Then the normal signal position of the camshaft signal with respect to the crankshaft signal is present. The specification of the adjustment step width, in this connection, is defined by the admissible switching level shift. From this, then, there results an adjustment step width based on the angle, as a function of the respective LS.
The adjustment is made under certain boundary conditions, for example, camshaft adjustment in retarded position. Before the adjustment, a temperature correction may be made based on characteristic curves stored in the control unit.
Line d) of
Line f) of
In
As was mentioned before, the difference of the startup signal position from the normal signal position, and thereby the angle error Δα that is to be adjusted, depends on the size of the air gap between the phase signal-generating wheel and the phase sensor of the camshaft. In
If the overall angle error to be adjusted, Δα1, at the camshaft amounts to, for instance, 2.5° (=5° at the crankshaft) at nFW=1, there comes about an adjustment of the angle error over altogether approximately 13 edge changes along line 41.
The adjustment curve along line 41 according to
According to the present invention, it is provided that correcting values based on the angle errors, that is, especially the values of angle errors Δα1 at nFW=1, or corrected angle errors Δα2 at nFW=2; Δα3 at nFW=3; up to Δαn at nFW=n are stored as correcting values KOW in a nonvolatile memory, which may also be seen in
According to
After the close of the calibrating phase and arrival at the normal signal position, angle errors Δα1 to Δα13 may then be determined by the comparison of the startup signal position with the normal signal position at the respective edge changes nFW. Corresponding values may be seen in
Upon a renewed switching on of the phase sensor and/or of the internal combustion engine, the phase signals are then adjusted not only by the adjustment values χ, but in addition by correcting values KOW, that are stored in the memory, in such a way that, after the renewed switching on of the phase sensor and/or the internal combustion engine, an improved phase signal is available, and especially after the renewed switching on, the normal signal position is at least largely achieved.
In the example shown in
The thus adjusted and corrected startup signal position of the phase signal to the crankshaft signal is compared to the normal signal position during the repeatedly renewed starting. A new correction may be carried out in response to deviations of the corrected startup signal position from the normal signal position to be expected. The new correcting values resulting from this may be drawn upon in the case of a once again renewed starting of the internal combustion engine, for the correction of the correcting values ascertained during the previous starting. Because of this, there comes about in each case an improved, corrected startup phase signal in response to several renewed starting procedures. The correction of the phase signal is accordingly improved and learned by multiple repetition of the adjustment and correction during renewed switching on; in particular, a moving average formation is carried out.
All in all, because of the nonvolatile storage of the correcting values, the systematic angle errors at renewed starting may be excluded.
In order to save space in the nonvolatile memory, according to a second example embodiment of the present invention, the correction may take place by using the correcting values characteristic of the angle errors. This may be done in particular in that the correcting values are portrayed by a straight line that approximates the angle errors. In response to the occurrence of an angle error of 2.5°, the straight line then corresponds to signal curve 41 in
For the plausibility check of the values, additional mechanisms may be used, for instance, top or bottom limits for the values may be used. Besides that, an averaging may be performed of several, e.g., three, straight lines from corresponding three adjustment procedures.
Number | Date | Country | Kind |
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PCT/EP2004/005747 | May 2004 | WO | international |
PCT/EP2004/006554 | Jun 2004 | WO | international |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2004/006686 | 6/21/2004 | WO | 00 | 11/16/2007 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2005/119041 | 12/15/2005 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
5417187 | Schneider et al. | May 1995 | A |
5692488 | Schmitz et al. | Dec 1997 | A |
20030000498 | Mathews et al. | Jan 2003 | A1 |
Number | Date | Country |
---|---|---|
41 41 713 | Jun 1993 | DE |
43 10 460 | Oct 1994 | DE |
0017933 | Oct 1980 | EP |
3099625 | Aug 2000 | JP |
2001-082194 | Mar 2001 | JP |
2001263152 | Sep 2001 | JP |
2003247856 | Sep 2003 | JP |
Number | Date | Country | |
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20080210021 A1 | Sep 2008 | US |