The invention relates to a method for determining a wear value for a transmission element, in particular, a timing chain or a toothed belt, arranged between a crankshaft and a camshaft of a reciprocating piston internal combustion engine, wherein the camshaft is driven by the transmission element via a drive part, such as, e.g., a camshaft gearwheel. In addition, the invention relates to a reciprocating piston internal combustion engine with a crankshaft, at least one camshaft, and at least one transmission element connecting these to each other, in particular, a timing chain or a toothed belt, wherein the transmission element is in driving connection with the camshaft via a drive part, such as, e.g., a camshaft gearwheel.
Such a reciprocating piston internal combustion engine with a crankshaft and two camshafts controlling intake and exhaust valves is known in practice. On the crankshaft there is a crankshaft gearwheel, which is locked in rotation with the crankshaft and which drives a timing chain. A camshaft gearwheel, which is locked in rotation with the relevant camshaft, is allocated to each camshaft and features twice the diameter of the crankshaft gearwheel. The timing chain engages with external teeth of the camshaft gearwheels and in this way transmits the rotational movement of the crankshaft to the camshafts with a rotational speed ratio of 2:1. At high rotational speeds, relatively large tensile forces occur, because the timing chain drives not only the camshaft allocated to it, but instead also the valves and valve springs activated by the camshaft. Increased running output of the internal combustion engine leads to wear, especially at the individual bearing points of the chain elements of the timing chain. Therefore, the length of the timing chain increases and the phase position of the camshaft relative to the crankshaft is changed, which has an unfavorable effect on the operating behavior of the internal combustion engine and results in an increase in fuel consumption and/or a decrease in the engine output. The state of the timing chain is therefore checked regularly, in order to replace the timing chain, if necessary, when a predetermined wear limit is reached. The checking of the timing chain, however, is relatively complicated, because parts of a control box of the reciprocating piston internal combustion engine and possibly other components, such as, e.g., an air filter, a generator, an engine cover, or the like, must be removed, in order to obtain access to the timing chain. The wear of the timing chain is determined by measuring the distance between the tensioned section and the loose section and/or by determining the position of a tensioning element of an adjustable chain tensioner when the internal combustion engine is stopped. For a precise check of the wear on the timing chain, it is even necessary to disassemble the timing chain. It is also disadvantageous that the intervals, within which the timing chain must be checked, must be designed for the most unfavorable operating conditions of the internal combustion engine, so that even under the most unfavorable operating conditions, the reaching of the wear limit of the timing chain can be recognized in due time and the timing chain can be replaced.
Therefore, there is the objective of creating a method and a reciprocating piston internal combustion engine of the type noted above, which allows a simple way to determine a wear value for the transmission element.
This objective is met with respect to the method of the type noted above in that, at spaced apart time points, at which the crankshaft drives the camshaft, at least one measurement value for the phase position of the drive part relative to the crankshaft is detected and that the wear value is determined from the difference between these measurement values.
Advantageously, it is therefore possible to check the wear of the transmission element during the operation of the reciprocating piston internal combustion engine, so that a time-intensive and expensive disassembly of a control box and/or other components of the internal combustion engine can be eliminated. Thus, the transmission element needs to be maintained only when the wear limit is actually reached. Thus, the maintenance costs decrease and the availability of the internal combustion engine increases.
In an advantageous embodiment of the invention, the camshaft is connected via an adjustment device so that it can rotate with the drive part, wherein the adjustment device is adjusted so that it is arranged in a predetermined adjustment position when detecting the measurement values for the phase position, wherein, for the rotational position of the crankshaft, a crankshaft sensor signal is detected, wherein the camshaft is driven via the transmission element by the crankshaft and rotated relative to the drive part, such that the camshaft runs through a camshaft reference position at two or more spaced apart time points, wherein the passage of the camshaft reference position is detected, in order to allocate a camshaft angle value to the camshaft reference position with reference to the crankshaft sensor signal, and wherein, with these crankshaft angle values as measurement values for the phase position, the wear value is determined. With the help of the adjustment device, the opening and closing times of the valves can be adapted in a known way to the relevant operating state of the internal combustion engine, for example, to the crankshaft rotational speed and/or the operating temperature. The crankshaft sensor signal needed for controlling the adjustment device and a measurement signal for the camshaft reference position can be used both for regulating the phase position to a desired value and also for determining the wear value of the transmission element.
In another advantageous construction of the invention, the camshaft is connected to the drive part so that it can rotate by the adjustment device, wherein the adjustment device is adjusted such that it is arranged in a predetermined adjustment position when the measurement values for the phase position are detected in a predetermined adjustment position, wherein, for the rotational position of the camshaft, a camshaft sensor signal is detected, wherein the camshaft is driven by the crankshaft via the transmission element, such that this runs through a crankshaft reference position at two or more spaced apart time points, wherein the passage of the crankshaft reference position is detected, in order to allocate a camshaft angle value to the crankshaft reference position with reference to the camshaft sensor signal, and wherein, with these camshaft angle values as measurement values for the phase position, the wear value is determined. With this construction of the invention, the wear value can also be determined in a simple way.
It is advantageous when the wear value is compared with a limit value and when an error state is detected when the limit value is exceeded. Reaching the limit value can then be reported to the user of the internal combustion engine, for example, by a corresponding display.
In a preferred embodiment of the invention, the rotational angle position of the camshaft is adjusted as a function of the wear value relative to the transmission element, such that the influence of the wear of the transmission element is at least partially compensated to the phase angle between the camshaft and the crankshaft. Therefore, low wear of the transmission element can be compensated, so that the valve timing practically does not change due to the wear and the internal combustion engine maintains its full power capacity over its entire service life.
It is advantageous when several wear values are determined and buffered for different operating states of the reciprocating piston internal combustion engine, especially for different operating temperatures and/or crankshaft rotational speeds, and when the rotational angle position of the camshaft is adjusted relative to the transmission element preferably as a function of the wear value allocated to each operating state of the reciprocating piston internal combustion engine. Therefore, the wear of the transmission element can be compensated even more precisely.
In a preferred construction of the invention, the adjustment device features an adjustment gear mechanism, which is constructed as a triple-shaft gear mechanism with a transmission element-fixed drive shaft, a camshaft-fixed driven shaft, and an adjustment shaft driven by an electric motor,
The measurement values for the phase position are thus determined indirectly from the measurement values of the second rotational angle measurement signal, the positional measurement signal, and a gear parameter, such as, e.g., the stationary gear transmission ratio of the triple-shaft gear mechanism. Therefore, the phase position and thus the wear value can be easily determined with great precision.
With respect to the reciprocating piston internal combustion engine, the previously mentioned objective is met in that the reciprocating piston internal combustion engine has a measurement device for the phase position of the drive part relative to the crankshaft, that the measurement device is connected to a data memory featuring at least one memory location, in which a measurement value for the phase position is stored, and that the measurement device is connected to an evaluation device, which is constructed for determining a wear value for the transmission element made from at least two phase position measurement values detected at different time points.
It is advantageous when the drive part is rotated by an adjustment device for changing the phase position of the camshaft relative to the crankshaft and can be locked in rotation with the camshaft in different rotational positions. In this way, the opening and/or closing times of the valves can be adapted to the corresponding operating state of the internal combustion engine. A crankshaft sensor needed for controlling the adjustment device and a sensor for detecting the camshaft reference position can be used both for regulating the phase position to a desired value and also for determining the wear value of the transmission element.
For a preferred construction of the invention, the adjustment device is constructed as a triple-shaft gear mechanism with a transmission element-fixed drive shaft, a camshaft-fixed driven shaft, and an adjustment shaft driven by an electric motor. The phase position between the camshaft and crankshaft can then be set electrically with great precision.
It is advantageous when the adjustment device has limit stops for limiting the adjustment angle between the drive shaft and the driven shaft. For measuring the phase position of the drive part relative to the crankshaft, the adjustment device can then be positioned against the limit stops, in order to tension the drive part in a defined rotational angle position with the camshaft.
Below, an embodiment of the invention is explained in more detail with reference to the drawing. Shown are:
A reciprocating piston internal combustion engine 1 shown schematically in
Between the drive part 6 and the camshaft 3 there is an adjustment device 8, which is shown in more detail in
The adjustment gear mechanism is integrated in a hub of the drive part 6. For limiting the rotational angle between the camshaft 3 and the crankshaft 2, the adjustment device 8 has a stop element 10 connected rigidly to the drive shaft and a counter stop element 11, which is locked in rotation with the camshaft 3 and contacts the stop element 10 in the position of use in a stop position.
In
As the electric motor 9, an EC motor is provided, which has a rotor, on whose periphery there is a series of magnetic segments, which are magnetized alternately in opposite directions and which interact magnetically via an air gap with teeth of a stator. The teeth are wound with a winding that is energized by a control device 16 integrated in a motor controller 15.
The position of the magnetic segments relative to the stator and thus the adjustment shaft rotational angle is detected with the help of a measurement device, which has, on the stator, several magnetic field sensors 17 that are offset to each other in the peripheral direction of the stator, such that for each rotation of the rotor, a number of magnetic segment-sensor combinations are run through. The magnetic field sensors 17 generate a digital sensor signal, which runs through a series of sensor signal states, which repeat as often as the measurement device has magnetic field sensors 17 for a mechanical full rotation of the rotor. This sensor signal is designated below also as an adjustment shaft sensor signal.
When the internal combustion engine is started—independent of the position, in which the rotor or the adjustment shaft is currently located—a positional measurement signal is set to a positional measurement signal starting value. Then the adjustment shaft is rotated, wherein for each state change of the adjustment shaft sensor signal in the operating program of the adjustment angle control device 14, an interrupt is triggered, in which the positional measurement signal is tracked.
As a reference signal generator for the camshaft rotational angle, a Hall sensor 18 is provided, which interacts with a trigger wheel 19 arranged on the camshaft 3. When a predetermined rotational angle position of the camshaft 3 is reached, a flank is generated in a camshaft reference signal. When the Hall sensor 18 detects the flank, in the operating program of the adjustment angle control device 14 an interrupt is triggered, in which the crankshaft rotational angle and the adjustment shaft rotational angle are buffered for regulating the phase angle for further processing. This interrupt is also designated below as a camshaft interrupt. Finally, in the operating program of the adjustment angle control device 14, a time slice-controlled interrupt is also triggered, which is designated below as a cyclical interrupt.
With the help of the crankshaft rotational angle measurement signal, the positional measurement signal, and a gear parameter, namely the transmission ratio, which the adjustment gear mechanism exhibits for a stationary drive shaft between the adjustment shaft and the camshaft 3, the current phase angle is calculated:
Here,
The phase angle signal is thus tracked, starting from a reference rotational angle value, for a state change of the crankshaft sensor signal and/or the adjustment shaft sensor signal. The phase angle signal determined in this way is regulated to a desired phase angle signal, which is prepared by the motor controller 15.
For determining a wear value, which represents a measure for the elongation of the transmission element 4 caused by wear during the operation of the internal combustion engine 1, while the crankshaft 2 drives the camshaft 3 via the transmission element 4, initially for different operating states of the internal combustion engine, such as, e.g., different crankshaft rotational speeds and/or different operating temperatures, a first measurement value is detected for the phase position of the drive part 6 relative to the crankshaft 2. For this purpose, initially the drive part 6 is brought into a predetermined adjustment position relative to the camshaft 3, for example, in the already mentioned stop position or an emergency running position, which is controlled with the help of the electric motor 9. When this adjustment position is reached, which can be checked, for example, for the stop position by detecting a change of the phase speed and/or current consumption of the electric motor 9, each time—as described above—the absolute phase angle between the camshaft 3 and the crankshaft 2 is measured. The measurement values for the phase angle can be determined, for example, on an engine test bed. These values are stored in a non-volatile data memory.
During the measurement of the phase angle, the crankshaft rotational speed is held essentially constant, in order to avoid sensor drift, as can occur, for example, for rotational speed ramps. In addition, as much as possible the torque of the crankshaft 2 is not changed during the measurement value detection, so that no phase shifts occur in the change between a push and a pull phase. Noise caused by oscillations of the control drive in the phase angle measurement signal can be removed by filtering the measurement signal.
At a later time point, at which the operating state of the internal combustion engine 1 corresponds approximately to the operating state at the time point of the measurement of a first phase position measurement value stored in the data memory, at least one second measurement value for the phase position is determined in a corresponding way. Then, in the adjustment angle control device 14, the difference from the first measurement value stored in the data memory and the second measurement value is formed, in order to determine the wear value for the transmission element 4.
The wear value is then compared with a limit value or a permitted range. If the wear value exceeds the limit value or lies outside of the permitted range, an error state is detected and a corresponding error message is entered into the data memory. If necessary, the error state can be displayed with the help of a display device, for example, on the dashboard of a motor vehicle.
In
ε(t)=φCnk(t)−2·φCam(t)−ΔφLangung
Here,
It should also be mentioned that for a repeated or constant measurement of the wear value, even a failure of the tensioning device could be determined, when a jump-like change of the wear value, which starts above a certain value, is detected. Here, it is even possible to realize an emergency running strategy, for which the selected phase angle is set and held. The failure of the tensioning device can be further transmitted from the adjustment angle control device 14 to the motor controller 15, for example, by means of a CAN-BUS 20.
Number | Date | Country | Kind |
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10 2005 037 517 | Aug 2005 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE2006/001183 | 7/8/2006 | WO | 00 | 1/29/2009 |
Publishing Document | Publishing Date | Country | Kind |
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WO2007/016889 | 2/15/2007 | WO | A |
Number | Name | Date | Kind |
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5689067 | Klein et al. | Nov 1997 | A |
5733214 | Shiki et al. | Mar 1998 | A |
7032552 | Schafer et al. | Apr 2006 | B2 |
Number | Date | Country |
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1498581 | Jan 2005 | EP |
2850755 | Aug 2004 | FR |
0000756 | Jan 2000 | WO |
Number | Date | Country | |
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20090139478 A1 | Jun 2009 | US |