1. Field of the Invention
The present invention relates to a method for bounce suppression of a valve member operated by a piezo actuator during the closing phase in an internal combustion engine and a corresponding device for carrying out the method.
2. Description of Related Art
In internal combustion engines, especially in Otto and Diesel engines, valves control the intake and the discharge of the combustion gases, the valve opening and closing times having a considerable influence on the power output, on the fuel consumption, on low-pollutant combustion and on the running properties of the internal combustion engine at a specified rotational speed. These valves are usually developed as flat-seat valves, in the closed state of the valve, a valve member being accommodated with its valve disk in a valve seat in a precisely fitting and sealing manner. To open the valve, the valve disk is lifted off from the valve seat, and in this context, an annular gap opens, through which the combustion gas is able to flow. The flat-seat valve is driven via the valve spindle, which is a part of the valve member. In modern engines, in order to open and close the valves, piezo actuators are used, which open and close again a valve at high speed. In particular during rapid closing of the flat-seat valve, the valve disk bumps into the valve seat, the sealing surfaces of the two elements striking each other. At higher closing speeds, the impact of the valve disk onto the valve seat leads to an elastic bump, as a result of which the flat-seat valve does not close abruptly, but rather opens slightly and closes again several times after the first closing. This impacting impairs the precision of the closing process, and thereby influences the abovementioned properties of the internal combustion engine in an undesired way. Furthermore, the impacting of the valve disk on the valve seat leads to rapid material wear. In particular, the exhaust valve of an internal combustion engine is especially exposed to corrosive conditions, because the sealing surfaces on the valve disk and the valve seat are exposed to high temperatures and the corrosive effects of the hot and combusted combustion gases.
The present invention provides a method for bounce suppression of a valve member operated by a piezo actuator during the closing phase in an internal combustion engine and a corresponding device for carrying out the method.
According to the present invention, the piezo actuator is electronically controlled in such a way that, during the closing process, first of all it absorbs the kinetic energy of the valve member shortly before impact, is thereby deformed itself, generates a charge internally, and with that, it increases its restoring force. Even before the piezo actuator goes over into the elastic rebound phase, the charge built up internally in the piezo actuator is dissipated, so that the valve member is finally damped by an inelastic bump upon impact and guided into the valve seat having lower kinetic energy, where the valve disk then remains, without the undesired bouncing motion.
The method according to the present invention, during the closing phase, includes the steps: partial discharging of the piezo actuator, whereby the valve member is braked even before reaching the valve seat, interruption of the discharge of the piezo actuator, whereby the piezo actuator is upset by the valve member and builds up an electric charge, renewed discharging of the piezo actuator, a residual charge remaining in the piezo actuator is at least partially dissipated after partial discharge and the charge built up during the charge interruption. The method, according to the present invention, for bounce suppression of a valve member operated by a piezo actuator, during the closing phase in an internal combustion engine, also includes an interruption of the discharge process of the piezo actuator during closing of the valve, the selection of the points in time of the start of the interruption and the end of the interruption being significant for optimum bounce suppression.
In the embodiment of the present invention, it is alternatively also possible to repeat the process within a valve-closing cycle once or several times, whereby the valve member is returned into the valve seat in a stuttering manner. Each discharge process is interrupted in a controlled manner, in this context. During the respective interruption times, the valve member has a closing speed determined by the interruption time period, and this speed, as well as the mass of the valve member, determine the kinetic energy of the valve member. Beginning at the time of the interruption, the valve member, which is connected in a directly or indirectly force-locking manner to the piezo actuator, is braked via the elastic effect of the piezo actuator. During the braking, the piezo actuator is deformed by the impulse of the valve member, and in the process, the piezo crystal in the piezo actuator builds up a charging voltage which increases the restoring force of the piezo crystal. Even before the piezo crystal gets into the back swing, and therefore acts itself as an impact surface instead of the valve seat, the charge built up in the piezo actuator is discharged. Because of the discharge, the piezo actuator, that is mechanically stressed by the kinetic energy of the valve member, loses its restoring force, whereby the elastic back swing does not take place. This being the case, during the interruption of the discharge, the piezo actuator acts like an impact cushion, in which the kinetic energy is converted into deformation energy and is dissipated.
In the following, the present invention is explained in detail with reference to the attached drawings. The figures show:
FIGS. 3.1-3.6 show a diagram for clarifying the automatic setting of the discharge interruption times.
Beginning with curve 1 in
During the next valve cycle, the discharge process begins again at time 1, but is interrupted earlier than at time o, namely, at time n. The charge buildup then taking place in curve 2, after time n, is correspondingly greater than after time o in curve 1, because the piezo actuator still has sufficient capacitance for charge buildup and for mechanical upsetting. Thereafter, the same circumstances set in while a plateau in time forms in charging voltage Up, as in curve 1 of charging voltage Up.
In a still later valve cycle, the discharge diagram is shown in
In order to suppress the development of the level remaining the same in time, the second discharge pulse is advanced, at this point, to such an extent that directly after the maximum buildup of the charging voltage at time o, curve 4 in
During the optimizing phase, the curves of valve lifts hv do not differ greatly from one another. The stress absorbed by the piezo actuator, however, does differ. In response to the optimized discharge, the piezo actuator is stressed in the elastic range and is destressed again.
As is shown in
For the setting of the discharge current times, control device 20 detects a rise in the charging voltage of piezo actuator P after the interruption of the first discharge current, and measures the height of the charging voltage rise. Only when the height of the charging voltage rise reaches or exceeds a predetermined value does control electronics 20 control the point in time of the renewed discharge pulse, control device 20 in this case detecting a plateau development over time, and advancing in time the second discharge pulse in successive valve cycles until the plateau development of the charging voltage fails to appear. In order to set the two points in time, control device 20 controls the points in time according to the following strategy: First, the setting of the time of the first interruption takes place after a partial discharge by control device 20, so that the interruption takes place so late that the upsetting of piezo actuator P, taking place after the interruption, is so slight that the accompanying charge buildup falls below a specified value. This ensures that control device 20 does not close the valve member at too early a closing time. Then the setting of the time of the renewed discharge by control device 20 begins so that the renewed discharge takes place so late that the charge of piezo actuator P, built up by upsetting, does not change over a specified time interval. A plateau over time is detected by this, which is minimized in the subsequent control cycle. From this non-optimal state, the control device controls the point in time again by the subsequent adjustment of the point in time of the interruption after a partial discharge, until it has been advanced in time so far that the charge buildup reaches or exceeds a specified value. Only after that does the adjusting of the point in time of the renewed discharge take place, until it has been advanced so far that the charge of the piezo actuator, built up by the upsetting, changes within a specified time interval by a specified amount, so that no plateau formation over time is detected.
Control device 20 used for the control, in an advantageous manner has a device which detects the impact of the valve member, preferably via the monitoring of the charging voltage after the discharge of piezo actuator P. When an impact is detected, control device 20 is activated for setting the discharge time, and if no further impact is detected, control device 20 is deactivated.
For the implementation of control device 20, a microcontroller 23 may be used or a control electronics system, the input of the control devices being the charging voltage and the output being a signal for triggering the discharge process.
Number | Date | Country | Kind |
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10 2008 000 731 | Mar 2008 | DE | national |
10 2008 040 412 | Jul 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/EP2009/050849 | 1/26/2009 | WO | 00 | 11/12/2010 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2009/115360 | 9/24/2009 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4593658 | Moloney | Jun 1986 | A |
6155500 | Takase | Dec 2000 | A |
Number | Date | Country |
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199 21 456 | Nov 2000 | DE |
10 2004 015 002 | Oct 2005 | DE |
0 995 899 | Apr 2000 | EP |
1 199 446 | Apr 2002 | EP |
2002-544424 | Dec 2002 | JP |
2005-351139 | Dec 2005 | JP |
WO 0153662 | Jul 2001 | WO |
WO 2006069750 | Jul 2006 | WO |
Number | Date | Country | |
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20110042594 A1 | Feb 2011 | US |