This application claims priority from German patent application serial no. 10 2013 205 564.1 filed Mar. 28, 2013.
The present invention concerns a method for engaging a form-locking shift element to realize a gear in an automatic transmission, whereat at least one further, friction shift element is to be engaged to realize the gear to be activated.
During gear engagement processes in automatic transmissions in which a form-locking shift element to be engaged has to be synchronized and at least one other, frictional shift element is involved, according to the prior art an additional shift element, which is not involved in the gear to be engaged but which serves as a synchronizing shift element is actuated so as to synchronize the form-locking shift element to be engaged. Disadvantageously, when the form locking shift element is engaged, then although the synchronizing shift element has already been disengaged torque is present at the form locking shift element which can prevent the claws of the form locking shift element to be engaged from being pushed fully home to their end position.
The objective of the present invention is to provide a method for engaging a form-locking shift element to obtain a gear in an automatic transmission, wherein at least one further, frictional shift element is involved in obtaining the gear to be engaged and a shift element not involved in the gear to be engaged but which serves as a synchronizing shift element is actuated in order to synchronize the form locking shift element to be engaged, by carrying out which method the torque present at the form locking shift element to be engaged once the synchronizing shift element has been disengaged, is reduced.
Accordingly, a method is proposed for engaging a form-locking shift element to obtain a gear in an automatic transmission, wherein at least one further, frictional shift element is involved in obtaining the gear to be engaged and a shift element not involved in the gear to be engaged but which serves as a synchronizing shift element is actuated in order to synchronize the form locking shift element to be engaged, in this method a further, frictional shift element involved in the gear engagement is closed and then opened to a defined extent such that it operates with slip in order to ensure the engagement of the form locking shift element.
During this a further, frictional shift element not directly needed for synchronization but involved in the gear engagement is brought to its current transmission limit plus a pressure offset, so that the rotational speed difference at the shift element is zero. Depending on the engagement time-point of the claws of the form locking shift element to be engaged, the pressure at the further frictional shift element is reduced in such manner that slip can take place at the shift element. In this way the torque at the claws of the form locking shift element to be engaged is reduced, whereby the claws can be pushed fully home to their end position.
When the fully interlocked condition is recognized by an appropriate sensor system, the further frictional shift element is closed completely. If no sensor system for recognizing full interlock has been provided, then the further frictional shift element is closed completely after a specified time interval following the moment when the pressure reduction begins.
Below, an example of the invention will be explained in more detail with reference to the sole FIGURE which shows, in each case as functions of time, the pressure variation at the form locking shift element to be engaged, at the further, frictional shift element, at the synchronizing shift element and at a third shift element involved, as well as the variation of the rotational speed difference at the form locking shift element to be engaged and the torque variation at the form locking shift element to be engaged, according to the prior art and in the method according to the invention, again as functions of time.
In the attached FIGURE, A represents the time variation of the pressure at a third shift element which is involved in obtaining the gear; this shift element is already closed. Curve B shows the time variation of the pressure at the further, frictional shift element involved in obtaining the gear, whereas curve C shows the time variation of the pressure at the synchronizing shift element and curve D shows the time variation of the pressure at the form locking shift element to be engaged. Curves F and G show the time variations of the torque at the form locking shift element to be engaged, respectively in the prior art and in the method according to the invention.
At time t_0 the process for engagement of the form locking shift element is initiated (curve GE_aktiv), and in order to synchronize the form locking shift element a synchronizing shift element, which is not needed for the gear to be engaged, is filled and closed, which happens at time t_1 (curve C). At the same time t_1 the pressure is increased at a further frictional shift element, one which is not directly needed for synchronization but is involved in engaging the gear (curve B), until it is brought to its current transmission limit plus a pressure offset, whereby the rotational speed difference at that shift element becomes zero. This pressure is maintained until time t_2.
Between times t_1 and t_2 the pressure at the synchronizing shift element increases and the rotational speed difference between the claws of the form locking shift element to be engaged is reduced.
At time t_2, the pressure in the further frictional shift element is reduced in such manner that slip can take place in that shift element, and then, at time t_3, the pressure at the form locking shift element to be engaged is increased in order to engage the form locking shift element. The time t_2 can be determined either from the synchronization duration of the form locking shift element or with reference to the signal from a position sensor which detects the position of the claws of the form locking shift element.
The rotational speed difference between the claws of the form locking shift element is reduced farther, and reaches zero at a time t_4 when the pressure at the further frictional shift element reaches a minimum, namely zero. In this way the torque at the claws of the form locking shift element to be engaged (curve G) is reduced by comparison with the prior art (curve F), so enabling the claws to be pushed fully home to their end position. During this the synchronizing shift element is disengaged.
The further frictional shift element is fully closed when the end position of the claws of the form locking shift element is recognized by an appropriate sensor system; in the example shown in the attached FIGURE this takes place at time t_5. In the case when no sensor system has been provided for recognizing the end position, the further frictional shift element is closed completely after a specified time interval following the beginning of pressure reduction in the further frictional shift element, and the torque at the claws of the form locking shift element then increases.
Number | Date | Country | Kind |
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10 2013 205 564 | Mar 2013 | DE | national |
Number | Name | Date | Kind |
---|---|---|---|
8394000 | Popp et al. | Mar 2013 | B2 |
8465394 | Cuppers et al. | Jun 2013 | B2 |
8500601 | Arnold | Aug 2013 | B2 |
20110263382 | Arnold | Oct 2011 | A1 |
20130196814 | Gumpoltsberger et al. | Aug 2013 | A1 |
20130268169 | Arnold | Oct 2013 | A1 |
20140182415 | Griesmeier | Jul 2014 | A1 |
Number | Date | Country |
---|---|---|
10 2008 001 566 | Nov 2009 | DE |
10 2009 028 305 | Feb 2011 | DE |
10 2009 056 793 | Jun 2011 | DE |
10 2010 000 858 | Jul 2011 | DE |
10 2010 042 656 | Apr 2012 | DE |
Entry |
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German Search Report Corresponding to 10 2013 205 564.1 mailed Nov. 21, 2013. |
Number | Date | Country | |
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20140290404 A1 | Oct 2014 | US |