• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a method for performing switching operations in a vehicle drive train (20) having a vehicle transmission (10), wherein an input shaft (11) of the vehicle drive train (17) is connected by at least two switching elements via different gears with an output shaft (12) in which, at least during an indirect shift from a source gear to a target gear in a first torque phase, a torque transfer from at least one extending shift element to at least one retracting first shift element, in a subsequent to the first torque phase (TP1) speed phase (SP), a synchronization between the engine speed (nM) and the rotational speed (n1) of the target gear, and in a subsequent to the rotational speed phase (SP) second torque phase (TP2) a torque transfer from a continuous switching element is performed on a retracting second switching element. In order to achieve short switching times in indirect switching operations, it is provided that the synchronization between the speed (n1) of the target gear and the engine speed (nM) begins in or at the end of the first torque phase (TP1).
    公开号:AT517581A4
    申请号:T50710/2015
    申请日:2015-08-07
    公开日:2017-03-15
    发明作者:Yolga Muammer
    申请人:Avl List Gmbh;
    IPC主号:
    专利说明:

    The invention relates to a method for performing switching operations in a vehicle drive train, which comprises a vehicle transmission, wherein an input shaft of the vehicle drive train is connected by at least two switching elements via different gears to an output shaft, wherein at least during an indirect shift from a source gear to a target gear in a first Torque phase, a torque transfer from an extending switching element to a retracting first switching element, in a following the first torque phase rotational phase synchronization between the engine speed and the speed of the target gear, and in a following on the speed phase second torque phase torque transfer from a continuous switching element to a retracting second switching element is performed.
    As retracting shift elements open and closed in the target gear shift elements are here referred to in the source gear, which engage during at least one torque phase in a gear change (= close) and are closed in the target gear. As extending switching elements closed and opened in the target gear switching elements are referred to in the source gear, which disengage already during or immediately after the first torque phase (= open). As a continuous switching elements closed switching elements are referred to in the source gear, which disengage only in and after the second torque phase (= open).
    Automatic transmissions known in the art, such as automatic transmissions or dual clutch transmissions, are adapted to perform direct or indirect gear changes according to the specific transmission design. Direct switching operations are switching operations between, for example, successive gears, which have a common switching element A, B, C, D, E - for example, a clutch or a braking device - have. For example, in the following exemplary switch matrix, switching operations between gears 1 and 2, 2 and 3, 1 and 3, 3 and 4 are direct shifts:
    The prior art manual transmission illustrated in FIG. 1 has, for example, this above switching matrix.
    Indirect switching operations, however, switching operations between gears, which have no common switching element A, B, C, D, E, ie switching operations between the courses 1 and 6, 1 and 5, 2 and 5, 3 and 6 in the exemplary switching matrix.
    In order to carry out indirect switching operations, an intermediate gear is selected and the shifting process is carried out via this intermediate gear. In a shift from 3rd to 6th gear, 4th gear can be selected as an intermediate gear since 4th gear with 3rd and 6th gears has common shift elements (referred to as "continuous shift elements" herein) the prior art indirect switching operations from 3rd gear to 6th gear on the 4th gear performed as an intermediate.
    Various solutions are known which try to reduce the switching time without degrading the shift quality. So it is known, the second retracting clutch (in the example, the switching element C for the switching process 3 -> -> 4 -> 6) to fill early during the switching operation. Nevertheless, the switching times for indirect switching operations using known methods are much greater than for direct switching operations.
    In modern transmissions, adjacent gears are formed both in increasing, as well as in descending order (ie, for example, the 2nd gear both with the 1st gear, and with the 3rd gear) as gears for direct gearshifts. Therefore, indirect gearshifts usually take place only with gear changes with larger changes in the gear ratios, for example, from 6th gear to 3rd gear. For example, the likelihood of requesting a high ratio gearshift is quite high when the driver performs a so-called kickdown from a sailing operation. Thus, many indirect shifts occur with sudden power requirements when downshifting with high power requirements or even with overdriving with power reduction.
    As can be seen from Fig. 2, occur in known from the prior art indirect switching operations, which begin with a speed synchronization phase (that is Schubüber- and Zugrückschaltungen) after the preparation phase for filling the first retracting switching element two rotational speed phases SP1, SP2 and two torque phases TP1, TP2, wherein during a first rotational phase SP1, the engine speed n with the gear ratio of the intermediate gear (for example, 5th gear) is synchronized. During the first torque phase TP1, the torque is transferred from the source gear (here 6th gear) to the intermediate gear (here 5th gear). Thereafter, in a second speed phase TP2, the engine speed is synchronized with the speed of the target gear (here 3rd gear). In the second torque phase TP2, the torque is transferred from the intermediate gear (here 5th gear) to the target gear (here 3rd gear), wherein all switching elements occupy the positions assigned to the target gear. The second torque phase TP2 is followed by a recovery phase RP. The entire gear change sequence thus has a preparation phase PP, two rotational speed phases SP1, SP2, two torque phases TP1, TP2 and a recovery phase RP. Methods for carrying out indirect gear changes of the type described are, for example, from the publications EP 478 945 A, EP 827 861 A, EP 1 578 636 A, US Pat. No. 5,961,421 A, US Pat. No. 6,009,768 A, DE 103 49 220 A and DE 198 53 824 A known. The known methods have the disadvantage that indirect gear changes require significantly higher switching times than direct gear changes.
    The invention is therefore based on the object to reduce the switching times for indirect gear changes, especially for indirect train downshifts to.
    According to the invention, this is done by starting the synchronization between the speed of the target gear and the engine speed in or at the end of the first torque phase.
    Thereby, the first speed phase can be saved, which - depending on the configuration of the elements circuit, transmission, engine, vehicle - typically takes about 300 ms to 800 ms. An indirect switching process can thus be carried out much faster when using the method according to the invention than in conventional methods.
    In a preferred embodiment of the invention it is provided that the synchronization between the engine speed and the speed of the target gear ends in or at the end of the second torque phase. Conveniently, during the first torque phase, the continuous switching element is controlled to open until the adhesion point.
    Preferably, the first torque phase begins immediately after a preparation phase for the gear change.
    In order to achieve a particularly short shift duration or a pleasant driving feel, it is advantageous if the synchronization of the change in engine speeds over the time between the speed of the source gear and the speed of the target gear is continuous
    The switching elements can be designed as clutches or as braking devices. Under clutches friction clutches, such as multi-plate clutches are understood here. The braking devices may be formed by multi-disc brakes.
    In the method according to the invention thus eliminates a speed phase. Each indirect gear change begins in the process according to the invention with the preparation phase to fill the incoming first clutch. In contrast to the described prior art, the preparation phase follows in the case of overshoot and pull downshifts equal to the first torque phase instead of the first speed phase. In the first speed phase, the switching elements of the intermediate gear are active. It is essential that in the first torque phase, the continuous switching element precisely controlled and zoomed close to the adhesive limit or. guided under the adhesive limit w5./_15 |achach the torque transfer from the expiring switching element to the first incoming switching element of the change of the gear ratio begins to adjust the engine speed of the speed of the target gear. Since no adaptation of the speed to the intermediate gear is necessary (the speed adjustment is forced through the clutch on - the speed synchronization to the intermediate passage is virtually uncontrolled), switching time is saved. As a result, on the one hand a fast synchronization time can be achieved, while on the other hand it is ensured that the rotational speed synchronization is smooth, since the approach of the rotational speed to the target rotational speed takes place with a low gradient. After the speed phase, the shift continues in a conventional manner with a second torque phase to engage the clutch of the target gear. After that follows a recovery phase with a safety ramp.
    In the following the invention will be explained in more detail with reference to a non-limiting embodiment, which is illustrated in the drawing.
    Show it
    1 schematically shows a vehicle drive train for carrying out the method according to the invention,
    2a shows a speed curve during an indirect switching operation according to the prior art,
    2b shows a torque curve during an indirect switching operation according to the prior art,
    3a shows a speed curve during an indirect shift from a high gear to a low gear when using the method according to the invention,
    3b shows a torque curve during an indirect shift from a high gear to a low gear when using the method according to the invention,
    Fig. 4a shows a speed curve during an indirect shift from a low gear to a higher gear when using the method and
    Fig. 4b shows a torque curve during an indirect shift from a low gear to a higher gear when using the method according to the invention.
    1 shows a vehicle drive train 20 arranged between an input shaft 11 and an output shaft 12 with a vehicle transmission 10 and a torque converter 13, which is suitable for carrying out the method according to the invention. With the input shaft 11, a non-illustrated prime mover - for example, an internal combustion engine with the output shaft 12, a not further shown output of the vehicle is connected. The example designed as an automatic transmission vehicle transmission 10 has a first planetary gear set 14 and a second planetary gear set 15, a first switching element A, a second switching element B, a third switching element C, a fourth switching element D and a fifth switching element E, wherein the second planetary gear set 15 as Ravigneaux wheelset is formed. In the exemplary embodiment, the switching elements A, B, E are designed as clutches and the switching elements C, D as braking devices. With SI, S2 and S3, the sun gears of the planetary gear sets, with PI, P2, P3, the planetary gears of the plate sets, and designated by Hl, H2, the ring gears of the planetary gear sets. Of course, other transmission configurations for carrying out the method according to the invention are possible.
    FIGS. 2 to 4 respectively show the profiles of the rotational speeds n and of the torque T over the time t during indirect gear changes. 2a, 3a and 4a are respectively the engine speed nM, the speed of the output gear n0, the speed of the intermediate gear nz and the speed of the target gear ni entered. In FIGS. 2b, 3b and 4b are respectively the motor torque TM (input torque - shown only in FIGS. 2b and 4b), the torque Tie of the first retracting switching element, the torque T2e of the second retracting switching element, the torque Ta of the retracting switching element , and the torque Tc of the continuous switching element shown. In addition, in each case qualitatively the approximate course of the output torque J12 at the output shaft 12 is shown in FIGS. 3b and 4b.
    2a and 2b respectively show the course of the rotational speed n and the torque T over the time t during an indirect gear change in a downshift from a higher to a lower gear, for example, from 6th gear to 3rd gear, using a known from the prior art method, with about the 5th gear is used as an intermediate. The gear change is divided into the preparation phase PP, the first speed phase SP1, the first torque phase TP1, the second speed phase SP2, the second torque phase TP2 and the recovery phase RP. Before the preparation phase PP both incoming switching elements (here first switching element A and second switching element B) are opened. During the preparation phase PP, the first entering switching element (in the present case, the second switching element B) is filled and guided from the completely open position (corresponding to T0) to the contact point TKp (so-called "kiss point") During the first rotational phase SP1, the engine speed becomes nM with the speed nz synchronized with the gear ratio of the intermediate gear (here 5th gear) During the first torque phase TP1, the torque is transferred from the source gear (here 6th gear) to the intermediate gear (here 5th gear), the second retracting switching element (here In this first torque phase TP1, the engine speed nM is usually maintained at the speed nz of the intermediate gear until the torque transfer from the source gear to the intermediate gear is completed, this section occupying a certain time Δt is designated in Fig. 2a with X. The first entering Scha ltelement (here first switching element A) is filled and led to the touch point (see line Tie). After the first torque phase TP1, the engine speed nM is synchronized with the speed ni of the target gear (here, 3rd gear) in a second rotational speed phase SP2. In the second torque phase TP2, the torque is transferred from the intermediate gear (here 5th gear) to the target gear (here 3rd gear), wherein all switching elements occupy the positions assigned to the target gear. It is therefore also the first retracting switching element (here first switching element A) completely closed, and the continuous switching element (here fifth switching element E) completely open. The second torque phase TP2 is followed by a recovery phase RP, in which the clutch torque of the retracting second clutch is increased beyond the engine torque TM with a defined safety factor. The entire gear change sequence thus has a preparation phase PP, two rotational speed phases SP1, SP2, two torque phases TP1, TP2 and a recovery phase RP.
    3a and 3b respectively show the course of the rotational speed n and the torque T over the time t during an indirect gear change in a downshift operation in the train operation from a higher to a lower gear, for example, from 6th gear in the .¾ / r ng, when using the method according to the invention, with about the 5th gear is used as an intermediate. The gear change is divided into the preparation phase PP, the first torque phase TP1, the speed phase SP, the second torque phase TP2 and the recovery phase RP. Before the preparation phase PP both incoming switching elements (here first switching element A and second switching element B) are opened. During the preparation phase PP, the second retracting switching element (in the present case the second switching element B) is filled and guided from the fully open position (corresponding to T0) to the contact point TKp (so-called "kiss point") (see line T2e) Torque phase TP1 takes place the torque transfer from the source gear (here 6th gear) to the intermediate gear (here 5th gear), wherein the second retracting switching element (here the second switching element B) is closed .. The first incoming switching element (here first switching element A) is filled and In the first torque phase TP1, the synchronization to the intermediate gear (5th gear) is forced by the closing of the second incoming switching element B. The first torque phase TP1 is followed directly by a single rotational phase SP, in which the predominant synchronization of the engine speed nM with the speed ni of the target gear ( here 3rd gear) is performed. In the second torque phase TP2, the torque is transferred from the intermediate gear (here 5th gear) to the target gear (here 3rd gear), wherein all switching elements occupy the positions assigned to the target gear. It is therefore also the first incoming switching element (here first switching element A, corresponding to the line Tie) completely closed, and the continuous switching element (here fifth switching element E, corresponding to the line Tc) completely open.
    In contrast to the known method shown in FIGS. 2a and 2b, the synchronization between the speed of the target gear and the engine speed already begins in or at the end of the first torque phase TP1 and is continued in the speed phase SP and finally terminated in the second torque phase TP2.
    As before, the second torque phase TP2 is followed by a recovery phase RP, in which the clutch torque of the entering second shift element is increased beyond the engine torque TM with a defined safety factor. The entire gear change sequence thus has a preparation phase PP, a speed phase SP, two torque phases TP1, TP2 and eÄne. Recovery phase RP up.
    4a and 4b respectively show the course of the rotational speed n and the torque T over the time t during an indirect gear change in an upshift from a low to a higher gear, for example from 3rd gear to 6th gear, using the method according to the invention, wherein about the 4th gear is used as an intermediate. The gear change is again divided into the preparation phase PP, the first torque phase TP1, the speed phase SP, the second torque phase TP2 and the recovery phase RP. Before the preparation phase PP both incoming switching elements (here third switching element C and fifth switching element E) are opened. During the preparation phase PP here both the first and the second retracting switching element (here fifth switching element E and third switching element C) filled and out of the fully open position (corresponding to T0) to the touch point TKP (so-called "kiss point") out ( see Tie, T2e) During the first torque phase TP1, the torque is transferred from the source gear (here 3rd gear) to the intermediate gear (here 4th gear), the second engaging shift element (here the fifth shift element E) is closed In the second torque phase TP2, the torque is transferred from the intermediate gear (here 4th gear) to the target gear (here 6 Gear), with all the switching elements occupying the positions assigned to the target gear, so that the first will also enter de switching element (here third switching element C, corresponding to the line Tie) completely closed, and the continuous switching element (here first switching element A, corresponding to the line Tc) completely open.
    Even during the upshift in overrun begins - in contrast to previously known method for performing an indirect gear change - the synchronization between the speed of the target gear and the engine speed already in or at the end of the first torque phase TP1 and is continued in the speed phase SP and finally in the second torque phase TP2 ended.
    The second torque phase TP2 is followed, as before, by a recovery phase RP, in which the clutch torque of the entering second shift element is increased with a defined safety factor via the absolute input torque TM hjnaiiQ. The whole
    Gear change sequence thus has a preparation phase PP, a speed phase SP, two torque phases TP1, TP2 and a recovery phase RP.
    In comparison with known methods, only a single rotational speed SP for synchronizing the engine speed with the rotational speed of the target gear is necessary in the method according to the invention, whereby time can be saved during the switching process.
    For example, b [0] ei a simple train downshifts according to the prior art typically first speed synchronization over the extending switching element (the engine accelerates itself, in this time is little torque on the output available, the speed synchronization takes a certain time), only thereafter, the torque transfer is performed and the torque transmission ratio corresponds to the target gear.
    In a simple train downshift carried out according to the method according to the invention, first the first torque phase TP1 is carried out, in which the rotational speed has not yet been synchronized to the target gear. In a train downshift, however, the speed change of the engine can only be controlled with the retracting switching element when the engine speed nM is above the synchronous speed of the target gear (which at the beginning of the circuit may not yet be the case). The speed synchronization of the engine to the target speed is thus now enforced and conditioned not only by an excess torque of the motor relative to the torque transmitted by the switching element, but supported by the torque transmitted by the incoming switching element. The engine speed nM thus increases much faster. The additionally required energy is taken from the kinetic energy of the vehicle (hence the short deflection P at the output torque T12, contrary to the normal direction of acceleration, see Fig. 3b, 4b). In order to avoid a possibly arising Einkuppelruck, the continuous switching element is led to the, or under the adhesion point. Couples the incoming switching element for the intermediate gear (ie, the speed difference is zero), a speed difference is built directly in the continuous switching element - thus the engagement of the incoming switching element is attenuated for the intermediate and there are no significant vibrations in the drive train.
    Advantage of the method is that the (depending on the configuration of the elements circuit, transmission, engine, vehicle) about 300 ms to 800 ms lasting first speed phase omitted for synchronization.
    The total duration in a conventional indirect (dual) train downshift is, for example, 200 ms preparation phase, 500 ms first speed phase SP1 (speed synchronization 1), 300 ms first torque phase TP1 (torque transfer 1), 500 ms speed phase SP2 (speed synchronization 2), 300 ms second torque phase TP2 (Torque transfer 2) - in total about 1.8 seconds. If the first rotational speed phase SP1 is now omitted, a considerable time saving of 500 ms results in this example.
    The inventive method is advantageously suitable for a variety of types of vehicle transmissions such as dual clutch, automatic or other transmissions, in which at least two switching elements are provided. In dual-clutch transmissions, the incoming shift element for the intermediate gear and the outgoing shift element for the target gear are formed by the same clutch. Furthermore, the extending switching element for the intermediate passage and the incoming switching element for the target gear are formed by the same coupling.
    With the method according to the invention, short switching times can be realized in indirect switching operations, in particular in indirect train downshifts. Of course, the method according to the invention can also be applied to indirect thrust upshifts, which, however, are typically not time-critical from the driver's point of view.
    权利要求:
    Claims (5)
    [1]
    A method of performing shifts in a vehicle driveline (20) having a vehicle transmission (10), wherein an input shaft (11) of the vehicle driveline (17) is connected to an output shaft (12) through at least two shift elements via different gears at least during an indirect shift from a source gear to a target gear in a first torque phase, torque transfer from at least one extending shift element to at least one retracting first shift element, in a subsequent to the first torque phase (TP1) speed phase (SP) synchronization between the engine speed (nM ) and the speed (ni) of the target gear, and in a subsequent to the rotational speed phase (SP) second torque phase (TP2) a torque transfer from a continuous switching element is performed on a retracting second switching element, characterized in that the synchronization between the engine number of revolutions (nM) and speed (ni) of the target gear in or at the end of the first torque phase (TP1).
    [2]
    2. The method according to claim 1, characterized in that the synchronization between the speed (ni) of the target gear and the engine speed (nM) ends in or at the end of the second torque phase (TP2).
    [3]
    3. The method according to claim 1 or 2, characterized in that during the first torque phase (TP1), the continuous switching element is controlled to open or under the adhesion point.
    [4]
    4. The method according to any one of claims 1 to 3, characterized in that the first torque phase (TP1) begins immediately after a preparation phase (PP) for the gear change.
    [5]
    5. The method according to any one of claims 1 to 4, characterized in that in the synchronization, the change of the engine speeds (nM) over the time (t) between the speed of the output gear (n0) and the speed (ni) of the target gear is continuous.
    类似技术:
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    同族专利:
    公开号 | 公开日
    CN106438995B|2020-06-19|
    AT517581B1|2017-03-15|
    DE102016114087A1|2017-02-09|
    CN106438995A|2017-02-22|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    EP0478945A2|1990-10-05|1992-04-08|Mercedes-Benz Ag|Automatic gear change method of a multiple-path-gear-transmission using servo pressure means|
    EP0827861A2|1996-08-08|1998-03-11|Volkswagen Aktiengesellschaft|Method for gear shift of a double clutch gearbox and double clutch transmission therefor|
    US5961421A|1997-08-11|1999-10-05|Toyota Jidosha Kabushiki Kaisha|Power on skip downshift using three clutches|
    US6009768A|1998-01-13|2000-01-04|Toyota Jidosha Kabushiki Kaisha|Skip downshift control apparatus for automatic transmission|
    DE19853824A1|1998-11-21|2000-05-31|Getrag Getriebe Zahnrad|Automated motor vehicle drive train has parallel force transfer paths; second force transfer path transfers torque to drive shaft during force transfer interruption in first transfer path|
    EP1578636A1|2002-12-20|2005-09-28|Volkswagen Aktiengesellschaft|Method for controlling the shifting of an automatic twin clutch transmission|
    DE10349220A1|2003-07-16|2005-02-03|Volkswagen Ag|Gear changing method for double-clutch gearbox for road vehicle involves brief engagement of intermediate gear ratio when changing up or down to next gear on same layshaft|
    JP2010084945A|2010-01-18|2010-04-15|Aisin Aw Co Ltd|Shift control device for automatic transmission|
    WO2005008103A1|2003-07-16|2005-01-27|Volkswagen Aktiengesellschaft|Method for switching of a double-clutch gearbox on a motor vehicle|
    JP5808205B2|2011-09-07|2015-11-10|日産自動車株式会社|Coastal downshift control device for automatic transmission|CN110173561B|2019-05-24|2021-04-30|盛瑞传动股份有限公司|Self-adaptive method for gear shifting torque control of automatic gearbox and automatic gearbox|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    ATA50710/2015A|AT517581B1|2015-08-07|2015-08-07|METHOD FOR CARRYING OUT SWITCHES IN A VEHICLE DRIVE TRAIN|ATA50710/2015A| AT517581B1|2015-08-07|2015-08-07|METHOD FOR CARRYING OUT SWITCHES IN A VEHICLE DRIVE TRAIN|
    DE102016114087.2A| DE102016114087A1|2015-08-07|2016-07-29|A method of performing shifts in a vehicle driveline|
    CN201610826768.3A| CN106438995B|2015-08-07|2016-08-02|Method for carrying out a gear shift operation in a vehicle drive train|
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