The present invention relates to a method for controlling the operation of changing to a higher gear (upshift) in a motor vehicle equipped with a double clutch transmission.
With reference to
In a transmission of this type, the gear changing operation is performed in so-called power shift mode, namely with a phase where the starting gears (disengaging gear) and the end gears (engaging gear), which are each associated with a respective section of the transmission, are simultaneously engaged and transmission of the torque takes place via both sections of the transmission. Transfer of the torque from the disengaging section to the engaging section of the transmission therefore is performed by opening the friction clutch associated with the disengaging gear and simultaneously closing the friction clutch associated with the engaging gear. This phase is referred to herein below as the crossover phase of the friction clutches, or simply as the crossover phase. Opening of a clutch and simultaneous closing of the other clutch must be modulated according to suitable control logics which aim to ensure that the gear changing operation is performed as rapidly and comfortably as possible.
A gear changing operation will be described now in detail, assuming changing from a lower gear associated with the first section of the transmission to a higher gear associated with the second section of the transmission, considering a rigid axle model of the transmission of
The crossover phase of the friction clutches is preceded by a phase where the transmission of the driving power from the engine to the wheels occurs via a single section of the transmission, namely the section associated with the disengaging gear, the first friction clutch 20 (disengaging gear) being closed and the second friction clutch 24 (engaging gear) being open.
The simplified model represented by the following equation therefore applies:
where the angular velocity ωm of the driving shaft 22 is synchronized with the angular velocity ωp,dis of the first primary shaft 12 (disengaging gear) and where the resistive torque CR is considered to be constant for the entire gear changing operation.
The equivalent moment of inertia, referred to the primary shaft, of the transmission section associated with the disengaging gear is defined, without taking into account the moments of inertia of the individual shafts of the transmission, by the following equation:
The gear changing operation provides firstly for engagement of the engaging gear, obtained by means of rotational coupling between the idle gearwheel (which may be equally well the driving gearwheel or the driven gearwheel) of the gearing associated with this gear and the respective shaft (primary or secondary shaft, respectively), typically by means of a sliding engaging sleeve, while the friction clutch associated with the engaging gear is kept open, then the crossover phase of the friction clutches, during which the friction clutch associated with the disengaging gear is gradually opened, while the friction clutch associated with the engaging gear is gradually closed, and finally disengagement of the disengaging gear by means of uncoupling of the idle gearwheel (driving or driven gearwheel) of the gearing associated with this gear from the respective shaft (primary or secondary shaft, respectively).
The simplified model which describes the crossover phase, during which both the clutches are in a slipping condition, is represented by the following equations:
A first constraint imposed in the known strategies for controlling the gear changing operation is the synchronism between the angular velocities ωm of the driving shaft 22 and ωp,dis of the first primary shaft 12 (disengaging gear). The following relation must therefore apply:
ωm=ωp,dis. (6)
Assuming that the angular velocities ωm and ωp,dis are the same at the start time of the gear changing operation, the synchronism between the angular velocities of the driving shaft 22 and of the first primary shaft 12 (disengaging gear) during the entire crossover phase is ensured if the following relation is satisfied:
{dot over (ω)}m(t)={dot over (ω)}p,dis(t) (7)
Since ωp,dis and ωR are linked, on the basis of the equation (5), by the following relation:
ωp,dis=τdis·ωR, (8)
and, if the abovementioned condition of synchronism of the angular accelerations expressed by the relation (7) is set, the equation (3) becomes:
Jm·τdis·{dot over (ω)}R=Cm−CF,inn−CF,dis. (9)
Taking {dot over (ω)}R from the equation (4) and substituting it in the equation (9), the following equation which links the torque profiles of the engine and of the two friction clutches 20 and 24 in the condition of synchronism between driving shaft 22 and first primary shaft 12 (disengaging gear) is obtained:
Jeq·Cm−(Jeq+Jm·τinn·τdis)·CF,inn−CF,dis·(Jeq+Jm·τdis2)+Jm·τdis·CR=0. (10)
Taking CF,dis from the equation (10), the minimum torque profile of the first friction clutch 20 which ensures synchronism between the angular velocities ωm and ωp,dis of the driving shaft 22 and of the first primary shaft 12 (disengaging gear), respectively, is obtained:
If the first friction clutch 20 (disengaging gear) is controlled with a torque profile greater than the minimum torque profile defined by the equation (11), the previous transmission model with both the friction clutches 20 and 24 in a slipping condition, defined by the equations (3) and (4), is replaced by a new transmission model in which only the second friction clutch 24 is in a slipping condition, while the first friction clutch 20 is closed and therefore the first primary shaft 12 (disengaging gear) rotates at the same angular velocity as the driving shaft 22. This new model is defined by the following equations:
If the open condition of the second friction clutch 24 is set at the beginning of the crossover phase (time t=0), i.e.
CF,inn(0)=0, (14)
the initial minimum value of CF,dis:
is obtained from the equation (11).
If, moreover, the open condition of the first friction clutch is set at the end of the crossover phase (instant t=tfi), i.e.
CF,dis(tfi)=0, (16)
the following equation, which links the final value of the engine torque Cm to the final value of the torque CF,inn of the second friction clutch 24 (engaging gear):
is obtained from the equation (10).
From the equation (17) it can be seen that, in the case of negligible resistive torques CR, the final torque Cm(tfi) of the engine is greater than the final torque CF,inn(tfi) of the second friction clutch 24 (engaging gear).
In short, the equation (15) represents a general constraint for selection of the torque profile of the first friction clutch (clutch to be opened) which ensures no slipping of this clutch, while the equation (17) represents the link between the final values of the engine torque and of the torque of the second friction clutch (clutch to be closed) which ensures the synchronism between the angular velocities of the driving shaft and of the first primary shaft (disengaging gear) and the continuity of the angular acceleration at the time of opening of the first friction clutch.
The object of the present invention is to provide a method for controlling the operation of changing to a higher gear (upshift) in a motor vehicle equipped with a double clutch transmission, which enables to control the loss of longitudinal acceleration of the vehicle during the crossover phase of the friction clutches in a gear changing operation, in particular in an upshift operation.
This and other objects are fully achieved according to the invention by virtue of a control method for controlling the operation of changing from a lower gear to a higher gear in a motor vehicle equipped with an engine, with a driving shaft and with a double clutch transmission including first and second primary shafts, as well as first and second friction clutches operable to connect the first primary shaft and the second primary shaft, respectively, to the driving shaft, the gear changing operation including a crossover phase of the friction clutches during which the first friction clutch associated with the gear to be disengaged is opened and the second friction clutch associated with the gear to be engaged is closed, the method comprising the steps of:
The features and advantages of the invention will emerge clearly from the detailed description which follows, provided purely by way of non-limiting example with reference to the accompanying drawings, in which:
With reference to the diagram of a double clutch transmission for a motor vehicle shown in
This preferred mode of implementation of the control method is based on the idea of determining a given profile for the longitudinal acceleration of the vehicle during the crossover phase and defining consequently the profile of the engine torque. If, for example, a constant profile is determined for the longitudinal acceleration of the vehicle, the engine torque is incremented accordingly during the crossover phase.
The longitudinal acceleration of the vehicle is approximately described, without taking into account the elasticity of the gearbox shafts, by the equation:
where the expression {dot over (ω)}R has been obtained from the equation (13).
From the equation (18), assuming that CR is constant and considering that CF,inn increases during the crossover phase and that τinn is less than τdis, it follows that, in order to keep the longitudinal acceleration of the vehicle constant during the entire crossover phase, it is necessary to increment Cm.
At the start time of the crossover phase (t=0), taking into account that CF,inn(0)=0 (the second friction clutch 24 is still open and therefore does not transmit torque), the longitudinal acceleration of the vehicle, on the basis of the equation (13), is equal to:
At the end of the crossover phase (t=tfi), the first friction clutch 20 is open, the torque is transmitted entirely to the wheels via the transmission section associated with the new gear and the longitudinal acceleration, using the equation (4) and setting CF,dis=0, is therefore equal to:
In order for the longitudinal acceleration of the vehicle to be constant during the crossover phase, it is necessary that:
ax(tfi)=ax(0); (21)
and, therefore, on the basis of the equations (19) and (20):
The jerk, namely the derivative of the longitudinal acceleration, is defined by the following expression:
The derivatives of the engine torque Cm and of the torque of the friction clutch to be closed CF,inn are defined by the following expressions (considering the linear progression of these torques):
Using the expressions of Cm(tfi) and Cf,inn(tfi) provided by the equations (17) and (22), the equations (24) and (25) become:
If the expressions of Ċm and ĊF,inn provided by the equations (26) and (27) are substituted in the equation (23), confirmation of zeroing of the jerk is obtained.
The control method may also be implemented allowing for a certain reduction in the longitudinal acceleration of the vehicle during the crossover phase and therefore determining a final value for the longitudinal acceleration which is equal to a given percentage of the initial value. In this connection, it is pointed out that the expressions “initial value” and “final value” used in the present description and in the claims are to be intended as the value at the at the beginning of the crossover phase and as the value at the end of the crossover phase, respectively.
The main steps to be followed in order to define the torque profiles during the crossover phase in accordance with the control method according to the preferred mode of implementation of the invention described above, assuming that linear torque profiles are chosen (so that only the initial and final values of these profiles and the overall duration of the crossover phase need be defined), are as follows:
If the final value of the engine torque calculated in step d) is greater than the maximum value which the engine is able to provide, then the final value of the engine torque is suitably limited and the final value CF,inn(tfi) of the torque of the friction clutch to be closed is calculated by inversion of the equation (17) using the set value Cm(tfi).
As regards the torque profile of the friction clutch to be closed, in order to minimize the reduction in the longitudinal acceleration during the period immediately following the crossover phase, it is preferable to use as final value CF,inn(tfi) the minimum between the value calculated in step b) (value corresponding to the zero jerk condition) and a target value of the torque intended to be transmitted through the friction clutch associated to the new gear after the crossover phase, i.e. when the angular velocity of the engine is synchronized with the angular velocity of the primary shaft associated to the new gear, such a target value being calculated for instance on the base of the amount of depression of the accelerator pedal.
Owing, therefore, to a suitable definition of the torque profiles, in particular of the engine torque profile, with the control method according to the preferred mode of implementation of the method described above, it is possible to zero or at least minimize the jerk, thus ensuring better performance and greater travel comfort in upshift manoeuvres than in the prior art.
According to an alternative mode of implementation of the control method according to the invention, the final value of the longitudinal acceleration of the vehicle is chosen so as to obtain a constant engine torque profile during the crossover phase (i.e. from the initial time t=0 to the final time t=tfi). In other words, first the final value of the longitudinal acceleration of the vehicle corresponding to a constant engine torque is calculated, and then the final value of the engine torque is set to be constant and equal to the initial value of the engine torque. Once this constant engine torque value is established, the torque profiles during the crossover phase are determined according to the following steps:
Leaving aside the effect of the resistive torque CR and since τdis is greater than τinn (upshift), determination of a constant engine torque Cm results in a course of the longitudinal acceleration of the vehicle which decreases over time, as can be seen in
The strategy of generating reference torque profiles according to the preferred mode of implementation of the control method according to the invention illustrated in the first part of the description may be combined where necessary with the alternative mode of implementation illustrated in the second part of the description, for example using the former only for medium- or low-load gear changes and for low gears.
Control of the gear changing operation according to the invention may be performed in an open loop, even though closed loop control is preferable in view of the greater robustness.
Naturally, without modifying the principle of the invention, the embodiments and the constructional details may be greatly varied with respect to those described and illustrated purely by way of a non-limiting example.
In this connection, the invention is clearly applicable not only to two-wheel drive vehicles but also to four-wheel drive vehicles, not only to road vehicles but also to off-road vehicles, not only to vehicles with a transverse gearbox but also to vehicles with a longitudinal gearbox and not only to vehicles with synchronizers mounted on the two primary shafts of the gearbox but also to vehicles with synchronizers mounted on the secondary shaft (or secondary shafts) of the gearbox. Moreover, the invention is applicable not only to vehicles with double clutch transmissions, but also to vehicles equipped with a transmission having more than two friction clutches (for example to tractors and industrial vehicles).
Number | Date | Country | Kind |
---|---|---|---|
08425642 | Oct 2008 | EP | regional |
Number | Name | Date | Kind |
---|---|---|---|
5407401 | Bullmer et al. | Apr 1995 | A |
5669851 | Tietze | Sep 1997 | A |
7704189 | Baur et al. | Apr 2010 | B2 |
20050037893 | Siebigteroth et al. | Feb 2005 | A1 |
Number | Date | Country |
---|---|---|
199 39 334 | Mar 2001 | DE |
Number | Date | Country | |
---|---|---|---|
20100113219 A1 | May 2010 | US |