Abstract:
The invention relates to a method for controlling a gear shift, especially a pulling upshift in a parallel-shift transmission of a vehicle, said parallel-shift transmission having two transmission branches situated parallel to each other between an output shaft of a driving engine of the vehicle and a transmission output shaft, whereby an input shaft of each transmission branch is coupleable to the output shaft via a clutch assigned thereto and the input shaft of each transmission branch may be brought into rotationally fixed engagement with the output shaft having at least one prescribed gear ratio so that by disengaging the one clutch and engaging the other clutch a pulling-force-interruption-free change of the gear ratio between the engine output shaft and the transmission output shaft is possible, in which method during a gear ratio change the torque transmissible by the clutches is regulated in a controlled, prescribed manner and the load of the driving engine is regulated in such a manner that a prescribed slip of the clutches is maintained.

Description:
CROSS-REFERENCE TO RELATED APPLICATIONS  
       [0001]     This patent claims priority of German Patent Application No. 10 2004 007 101.2, filed Feb. 13, 2004, which application is incorporated herein by reference.  
       BACKGROUND OF THE INVENTION  
       [0002]     The invention relates to a method and a device for controlling a gear change, especially a pulling upshift, in a parallel-shift transmission of a vehicle.  
         [0003]     In recent times, parallel-shift transmissions for use in passenger vehicles have been of increasing interest, especially because they enable fuel-consumption advantages over traditional automatic planetary transmissions.  
       BRIEF SUMMARY OF THE INVENTION  
       [0004]      FIG. 5  shows the drive train of a conventional vehicle. A driving engine  10  is connected via a clutch device  12  to a transmission whose output shaft  16  is connected via a cardan shaft  18  and a differential  20  to rear wheels  22  of a motor vehicle.  
         [0005]     A clutch actuator  24  is provided for operation of clutch device  12 . Actuators  26  and  28  are provided for the operation of transmission  14 . Actuators  24 ,  26 ,  28  are controlled by an electronic control device  30  having a microprocessor and accompanying memories. Inputs of electronic control device  30  are connected to position sensors contained in the actuators and speed sensors  32  and  34  for detecting, for example, a speed of a transmission shaft and a speed of cardan shaft  34  or output shaft  16 . Furthermore, an input of control device  30  is connected to position sensor  36  of selector lever  38  for the activation of various programs of control device  30 .  
         [0006]     To control driving engine  10 , engine control unit  40  is used, whose inputs are connected to position sensor  42  for detecting the position of an accelerator pedal, speed sensor  46  for detecting the speed of the crankshaft of the internal combustion engine, temperature sensor  48  for detecting an engine temperature, sensors  50  for detecting additional operating parameters of the engine and a position sensor for detecting the position of actuator  52  for load actuator  53  of driving engine  10 . Furthermore, sensors  54  connected to engine control unit  40  may be provided for detecting the speeds of front wheels  56  and rear wheels  22 . Engine control unit  40  is connected to transmission control device  30  via a data line, for example CAN data bus  58 , through which data is communicated.  
         [0007]      FIG. 6  diagrammatically shows the structure of clutch device  12  and transmission  14 . Output shaft  58  of driving motor  10  is rotationally fixedly connected to two parallel transmission branches  60  and  62 , each of which is rotationally fixedly connected via transmission unit  64  or  66  to drive shaft  16 . Transmission units  64  and  66  may be conventional shift transmissions whose gears are each rotationally fixedly connected in a known way via actuation device  68  or  70 . Clutches K 1  or K 2  are operable via actuators  24   1  or  24   2 .  
         [0008]      FIG. 7  shows the structure of a twin-clutch or parallel-shift transmission having a total of three shafts, namely, two input shafts  72  or  74 , which may be rotationally fixedly connected via different gear sets to common output shaft  16 . The gear sets are in continuous contact with each other. The gears of input shafts  72  or  74  may be synchronized in a known way via coupling members  76 , which are axially displaceable on the shafts, with the shafts and brought into rotationally fixed engagement with them. To move coupling members  76  and thereby shift the gears, actuation device  78  is provided with selector element  80  and shift element  82 , the selector element being operable, for example, by actuator  26  ( FIG. 4 ) and the shift element being operable by actuator  28  in a known way to shift the individual gears. At the input end, clutches K 1  and K 2  are in rotationally fixed engagement with output shaft  58  of the driving engine. Clutches K 1  and K 2  are operated by clutch actuators  241  and  242  ( FIG. 6 ).  
         [0009]     If, for example, clutch K 1  is engaged and a ratio defined by transmission branch  60  is accordingly present between output shaft  58  and output shaft  16  in the illustrated example in first, third or fifth gear, one of the gears of transmission branch  62  is shifted when clutch K 2  is disengaged so that just by disengaging clutch K 1  and simultaneously engaging clutch K 2  a pulling-force-free ratio change from a gear of transmission branch  60  to a gear of transmission branch  62  can occur.  
         [0010]     This gear or ratio change must be accomplished as comfortably as possible for the driver of a vehicle, whereby, depending on the position of selector lever  38 , different programs may be activated in control device  30  according to which the gear change takes place in as quick, sporty, soft and comfortable a way as possible or otherwise in an optimized manner.  
         [0011]     The actuation of clutches K 1  and K 2  and of the load actuator of driving engine  10  therefore occurs according to programs that are stored, for example, in control device  30  from whence actuator  52  of load actuator  53  is also operable via BUS  58  and control unit  40 .  
         [0012]     Lowering the torque of the first engaged clutch somewhat and increasing the engine torque briefly via the reduced clutch torque in a gear or ratio change so that the clutch slips is known from DE 101 60 308 A1. The slipping speed of, for example, 10 to 20 rpm is maintained via regulation of the clutch actuator during a gear change. The clutch transmitting the new gear ratio is engaged by controlled drive of its actuator, whereupon the disengagement of the clutch that transmits the torque at the beginning occurs in a controlled manner, because its slipping speed is kept constant. As soon as the “hold” clutch is completely disengaged, the “new” clutch transmits the entire engine torque and then for the time being is engaged no further. However, because the engine and thus also the engine-side half of the new clutch rotates at the speed of the transmission input shaft plus the slipping speed, but the transmission-side half of the new clutch rotates at the speed of the transmission input shaft, the engine speed is pulled down to the speed of the newly active transmission input shaft by a subsequent lowering of the engine torque to below the clutch torque of the new clutch. The deceleration of the engine brings an additional torque that stems from the energy stored in the flywheel of the engine and acts via the transmission input shaft on the transmission output shaft. The lowering of the engine torque corresponds to the torque contribution based on the deceleration of the engine so that no additional torque is applied to the transmission output shaft due to the deceleration of the engine. The new clutch is then completely engaged and the engine torque is reduced to its original value.  
         [0013]     Running the clutch that first transmits torque to its slip limit and briefly increasing the engine torque in a pulling-force-free gear ratio change of a parallel-shift or twin-clutch transmission so that the torque-transmitting clutch slips with a reserve and the new clutch does not stick in the transition from the old clutch to the new clutch is known from DE 103 08 700 A1.  
         [0014]     The object of the invention is to specify a method and a device for carrying it out in which a gear change of a parallel-shift transmission, especially a pulling upshift, may be as comfortably configured as possible under all conditions.  
         [0015]     The portion of the task concerning the method is achieved using a method for the control of a gear change, especially a pulling upshift in a parallel-shift transmission of a vehicle, the transmission having two transmission branches situated between an output shaft of a driving engine of the vehicle and a transmission output shaft, whereby an input shaft of each transmission branch is coupleable to the output shaft via a clutch assigned thereto and the input shaft of each transmission branch can be brought into rotationally fixed engagement with the output shaft having at least one prescribed ratio so that by disengaging the one clutch and engaging the other clutch a pulling-force-interruption-free change of the gear ratio between the engine output shaft and the transmission output shaft is possible, in which method during a gear ratio change the torque transmissible by the clutches is changed in controlled, prescribed manner and the load of the driving engine is controlled in such a manner that a prescribed slip of the clutches is maintained.  
         [0016]     Therefore, in the method of the invention, the torque transmissible by the clutches during a gear ratio change is controlled, i.e., changed according to a set, prescribed program, whereas the engine torque during the transmission ratio change is changed in a controlled manner such that a prescribed clutch slip is maintained. This has the advantage that the clutch torque which is decisive for the quality of the torque that is active on the output shaft of the transmission may be controlled independently and therefore optimally in relation to the desired output torque of the transmission. One objective of this adjustment lies in maintaining the slip that was set immediately before the beginning of the gear ratio change. The increase of the slip would be unpleasantly perceived by the driver as a turning away of the engine speed. A sign change of the slip is likewise unpleasant, because it would become noticeable via a torque jump at the output of the transmission.  
         [0017]     Therefore, an embodiment of the method of the invention is preferable in which a prescribed slip that is maintained during the gear ratio change is set before the beginning of the gear ratio change on the clutch transmitting the old gear ratio.  
         [0018]     An implementation of the method of the invention is preferred such that the torque of the clutch transmitting the old gear ratio is changed continually during the gear change to approximately zero and the torque of the clutch transmitting the new gear ratio is changed continually from approximately zero to a prescribed value.  
         [0019]     Preferably, the sum of the torques transmissible by both clutches changes during the gear ratio change from a starting value to a final value and the starting value is related to the final value somewhat as the old gear ratio is related to the new gear ratio.  
         [0020]     To maintain the clutch slip, the load of the driving engine is advantageously pre-controlled corresponding to the sum of the instantaneous torque values transmissible by the clutches.  
         [0021]     Advantageously, the pre-control of the load of the driving engine is also controlled corresponding to an additional parameter, which includes at least one of the following parameters: 
        dynamic portion from the acceleration of the input shaft transmitting the old gear ratio;     torque that results from the difference between the acceleration of the speed of the driving engine and the input shaft transmitting the old gear ratio at the beginning of the gear ratio change; and,     clutch torque error on the clutch transmitting the old gear ratio at the beginning of the gear ratio change.        
 
         [0025]     To keep the slip of the clutches constant, the load of the driving engine is advantageously controlled via a D-controller to which the time derivative of the current slip is supplied as an input value.  
         [0026]     Preferably, the load of the driving engine is regulated to hold constant the slip of the clutches alternatively or additionally using a P-controller, to which the difference of the instantaneous slip and the slip at the beginning of the gear ratio change is supplied as an input value.  
         [0027]     The object of the invention directed to a device is achieved using a device for controlling a gear change, especially a pulling upshift in a parallel-shift transmission of a vehicle that has two transmission branches situated parallel to each other between an output shaft of a driving engine and a transmission output shaft, whereby an input shaft of each transmission branch is coupleable via a clutch assigned thereto to the output shaft, and the input shaft of each transmission branch may be brought into rotationally fixed engagement with the output shaft using at least one prescribed gear ratio, so that by disengaging the one clutch and engaging the other clutch a pulling-force-free change of the ratio between the engine output shaft and the transmission output shaft is possible, which device includes: 
        an actuation device for the clutch of the first transmission branch;     an actuation device for the clutch of the second transmission branch;     an actuation device for a load actuator of the driving engine;     sensor devices for detecting the slip of the first clutch and the second clutch; and     a control device connected to the actuation devices and the sensor devices for controlling the operation of the actuation devices in such a manner that a method is implemented as described in any of claims  1  to  8 .       
 
     
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
       [0033]     The invention is explained below in reference to exemplary diagrammatic drawings and with additional details.  
         [0034]     Shown are:  
         [0035]      FIG. 1  shows diagrams for the explanation of parameters that are relevant for the pre-control of the driving engine;  
         [0036]      FIG. 2  shows a flow diagram for the explanation of the regulation of the engine torque;  
         [0037]      FIG. 3  shows diagrams for the explanation of a transmission ratio change with change of a driver&#39;s desired torque;  
         [0038]      FIG. 4  shows diagrams similar to those of  FIG. 3 ;  
         [0039]      FIG. 5  is a known vehicle drive train in which the invention may be implemented;  
         [0040]      FIG. 6  is a schematic illustration of a known parallel-shift transmission; and,  
         [0041]      FIG. 7  is an exemplary design of a 3-shaft parallel-shift transmission. 
     
    
     DETAILED DESCRIPTION OF THE INVENTION  
       [0042]     In the following description of the invention, reference is made to an exemplary vehicle drive train as shown in  FIG. 5 , in which clutch actuator  24  includes two actuators that are controllable independently of each other by control device  30  according to programs stored there and with which the two clutches K 1  and K 2  ( FIGS. 5 and 6 ) are operable independently of each other in such a manner that a defined clutch torque is transmissible at each clutch. The slip of the clutches may be calculated via their input speed (detected by speed sensor  46 ) and the speeds of output shafts  72  and  74  ( FIG. 6 ), detected by sensors  32 , or from the speed of output shaft  16  (detected by sensor  34 ) and the gears that are active at the time (recognized by control device  30 ).  
         [0043]     During a gear shift or a gear ratio change, the clutch of the old gear (old clutch) is disengaged and the clutch of the target gear (new clutch) is engaged at a specified torque. In this context the actual gear ratio change or gear shifting that is in effect on the vehicle occurs. By disengaging the old clutch and engaging the new one, the torque acting on output shaft  16  changes according to the gear ratio. The prerequisite for a transition without jerking is that both clutches slip in the overall course of operation. The clutch torques are controlled, whereas the engine torque is regulated. The regulation occurs in such a way that driving engine  10 , by changing the position of its load actuator  53  at engine output shaft  58 , outputs a torque that leads to a slip of the clutches, which are actuated in a controlled manner. The regulation of the position of load actuator  53  or of the torque of engine output shaft  58  occurs in the context of a pre-control on which that actual regulation is superimposed.  
         [0044]     The pre-control is explained below in reference to  FIG. 1 , whereby the time is indicated on the abscissa, different torques are indicated in the top part of  FIG. 1  and different speeds are indicated in the bottom part. t phase  is used to indicate a prescribable time period during which a gear ratio change occurs and which is determined, for example, by the program activated using the selector lever.  
         [0045]     Dashed line I of  FIG. 1  indicates the pre-controlled torque on the output shaft of the driving engine; dotted and dashed curve II indicates the torque that is transmissible by the old clutch. Dashed and double-dotted curve III indicates the torque that is transmissible by the new clutch.  
         [0046]     As is evident, before the beginning of a gear ratio change, the torque of the old clutch is lowered slightly so that the old clutch slips. The initial slip of the old clutch, which is prescribable in the program, is held to a constant value during the entire gear ratio change by modifying the engine torque, this slip being valid both for the old clutch as well as for the new clutch. The torque transmissible by the old clutch is reduced to a very small value in a linear manner beginning with the beginning of the gear ratio change until the end of the gear ratio change corresponding to the prescribed period t Phase  of the gear ratio change. The torque that is transmissible by the new clutch is preferably increased in a controlled, linear manner according to line III up to a final value at the end of the gear ratio change, whereby the torque transmissible by the new clutch at the end preferably relates to the torque transmissible by the old clutch at the beginning of the gear ratio change as the beginning gear ratio relates to the final gear ratio; that is, in a pulling upshift, for example, the final torque is much larger than the beginning torque, just as, at the same speed of the driving engine, the output shaft in the lower gear turns faster than in the higher gear. Precontrol line IV results, which equals the sum of the instantaneous clutch torques that are transmissible at a given time, namely M Cl,Alt +M Cl,Neu .  
         [0047]     Overlapping the pre-control torque according to line IV is a torque M Dyn,Alt,Begin , which corresponds to the dynamic portion from the acceleration of the old transmission input shaft, i.e., M Dyn, Alt =J Eng ·ω Alt . This dynamic portion abates slightly during the gear ratio change.  
         [0048]     In addition a term M Err  is added, which is the clutch torque error on the old clutch at the beginning of the overlap, which includes the friction value and contact point error and naturally drops off to zero at the end of the gear ratio change.  
         [0049]     The following applies for M Err : M Err =M Eng −M Cl, Alt −M Cl, Neu −M Dyn, Alt, Begin −M Acc .  
         [0050]     M Dyn, Alt Begin  is determined at the beginning of the gear ratio change. M Err  is a torque that applies only for the old clutch and is not transmissible to the new one. Thus, M Err  is reduced during the gear change to zero.  
         [0051]     M Acc  is a torque that results from the difference between the accelerations of the engine speed and the old transmission input shaft, measured at the beginning of the gear ratio change, and amounts to: 
 
 M   Acc   =J   Eng *ω Acc  
 
         [0052]     Therefore, the following results for the pre-control engine torque:  
         M     Eng   ,   precontrol       =       M     Cl   ,   Alt     ′     +     M     Cl   .   Neu       +       M   Err     ·         t   Phase     -   t       t   Phase         +     M     Dyn   ,   Alt             
 
 If one uses the aforementioned formula in the present formula for M Err , the following results for the time t=0: 
 
 M Eng,precontrol =M Eng −M Acc , as illustrated in  FIG. 1 . 
 
         [0053]     Also added to the pre-control engine torque M Eng,precontrol  is the torque M Acc , which decreases in a linear manner during the gear ratio change.  
         [0054]     The period t Phase  may be set in advance and remains constant during a gear ratio change.  
         [0055]     The period t Phase  may be set in advance and remains constant during a gear ratio change.  
         [0056]     In the curves associated with the speeds, dashed curve VI shows the course of engine speed ω Eng , single-dotted line VI the speed ω alt  of the “old” input shaft and double-dotted line VII the speed ω neu  of the “new” input shaft.  
         [0057]     ω Acc  represents the part of the acceleration of the engine speed that exceeds acceleration ω Alt , that is: 
 
ω Acc =ω Eng −ω alt  
 
         [0058]     One goal of the shift strategy is to achieve an acceleration of engine speed ω Eng  that is equal to the acceleration of the old transmission input shaft, that is ω Acc =0.  
         [0059]     Superimposed on the pre-control of the torque that is output by the driving engine, which is explained with reference to  FIG. 1 , is a control that includes a D-controller, which uses as an input value the time derivative of the slip Δω Act  at a given time. Parallel to this, a P-controller is switched whose input includes the difference between the current slip Δω Act  and the slip at the phase start or the start of the gear ratio change Δω Anf . The task of the P-controller is to prevent the slip from phasing out completely. The P-controller is only switched on if the absolute value of the slip becomes smaller than the slip that was determined at the beginning of the gear ratio change.  
         [0060]     Using the flow diagram according to  FIG. 2 , a control routine is explained below.  
         [0061]     A control routine is triggered by control device  30 , which indicates a forthcoming gear ratio change. If the beginning of the gear ratio change is present (t=0; step  90 ), then the starting slip Δω Anf  is set equal to the current or instantaneous slip Δω Act . The program proceeds to step  92  in which a check is made of whether the absolute value of Δω Act  is less than or equal to the absolute value of Δω Anf . If so, then in step  93  a proportional engine torque M P  is determined by the proportional controller in the following equation:  
         M   P     =           Δ   ⁢           ⁢     ω   Act       -     Δ   ⁢           ⁢     ω   Anf               sgn   ⁡     (     Δ   ⁢           ⁢     ω   Anf       )       ·   Δ     ⁢           ⁢     ω   Anf         ·   K_SEngTrqEngPThres         
 
 K being a stored proportionality constant. 
 
         [0062]     Next, the program proceeds to step  94 , in which an engine torque M D =Δω Act J Eng  is calculated by the differential controller, so that in step  95  an engine torque M Eng =M precontrol −M D −M P  is set.  
         [0063]     In the event that the condition of step  92  is not present, the proportional engine torque is set to 0 in step  96  and the program proceeds directly to step  94 .  
         [0064]     It should be pointed out that other types of controls are possible and that both the D-controller and the P-controller do not inevitably have to be present.  
         [0065]     In the following, the control of the clutch torques is explained:  
         [0066]     As is depicted in  FIG. 1 , the clutch torque of the old clutch (curve II) declines in a linear manner until it is completely disengaged. The overlap time or the period of the gear ratio change is prescribed and is a function of, for example, the shifting program that is selected at a given time.  
         [0067]     The clutch torque of the new clutch is kept at 0 before a gear ratio change, whereupon it is ensured that the clutch may react as quickly as possible to the torque demand during the gear ratio change, and any possible slack in the transmission is overcome.  
         [0068]     In order to be able to take into account a possible change of the driver&#39;s desired torque M FB  during a gear ratio change, the torque of new clutch M Cl, Neu  is recalculated in each interrupt according to the following formula (see  FIG. 3 ):  
         M     Cl   ,   Neu     ′     =       M     Cl   ,   Neu     ′     +           M   FW     -     M     Cl   ,   Neu     ′           t   Phase     -   t       ·     t   step             
 
 t Phase  being the overlap or gear ratio change period, t designating the current time and t step  designating the length of the step. 
 
         [0069]     Shown in  FIG. 3  are: 
        curve a) driver&#39;s desired torque M FW ;     curve b) the target torque M Cl, Alt, Soll  of the old clutch;     curve c) actual torque Cl, Alt, Ist  of the old clutch;     curve d) target torque M Cl, Alt, Soll  of the new clutch; and     curve e) actual torque M Cl, Neu, Ist  of the new clutch.        
 
         [0075]     In order for the clutch to “respond” faster at the beginning of a gear ratio change, another clutch torque is calculated parallel to the previous clutch torque as follows:  
           M     Cl   ,   Neu     ″     =     min   ⁢       M   FW     3         ,       820.0   ·   K     ⁢     :     ⁢   _JENG         
 
 The parameters of the min-function are experimentally determined and adapted to the particular vehicle. The greater of the two torques M′ Cl, Neu  and M″ Cl, Neu  is always used. 
 
         [0076]     In reference to  FIG. 4 , the calculation of torque MCI is explained again using the formula  
         M     Cl   ,   Neu     ′     =       M     Cl   ,   Neu     ′     +           M   FW     -     M     Cl   ,   Neu     ′           t   Phase     -   t       ·     t   step             
 
         [0077]     Overlap period t Phase  in this context is 50 ms, step length t step  is 10 ms and driver&#39;s desired torque M FM  at the beginning is 100 Nm and after 30 ms drops to 0. Before the overlap, the clutch torque of new clutch M Cl  is again 0. For new clutch torque M Cl,Neu  the following values are attained:  
               At   ⁢           ⁢   instant   ⁢           ⁢   t     =     0   ⁢     :                     M     Cl   ,   Neu       =         0   ⁢           ⁢   Nm     +             100   ⁢           ⁢   Nm     -     0   ⁢           ⁢   Nm           50   ⁢           ⁢   ms     -     0   ⁢           ⁢   ms         ·   10     ⁢           ⁢   ms       =     20   ⁢           ⁢   Nm                     At   ⁢           ⁢   instant   ⁢           ⁢   t     =     10   ⁢           ⁢   ms   ⁢     :                     M     Cl   ,   Neu       =         20   ⁢           ⁢   Nm     +             100   ⁢           ⁢   Nm     -     20   ⁢           ⁢   Nm           50   ⁢           ⁢   ms     -     10   ⁢           ⁢   ms         ·   10     ⁢           ⁢   ms       =     40   ⁢           ⁢   Nm                     At   ⁢           ⁢   instant   ⁢           ⁢   t     =     20   ⁢           ⁢   ms   ⁢     :                     M     Cl   ,   Neu       =         40   ⁢           ⁢   Nm     +             100   ⁢           ⁢   Nm     -     40   ⁢           ⁢   Nm           50   ⁢           ⁢   ms     -     20   ⁢           ⁢   ms         ·   10     ⁢           ⁢   ms       =     60   ⁢           ⁢   Nm                     At   ⁢           ⁢   instant   ⁢           ⁢   t     =     30   ⁢           ⁢   ms   ⁢           ⁢     (       M   FWM     =     0   ⁢           ⁢   Nm       )     ⁢     :                     M     Cl   ,   Neu       =         60   ⁢           ⁢   Nm     +             0   ⁢           ⁢   Nm     -     60   ⁢           ⁢   Nm           50   ⁢           ⁢   ms     -     30   ⁢           ⁢   ms         ·   10     ⁢           ⁢   ms       =     30   ⁢           ⁢   Nm                     At   ⁢           ⁢   instant   ⁢           ⁢   t     =     40   ⁢           ⁢   ms   ⁢           ⁢     (       M   FWM     =     0   ⁢           ⁢   Nm       )     ⁢     :                     M     Cl   ,   Neu       =         30   ⁢           ⁢   Nm     +             0   ⁢           ⁢   Nm     -     30   ⁢           ⁢   Nm           50   ⁢           ⁢   ms     -     40   ⁢           ⁢   ms         ·   10     ⁢           ⁢   ms       =     0   ⁢           ⁢   Nm                 
 
 As emerges from the preceding description, the calculation ensures that at the end of the overlap phase the torque of the new clutch corresponds to the value of the driver&#39;s desired torque. 
 
         [0078]     In full load shifts, in which no further increase of the engine torque is possible and the new clutch transmits substantially more than assumed, it may occur that the regulation of the engine torque that overlaps the pre-control is insufficient to prevent too sharp a decline in slip. In this case, a reaction via the clutches is necessary. Upon detection of such a situation, a bit is set and the “ramp-up” or torque increase of the new clutch is stopped.  
       Parts List  
       [0000]    
       
           10  Driving engine  
           12  Clutch device  
           14  Transmission  
           16  Transmission output shaft  
           18  Cardan shaft  
           20  Differential  
           22  Rear wheel  
           24  Clutch actuator  
           26  Actuator  
           28  Actuator  
           30  Control device  
           32  Speed sensor  
           34  Speed sensor  
           36  Position sensor  
           38  Selector lever  
           40  Engine control unit  
           42  Position sensor  
           44  Accelerator pedal  
           46  Speed sensor  
           48  Temperature sensor  
           50  Sensors  
           52  Actuator  
           53  Load actuator  
           54  Sensor  
           56  Front wheel  
           58  Engine output shaft  
           60  Transmission branch  
           62  Transmission branch  
           64  Transmission unit  
           66  Transmission unit  
           68  Actuation device  
           70  Actuation device  
           72  Input shaft  
           74  Input shaft  
           76  Clutch member  
           78  Actuation device  
           80  Selector element  
           82  Shift element