Abstract:
A method is described for operating a vehicle fitted with a continuously variable transmission (CVT) and having a lever for varying the transmission ratio of the CVT to permit the vehicle operator to vary the vehicle wheel speed. In the invention, the transmission ratio of the CVT is limited to a value dependent upon at least one of the prevailing engine speed and the rate of change of the engine speed.

Description:
FIELD OF THE INVENTION 
       [0001]    The present invention relates to the control of a continuously variable transmission (CVT) in a vehicle, in particular an agricultural vehicle, in which the wheel speed is varied by setting the transmission ratio of the CVT. 
       BACKGROUND OF THE INVENTION 
       [0002]    In certain tractors fitted with a CVT, in particular utility or compact tractors, the engine is controlled by means of both a hand lever and a foot lever, the latter being also referred to herein as a pedal. The engine operating point is chosen to correspond to the higher of two speed values demanded by the positions of the hand and foot levers. In normal operation, the engine operating point remains substantially constant and the wheel speed of the vehicle is varied by setting the transmission ratio in dependence upon the position of the foot lever. As the foot lever is depressed, the transmission ratio is increased to increase the wheel speed and this in turn increases the engine load. As long as the engine output power is capable of meeting the torque demand, the engine speed does not change appreciably when the foot pedal demands a lower engine speed than the hand lever, otherwise pressing the pedal results both in an increase of the transmission ratio and in an increase in the engine speed. 
         [0003]    If, however, the vehicle is subjected to a sudden increase in wheel load, such as if the vehicle commences to travel up an incline, and the engine output power cannot be increased to meet the additional torque demand, then the engine speed will decrease and wheel speed will drop. The natural tendency of a driver under such conditions is to depress the foot lever still further, i.e. to treat the foot lever in the same way as an accelerator pedal and to accelerate harder. This, however, has an opposite effect to that desired by the operator, in that the demanded increase in transmission ratio will add to the engine load and cause the engine speed to drop further. This can ultimately result in stalling of the engine and the vehicle. 
       SUMMARY OF THE INVENTION 
       [0004]    With a view to mitigating the foregoing disadvantage, the present invention provides a method of operating a vehicle fitted with a CVT and having a lever for varying the transmission ratio of the CVT to permit the vehicle operator to vary the vehicle wheel speed, characterised in that the transmission ratio of the CVT is limited to a value dependent upon at least one of the prevailing engine speed and the rate of change of the engine speed. 
         [0005]    Preferably, the limit value of the transmission ratio increases with engine speed within a lower range of engine speeds and is substantially constant throughout a contiguous higher range of engine speeds. 
         [0006]    By limiting the value of the transmission ratio at lower engine speeds, the invention prevents the operator from placing excessive torque demands on the engine and thus avoids potential stalling of the engine and the vehicle. 
         [0007]    In accordance with a second aspect of the invention, there is provided a vehicle having an engine, a CVT, a lever for enabling an operator of the vehicle to vary the vehicle speed, and a control unit for applying to the CVT a signal for setting the value of the transmission ratio in dependence upon the position of the lever, characterised by means for preventing the signal applied by the control unit to the CVT from exceeding a limit value dependent upon at least one of the prevailing engine speed and the rate of change of the engine speed. 
         [0008]    Preferably, the lever for varying the transmission ratio serves additionally in setting the operating point of the engine. 
         [0009]    Conveniently, the lever is a foot operated pedal. If desired, the vehicle may additionally comprise a second, hand operated, lever, and means for setting the operating point of the engine in dependence upon the higher of two desired values determined from the positions of the foot pedal and the hand operated lever. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0010]    The invention will now be described further, by way of example, with reference to the accompanying drawings, in which: 
           [0011]      FIG. 1  is a simplified illustration of the power train of a utility tractor, 
           [0012]      FIG. 2  is a schematic diagram of a control system for setting the transmission ratio of the CVT shown in  FIG. 1 , and 
           [0013]      FIG. 3  is a graph showing the highest permissible value at which the transmission ratio of the CVT can be set at different engine speeds to avoid stalling of the engine and the vehicle. 
       
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
       [0014]    The power train shown in  FIG. 1  is conventional and is used in compact tractors. An engine  10  is coupled to the input shaft  11  of a continuously variable transmission  12  through a shift clutch  14 , which allows the engine to drive the tractor selectively in a forwards mode and in a reverse mode. 
         [0015]    The CVT  12  comprises two cone sheaves  16   a  and  16   b  connected to one another by a belt or chain  18 . Each of the cone sheaves is a pulley comprised of two conical sides that can be moved towards and away from one another so as to allow the effective diameter of the pulley to be varied continuously. A control unit sets the separation between sides of both cone sheaves to vary the transmission ratio of the CVT  12 . Instead of operating mechanically, as just described, the CVT may be of a type that operates electrically or hydrostatically. 
         [0016]    The cone sheaves  16   a  and  16   b  are connected respectively to drive the sun gear and planet carrier of planetary gear set  20 , the output of which drives the axles  24  that are connected to the drive wheels of the tractor through a differential mechanism  22 . Additionally, provision is made in the drive train for the engine  10  to drive a rear power take-off (PTO) shaft  26  and a mid PTO shaft  28 . 
         [0017]    As the power train of  FIG. 1  is conventional, it is believed that its operation will be clear to the person skilled in the art without the need for more detailed explanation. In operation, the engine runs at a constant speed, selected to provide maximum efficiency or power. 
         [0018]    Typically, the engine will operate at 2600 rpm and will drive the rear PTO at, for example, 540 rpm and the mid PTO at 1000 rpm. The tractor speed is varied by altering the effective diameters of the two cone shaves  16   a  and  16   b  of the CVT  12 . 
         [0019]    Referring now to the schematic diagram of  FIG. 2 , the tractor controls include both a hand lever  30  and a foot pedal  32 . The position of each of these two levers  30 ,  32  corresponds to a desired value of engine speed and the higher of the two values is selected by a unit  34  and used to set the speed of the engine  10 . The unit  34  may operate electrically but in the preferred embodiment of the invention it operates mechanically and is connected by wires or Bowden cables to levers  30  and  32 . 
         [0020]    The position of only the foot pedal  32  is used to indicate the desired wheel speed, that is to say the desired road speed of the vehicle. This signal is applied to a ratio computation unit  36  which transmits a signal to a CVT control unit  40  that sets the effective diameter of the cone sheaves of the CVT  12 . 
         [0021]    As so far described, the control system is generally conventional. In prior art systems, the transmission ratio of the CVT  12  was calculated by the ratio computation unit  36  in dependence solely on the position of the foot pedal  32 , without regard to the prevailing engine speed. As a result, if the torque demand placed on the engine exceeded its capability, the engine speed would drop. In such circumstances, the operator would by natural tendency depress the foot pedal further and thus increase the load on the engine, which then risked causing the engine to stall. 
         [0022]    In the present invention, to avoid this risk, the ratio computation unit  36  is further connected to receive over a line  38  an input signal from the engine indicative of its prevailing speed. Depending on the engine speed, an upper limit is placed by the ratio computation unit  36  on the transmission ratio that can be set using the foot pedal  32 . 
         [0023]    The graph of  FIG. 3  shows the highest CVT ratio that can be set at any time by the position of the foot pedal  32  plotted against the prevailing engine speed. The maximum and minimum values of the transmission ratio are determined by the range of effective diameters of the cone sheaves of the CVT. So long as the engine speed is above 1300 rpm, the foot pedal  32  alone will determine the transmission ratio of the CVT to produce the desired wheel speed. 
         [0024]    Within the range of 800 rpm to 1300 rpm, however, a limit is placed on transmission ratio to prevent stalling. Hence, at 800 rpm the engine, when the engine is near its idling speed, selecting a high transmission ratio would cause the engine to stall. At this engine speed therefore, only the minimum possible transmission ratio can be set by the control unit  36 . The upper limit increases gradually with engine speed and the full range of transmission ratios can be set once the engine speed has reached 1300 rpm. 
         [0025]    If the engine speed attempts to drop below 800, as depicted by the broken line in  FIG. 3 , the engine risks stalling because the transmission ratio cannot be reduced any further. At this time, the clutch  14  needs to be disengaged to prevent the engine from stalling. 
         [0026]    The graph in  FIG. 3  shows a linear relationship between the speed and the highest permissible transmission ratio in the range from 800 rpm to 1300 rpm. This need not necessarily be the case as the highest permissible transmission ratio at any given engine speed can be matched to the torque curve of the engine. 
         [0027]    In the above description, the highest permissible transmission ratio is determined only by the prevailing engine speed. It will be appreciated, however, that a risk of stalling can be detected by the rate of change of engine speed, that is to say the time derivative of the prevailing engine speed. If the engine speed drops, its rate of change is an indication that the torque demand being placed upon is excessive. This indication can be used either instead of, or more preferably in addition to, the prevailing engine speed value to reduce the transmission ratio by placing an upper limit that varies with the rate of change. Thus, if the engine speed drops rapidly from say 2600 rpm to 2200 rpm, even though both these value are in excess of 1300 rpm, an upper limit can be placed on the transmission ratio by the ratio computation unit  36  to ensure that the engine continues to operate at a speed near its optimum range. Using both the prevailing speed and the rate of change of the speed allows the control system to respond sooner to an excessive torque demand that could risk causing the engine to stall.