WO2013020760A1

WO2013020760A1 - Method for influencing a gearshift strategy of a motor vehicle

Info

Publication number: WO2013020760A1
Application number: PCT/EP2012/063122
Authority: WO
Inventors: Johannes Kemler; Maik WÜRTHNER; Joachim Staudinger
Original assignee: Zf Friedrichshafen Ag
Priority date: 2011-08-10
Filing date: 2012-07-05
Publication date: 2013-02-14
Also published as: DE102011080712A1

Abstract

The invention relates to a method for influencing a gearshift strategy of a motor vehicle, e.g., a utility vehicle, wherein with the aid of driving status data and/or data desired by the driver the operation of the gear (3) is controlled, during which a switching reaction is determined for a predictive driving strategy based on topography data of a current position of the motor vehicle and/or topography data of a position at a specific distance ahead of the current position of the motor vehicle. In order to improve the switching strategy, road class related information and/or temporal traffic regulating information and/or route related information assumed to be probable is determined, if available. Such information or information relevant to the switching strategy derived from said information is considered for determining a switching reaction when the topography data is evaluated.

Description

Method for influencing a Getriebeschaltstrateqie a motor vehicle

The invention relates to a method for influencing a transmission shift strategy of a motor vehicle according to the preamble of patent claim 1.

The operation of an automatic or automated manual transmission of a motor vehicle is usually controlled and regulated by a transmission control device in which a switching strategy is implemented in the form of a computer program. The shift strategy determines a gear change from an actual gear to a desired gear with the aid of driving state data and driver request data. Driving state data may be, for example, vehicle mass, driving resistance, vehicle inclination, vehicle speed, vehicle acceleration, engine speed, and engine torque. Driver request data may be, for example, an accelerator pedal operation or accelerator pedal position and a brake pedal actuation or brake pedal position. As a driver's desired data are generally understood such data that reflect the desire of the driver with regard to the current operation of the vehicle.

In commercial vehicles, the tuning of the shift strategy is usually a compromise of the lowest possible fuel consumption and the greatest possible agility of the vehicle. Such a shift strategy must meet the special requirements of a commercial vehicle. In particular, even large inclines or declines, with or without charge, without active intervention of the driver must be able to cope. Under certain circumstances, circuits are also carried out that would not have been necessary with additional information about the route ahead.

So that the shift strategy can calculate circuits, certain driving state variables, such as gradient, driving resistance and vehicle mass, are calculated. The accuracy of the calculation can vary greatly depending on the required basic signals, such as speed and engine torque. If the transmission control signals from the environment of the vehicle are available, can these driving state variables are corrected or calculated more precisely. Also, a gear calculation that is better matched to the road ahead of the road is possible with such ambient signals. These signals can for example be supplied by a navigation system by means of a positioning system such as GPS in the form of topography data and further processed in the transmission control.

From WO 201 0/1 1 8 91 7 A1 a transmission control device is known, which continuously calculates the driving state data vehicle mass and / or driving resistance and / or vehicle inclination on the basis of topography data of a current position of the vehicle to change gear in a shift strategy at a To ensure the greatest possible agility of the vehicle and the lowest possible fuel consumption. As further driving state data or basic signals, the vehicle speed, the vehicle acceleration, the engine speed and the engine torque can be taken into account. A shift strategy of the transmission control device also determines from topography data, which lie at a defined distance before a current position of the vehicle, a gear change from an actual gear to a desired gear, depending on driving condition data, as well as driver input data, which via the operation of an accelerator pedal or a brake pedal be determined. For this purpose, the topography data are determined at a distance to the vehicle, which is determined as a function of the vehicle speed. The topography data of the current position and the preceding position are provided via a navigation device. From the topography data, a city traffic, a roundabout, a traffic light intersection, a cornering, destination information and off-road situations can be detected or derived and processed in the transmission control device.

From DE 1 0 2005 049 71 0 A1 a method for influencing an automated gearbox is known. In this case, the driving resistance is determined from existing or easily ascertainable driving state data, in particular from information about a drive torque in the drive train, a relevant speed and an acceleration of the vehicle. About the determined driving resistance pushes a transmission control, if necessary, switching points or selects switching programs to reduce fuel consumption, to improve the ability of the vehicle to climb and to increase ride comfort. Data connections to position-finding systems, navigation systems or the like off-vehicle equipment are not used.

From DE 10 2006 001 818 A1, a system for driver assistance in a commercial vehicle is known, in which a topography of a route ahead of the vehicle is evaluated computer-assisted in order to determine a gear change and to set specific Fahrbetnebskomponenten. The required topography of the predefined respective travel route is stored in an in-vehicle or external vehicle memory, for example a central database of a carrier, from which the topography data are retrieved by radio or by other suitable data transmission means when driving. During the driving operation, the current position of the vehicle may be determined with a GPS receiver and compared with the stored route data to verify whether the vehicle is actually on the travel route retrieved from the memory.

Against this background, the invention has for its object to provide a further improved switching strategy of a transmission control device.

The solution of this problem arises from the features of the main claim, while advantageous embodiments and further developments of the invention are the dependent claims can be removed.

The invention is based on the finding that through the combined processing of topographical data, such as altitude, inclination, slope information, and more information about traffic-pierced intersection detection and sign information, such as road class, traffic light phase information and probable route of the vehicle, a predictive flexible switching strategy available which makes more efficient use of the potentials. Let borrowed the fuel consumption, the acceleration capacity and the switching number reduction while driving a motor vehicle. It should be adjusted or suppressed accordingly when approaching certain driving situations or when driving through certain driving situations gear changes, and possibly also targeted temporary power flow interruptions of the drive train are made.

The invention is therefore based on a method for influencing a transmission shift strategy of a motor vehicle, for example a commercial vehicle, wherein the operation of the transmission is controlled with the aid of driving state data and / or driver command data, for which a forward-looking driving strategy is based on topographical data of a current position of the motor vehicle and / or based on topographical data of a position located at a certain distance before the current position of the motor vehicle, a switching reaction is determined.

Topographical data is understood to mean data relevant to the driving operation of a motor vehicle or information which describe geographical locations or which refer to geographical locations. A switching response may be a gear change from an actual gear to a desired gear or another, the torque transmission of a drive motor in the drive train of a motor vehicle influencing switching element actuation.

In order to achieve the stated object, the invention provides that road class-related information and / or temporally traffic-regulating information and / or route-related information assumed to be probable are detected, and that such acquired information or switching-strategy-relevant information derived therefrom contributes to the determination of a switching reaction an evaluation of the topography data are taken into account.

Accordingly, in a further developed gear shift strategy, signal calculations are performed by topographical data and their attributes, with additional road-characteristic, temporal and / or presumed information being evaluated, to avoid unnecessary switching or to optimize gear calculations of nominal gears. The respective calculated switching reaction or a signal calculation can be implemented by a transmission control device. Thereby, a forward-looking shift strategy is provided, which can bring about a reduction in fuel consumption and the number of transmission circuits, and at the same time ensures a high degree of agility of the vehicle and a high level of driving comfort.

According to one embodiment of the invention, it can be provided that when a road class, such as a highway or highway or country road, is detected, a switching reaction of the transmission, such as a change of switching points for upshifts and / or a change of switching points for downshifts, is determined. The change from a shift point is effected by setting a higher or a lower target speed in the shift strategy for a gear change. Accordingly, the currently used road class is detected and evaluated, and the transmission shift strategy or the transmission control device is influenced accordingly, wherein the influencing can also take place in the form of a data field switching in the transmission control device.

If it is detected, for example, that a motorway is being driven, the transmission shift strategy can be influenced in such a way that the transmission reacts in train operation with early upshifts or low target speeds of the gears as well as with correspondingly late downshifts. This is generally possible and useful on motorways due to the limited slopes and curve radii. This allows a particularly fuel-efficient, yet speedy driving can be achieved.

However, if it is recognized that a country road is being driven, then operation with a higher acceleration reserve can be planned. Accordingly, the transmission tends to respond with later upshifts or higher target speeds. This is more appropriate on rural roads, as the gradients on such roads are generally not limited to small values, and larger slopes are relatively common. fig occur. This ensures a comfortable driving on rural roads.

But if it is recognized that the vehicle is moving on a dirt road, for example, to remove wood on a forest road, away from the known road network or when used on a construction site, is to be expected with high gradients and / or high road resistance. Accordingly, the transmission will react with late upshifts or high target speeds in order to maintain a high acceleration reserve. This ensures safe driving in off-road use.

According to a further embodiment of the invention, it can be provided that, upon detection of a most probable route lying ahead, a switching reaction of the transmission adapted for this route is determined, such as activation or deactivation of a rolling function and / or a change of a switching point and / or a shift suppression. Accordingly, a route with a high probability of being selected by the driver is determined and evaluated. For example, the transmission may respond to a possible turn of this predicted route.

If the shortest and / or fastest way to reach the destination is, for example, via a motorway, the driver will probably turn off his current street at the appropriate motorway exit. For this purpose, it is evaluated how long and how far the vehicle can still drive on the currently traveled road or how long the vehicle can drive straight ahead, until the driveway on the highway will be reached. The distance or the predicted travel time to the turn-off point can be evaluated and trigger the following appropriate reaction:

- An available roll function (ie a drive-less forward drive) is no longer activated when the distance and / or the predicted travel time to the turn-off point falls below a predetermined limit.

If the distance and / or the predicted travel time to the turnaround falls below a predetermined threshold, upshifts are in train operation executed with a smaller gear jump, which can be realized for example by a suitable choice of a target gear, possibly by a restriction of a multiple circuit. Or they are executed at a higher target speed.

Upshifts in overrun are completely prevented before the turn-off or executed at best with higher target speed and / or a smaller gear jump.

If the change of road class is connected to the turn, then the switching criteria of the road class concerned can be applied after the turn.

According to a further embodiment of the invention, it can be provided that when detecting a traffic light crossing ahead and when recognizing a remaining duration of a current traffic light phase of this traffic light intersection, a shift phase-dependent and / or driving speed-dependent switching reaction of the transmission is determined. Accordingly, the type of an intersection ahead of the traveled route is evaluated. If a traffic light intersection is detected and the switching state and the remaining duration of the current traffic light phase is known, the transmission can respond depending on this time-varying information.

If the duration of a current green phase of the traffic light is known, then it can be calculated whether the current green phase is sufficient in time for the vehicle to be able to pass the intersection at the current driving speed. If this is the case then upshifts are performed at a lower target speed. If this is not the case, upshifts are suppressed as much as possible by setting a high target speed and a low gear step. Push downshifts are performed when the accelerator pedal is released at a higher target speed to utilize the drag losses of the engine for braking. If a preceding vehicle has been detected at a small distance, the target speed is further increased. If the duration of a current red phase is known, then the transmission can be switched to neutral in the vehicle's state, and a designated gear again be inserted shortly before the change to green.

According to a further embodiment of the invention can be provided that upon detection of a speed limit supportive measures to comply with this speed limit, such as suppression of roll function, suppression of thrust upshift, shift point change a thrust upshift, suppression of a pull upshift, and / or a switching point change a pull upshift determined and applied.

Accordingly, an existing currently valid speed limit and the distance is evaluated until the beginning of this limit. If the vehicle travels a predetermined amount faster than the speed limit set in front of the vehicle, overshooting below a predetermined threshold or when the vehicle has reached the speed limit range will suppress overrun or allow only a higher target speed , A train upshift is also suppressed or permitted only with increased target speed. Furthermore, a roll function is suppressed.

According to a further embodiment of the invention can be provided that upon detection of a lying on the traveled route roundabout dependent on a driver switching reaction of an engine torque transmitting starting element, such as opening or closing of the starting element, and / or a switching reaction of the transmission, such as switching a for passing through the roundabout adapted gear, is determined.

Thus, when approaching a recognized, usually authorized right-hand traffic, when the brake pedal is actuated, a gear is switched in which the roundabout can be expected to pass at a normal roundabout speed at a low engine speed. The gear and the speed of passage can be adjusted to the diameter of the roundabout as far as it will be adapted. A starting clutch is kept open during the braking phase, thus interrupting the drive train in the power flow. As soon as the driver activates the accelerator pedal in front of the roundabout, the starting clutch is closed in order to enable a spontaneous entry into the roundabout. Activation of this function may depend on falling below a distance limit to the roundabout. If the distance limit to the roundabout not fallen below, so downshifts can be performed, for example, in which the starting clutch is closed.

In addition, it can be provided that, if necessary, switching between a driving resistance determination from data available in the vehicle and a driving resistance determination from topographical data is performed.

The running resistance of the vehicle essentially results from a rolling resistance, a pitch resistance, an acceleration and deceleration resistance, and an air resistance. It is thus an important parameter as an input variable for a predictive switching strategy.

The driving resistance at a current position of the vehicle can usually be calculated directly from the data available in the vehicle by means of the transmission control. In certain operating states, however, this may not be possible or only in an imprecise manner, for example if the instantaneous braking forces of a service brake are not known or are not known with sufficient accuracy in a braking mode. However, it is basically possible to determine the driving resistance from topographical data both at a forward position and at a current vehicle position. Therefore, switching between determination of the running resistance at the current vehicle position from vehicle-related data or topography data in the transmission control apparatus may be made to ensure that the running resistance as an important variable for determining a switching reaction when performing the method can be provided at any time with sufficiently high accuracy. To clarify the invention, the description is accompanied by a drawing of an embodiment. In this, the single figure shows a schematically simplified block diagram of a drive train of a commercial vehicle, such as a truck.

The drive train shown in the figure has a drive unit 1, for example an internal combustion engine, which can be drive-connected via a starting element, for example a friction clutch 2, with an automatic or automated manual transmission 3. Via the gear 3, the drive torque or the rotational speed of the internal combustion engine 1 is converted and the converted torque is provided at an output 4 for driving the vehicle wheels 8.

The internal combustion engine 1 is controlled and regulated by a motor control device 5 in its operation. To control and regulate the functions of the transmission 3, a transmission control device 6 is provided, which communicates on the one hand with the transmission 3 and on the other hand with the motor control device 5 bidirectionally.

The transmission control device 6 is supplied with data from sensors 10 as well as from a navigation device 7. The navigation device 7 provides topographical data about the surroundings of a current position of the vehicle and about the environment at a defined distance from the current position of the vehicle, including road class related information, temporal traffic regulating information, and likely assumed route related information. The defined distance before the current position can be, for example, a distance that depends on the current vehicle speed, in particular a distance that decreases with the current vehicle speed.

The transmission control device 6 controls the operation of the transmission 3 by means of driving state data and driver's desired data. A shift strategy stored in the transmission control device 6 in the form of a computer program determines respective switching reactions, in particular a gear change from a current actual gear a nominal gear, or a temporary power flow interruption or a power flow reduction in the drive train.

The driving state data used may be the current driving resistance, the current vehicle inclination, the current vehicle mass, the current vehicle speed, the current vehicle acceleration, the current engine torque, the current engine speed, and other values. This data can be provided at least partially by the engine control device 5 as well as suitable sensor devices. For the calculation of the driving resistance, there is the possibility of switching between a determination via the transmission control device 6 from data present in the vehicle and a determination from topographical data. The driver's desired data can be signaled by the operation of an accelerator pedal or a brake pedal, sensed detected and the transmission control device 6 are fed directly or indirectly.

In a method for influencing a transmission shift strategy, road class-related information and / or temporally traffic-regulating information and / or presumed route-related information are taken into account in order to achieve the lowest possible fuel consumption with high agility of the vehicle and high driving comfort. Accordingly, in determining a gear change to be performed from an actual gear to a target gear on the basis of the driving state data and the driver's request data, this information is included and the gear change is modified as needed from a predetermined standard gear change.

To illustrate the method, an exemplary scenario of an assumed route of a lorry is described below.

The truck is loaded according to the data of the navigation device 7 on an unpaved road and begins its journey to a destination. For the unpaved farm road, a shift strategy is determined and used in which the transmission control device 6 is compared to a standard shift control system. Strategy reacts with later upshifts (higher target speeds) for gear changes, since a high rolling resistance and a high pitch resistance are possible on this economic way.

In a subsequent overland journey, a road is identified by the navigation device 7 as a road class. Correspondingly, later upshifts (higher target speeds) are determined in comparison to a standard shift strategy, since larger gradients can not be ruled out. A higher acceleration reserve is preferred.

In the case of the now performed journey, the navigation device 7 detects a speed limit that lies ahead and determines the distance to it. The vehicle is currently moving at a higher speed than the forward speed. When falling below a certain distance to the speed limit circuits are suppressed in train operation or overrun operation or permitted only with a higher target speed. A control technology basically available rolling function for a driveless forward drive is also suppressed, so not allowed for activation.

For the further, with high probability by the driver selected route is taken from the navigation device 7 a highway connection. A possible turning of the track with a turning angle below a predetermined limit is assumed for the driveway on the highway. Previously, it is calculated how long and how far the vehicle can still drive substantially straight ahead, should the driven route actually turn. The distance and the predicted travel time to the turnstile at the current speed are evaluated and an adjusted shift response or shift strategy is established, which allows a fuel-efficient yet fluid ride without abrupt maneuvers and inefficient gear shifts to the turn-off point. This envisages that the activation of the roll function is suppressed when falling below a certain distance or predicted travel time to the turnstile. Upshifts in train operation should also be carried out with a smaller shiftable gearshift or with a higher target turnaround. number to be executed. Train upshifts are thus triggered later. Upshifts in overrun are preferably not triggered or performed with a higher target speed and / or a smaller shiftable gear jump.

After turning onto the highway, the navigation device 7 detects the new road class. Here, especially a fuel-efficient operation of the truck is desired. For this purpose, early upshifts and low target speeds as well as late downshifts are specified in the shift strategy in train operation.

After leaving the highway, the truck enters a city traffic. The navigation device 7 detects an approach to a roundabout. When falling below a predetermined distance to the roundabout, a gear is engaged in an operation of the brake pedal, in which the roundabout can be sensibly traversed, for example, with a travel speed of 15 km / h at a target speed for the engine of 1000 1 / min. During the braking phase before the roundabout, the starting clutch 2, controlled by the transmission control device, is opened by an associated clutch actuator 9 and kept open. As soon as the driver actuates the accelerator pedal, the starting clutch 2 is closed. This allows spontaneous entry into the roundabout.

After passing through the roundabout is detected by the navigation device 7, a traffic light crossing ahead. Furthermore, the current traffic light phase and also the remaining time of this traffic light phase are detected.

In a current green phase, it is calculated whether the vehicle can pass the intersection at the current vehicle speed within this green phase. If this is the case, upshifts with a lower target speed are preferred. Otherwise, upshifts are suppressed by higher target speeds and smaller switchable gear jumps as possible. If the driver takes his foot off the accelerator pedal, overruns with higher target speeds, ie earlier downshift set points to use the drag losses of the internal combustion engine to the braking effect. If a vehicle ahead is detected with a small distance, the target speeds for push-downshifts increase again.

In the current red phase of the traffic light, the gearbox is switched to neutral when the vehicle is stationary, and a planned starting gear is engaged immediately before the end of the red phase. If it is calculated at a current red phase that the vehicle reaches the traffic light safely at green at the current driving speed, the current shift strategy can be maintained.

After passing the traffic light intersection, the vehicle reaches an entrance to its destination.

LIST OF REFERENCES

Drive unit, internal combustion engine starting element, starting clutch

vehicle transmissions

output

Motor controller

Transmission control device

navigation device

vehicle wheels

clutch

sensors

Claims

claims

1 . A method for influencing a transmission shift strategy of a motor vehicle, for example a commercial vehicle, wherein the operation of the transmission (3) is controlled by means of driving state data and / or driver request data, in which for a predictive driving strategy based on Topographiedaten a current position of the motor vehicle and / or Topographical data of a position located a certain distance away from the current position of the motor vehicle, a switching reaction is determined, characterized in that road class information and / or temporal road traffic regulating information and / or likely assumed route related information is detected, and that such information or information derived switching strategy relevant information for the determination of a switching reaction in an evaluation of the topography data are taken into account.

2. The method according to claim 1, characterized in that when recognizing a road class, such as highway, highway, highway, Wirtschaftsweg, a switching reaction of the transmission (3), such as a change of switching points for upshifts and / or a change of switching points for downshifts, is determined.

3. The method according to claim 1 or 2, characterized in that upon detection of a leading most likely driving route adapted to this route switching reaction of the transmission (3), such as an activation or deactivation of a rolling function and / or a change of a switching point and / or a Switching suppression, is determined.

4. The method according to any one of claims 1 to 3, characterized in that when detecting a traffic light crossing ahead and when detecting a residual duration of a current traffic light phase of this traffic light crossing a traffic signal phase dependent and / or driving speed-dependent switching reaction of the transmission (3) is determined.

5. The method according to any one of claims 1 to 4, characterized in that upon detection of a speed limit supportive measures to comply with this speed limit, such as suppression of roll function, suppression of thrust upshift, shift point change a thrust upshift, suppression of a pull upshift and / or Switching point change of a pull-up, be determined.

6. The method according to any one of claims 1 to 5, characterized in that upon detection of a leading roundabout dependent on a driver's desired switching reaction of an engine torque transmitting starting element (2), such as opening or closing the starting element (2) and / or a switching reaction of Getriebes (3), such as switching a gear adapted for passing through the roundabout gear is determined.

7. The method according to any one of claims 1 to 6, characterized in that, if necessary, is switched between a driving resistance determination from existing data in the vehicle and a driving resistance determination of topography data.