Method for controlling the output power of an internal combustion engine

Abstract

In a method for setting the output power of an internal combustion engine a resultant specified torque is determined from a driver-intended torque and at least tw o additional intended torques, and the resultant specified torque is set via a apparatus for adjusting torque. Each participant system, in addition to the intended torque, provides information regarding whether the intended constitutes a torque-increase or a torque-decrease. A processing block is provided for each participant system in which the particular intended torque is compared with the driver-intended torque and the resulting specified torque of the preceding participant system. From this, a resulting specified torque is determined. The priority of the particular torque requirement results from the sequence of the participant systems during processing.

Description

BACKGROUND AND SUMMARY OF THE INVENTION

This application claims the priority of 198 03 387.7, filed Jan. 29, 1998, the disclosure of which is expressly incorporated by reference herein.

The invention relates to a method for controlling the output power of an internal combustion engine in a motor vehicle.

A type of motor control (applicant's so-called ME 1.0) is disclosed in MTZ Motortechnische Zeitschrift 56 (1995) 11, pages 666 ff. In this article, the specifications of many vehicle systems of the internal combustion engine are carried on a so-called CAN bus to the motor controll system, where the resultant torque requirement is determined. Via a second segment of the motor control system (the torque adjustment segment, for example), various operating parameters of the internal combustion engine are then set or adjusted so as to establish the resultant required torque.

It is an object of the present invention to provide an improved method for establishing the output power of an internal combustion engine such that changes in existing processes or the adoption of new functionalities can be easily performed.

This and other objects and advantages are achieved by the method according to the invention by obtaining a driver-intended torque from a driver's command, with additional intended torques also being generated by at least two vehicle systems of a motor control system which affects the output torque. A resultant specified torque is determined from the driver-intended torque and the at least two additional intended torques, and the resultant specified torque is set via a torque setting apparatus.

A system utilizing the method according to the invention possesses an advantage over conventional torque interfaces because all functions are based on a common physical factor, preferably the crankshaft torque. Previous systems resorted to obtaining torque requirements directly from the various actuators in the vehicle. On the other hand, in the method according to the invention the torque requirements generated by all vehicle systems are first coordinated, and only then are they established via a common motor control/regulation system. As a result, changes in the existing vehicle systems, as well as the addition of new systems, are considerably simplified. Independence from the type of motor controls and internal combustion engines involved also proves advantageous.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a flow chart of a torque interface; and

FIG. 2 illustrates the manner in which the process of the invention for torque coordination operates.

DETAILED DESCRIPTION OF THE DRAWINGS

FIG. 1 shows an overview of the controls and functions which cooperate with the drive train of a motor vehicle. The driver signals his intent, in the form of a driver-intended torque M.sub.-- ACC, to the control device (generally indicated at 2), via the accelerator pedal ACC and a corresponding evaluation logic 1. Additional desired torques M.sub.-- i are communicated by various vehicles systems 3-6 through a standard interface, the so-called CAN bus 7, to the motor control timer 2. The vehicle systems are, for example, a proximity-controlled cruise control 3, dynamic drive control systems 4 or transmission controls 5. Furthermore, the motor control device 2 also permits an exchange of information with additional vehicle systems 6, via the CAN bus 7. However, use of the CAN bus 7 as an interface is not required. For example, the transmission control 5 can also be integrated into the motor control device 2. The exchanged torque inputs M.sub.-- i are based on a physical value, preferably the crankshaft torque.

The motor control device 2 is divided into two function blocks, torque coordination 2a and motor control/regulation 2b. At a minimum, the torque coordinator 2a must necessarily be included in the control device 2. The torque coordinator 2a processes and prioritizes the driver-intended torque M.sub.-- ACC, the external specified torques M.sub.-- i, and the requirements M.sub.-- Temp of an internal cruise control 8 which is functionally associated with the torque coordinator 2a. However, it is possible to locate the cruise control 8 in a separate apparatus.

The required torque M.sub.-- reg resulting from the torque coordination 2a, is input to the motor control/regulation 2b, which in turn reports the actual torque M.sub.-- act and its status back to the torque coordinator 2a. The motor control/regulation device 2b converts the required torque M.sub.-- reg to actuating signals for controlling actuators 10, making an allowance for the state of operation of the motor which is reported from sensors 9. In a diesel motor, the control signals include, for example, the position of the throttle valve, the amount of fuel injected and the ignition angle.

The principle of operation of the torque coordinator 2a is shown in FIG. 2. The current driver-intended torque M.sub.-- ACC is determined by the accelerator pedal position and the current motor speed in an evaluation logic 1, and this information is transferred to the torque coordinator 2a. In addition, the evaluating logic 1 provides information regarding the dynamics with which the torque setting is to occur, in the form of two so-called dynamic bits (MDYNO.sub.-- ACC and MDYN1.sub.-- ACC). Accordingly, a desired torque M.sub.-- i and two dynamic bits MDYN0.sub.-- i and MDYN1.sub.-- i are prepared and transferred to the torque coordinator 2a. Furthermore, the participant systems 3-6 and 8 also provide information concerning whether the desired torque M-i is a torque-increasing or torque decreasing torque, and send it to the torque coordinator 2a in the form of two additional bits (MMIN.sub.-- i and MMAX.sub.-- i).

In the torque coordinator 2a there are separate coordination blocks 20-23 for each participant system. In general, the prioritization of the input torques M.sub.-- i and of the dynamic bits MDYNO.sub.-- i and MDYN1.sub.-- i is performed by the sequence of the signal processing, with driver-intended torque M.sub.-- ACC having the lowest priority, and the transmission demand M.sub. EGS having the highest priority, as shown in FIG. 2. The resultant dynamic bits are obtained (with the aid of bits MMIN.sub.-- i and MMAX.sub.-- i) from the driver-intended torque M.sub.-- ACC and the resultant specified torque of the preceeding vehicle system, and from the dynamic bits MDYN0.sub.-- ACC and MDYN1.sub.-- ACC and the resultant dynamic bits MDYN0.sub.-- i and MDYN1.sub.-- i of the preceeding vehicle system. The precise operation of the coordination blocks 20-23 will be explained further below.

The function of the dynamic bits MDYN0.sub.-- i and MDYN1.sub.-- i will now be described using an Otto-cycle motor as an example. In Otto-cycle motors, demanded is torque achieved in different ways, preferably via the air route and through action on the ignition. A fuel shut-off would also be theoretically possible. The particular desired kind of torque adjustment is defined through the two dynamic bits MDYN0.sub.-- i and MDYN1.sub.-- i:

______________________________________Torque setting MDYN1.sub.-- i MDYN0.sub.-- i______________________________________Optimum efficiency torque setting 0 0via the air pathQuickest possible torque setting 0 1via ignition angle and air pathTorque set value for the air path 1 0is frozen, torque reduction isperformed by adjusting ignitionangleInvalid combination 1 1______________________________________

If, for example, the driver-intended torque is to be performed by an optimum-efficiency torque setting, the following dynamic bits are transferred by the evaluation logic 1 to the coordination block 20:

______________________________________MDYN0 ACC : = 0 MDYN1 ACC: = 0______________________________________

During normal operation of the proximity-controlled cruise control and the internal valve timer 8, an optimum efficiency torque setting is made:

______________________________________MDYN0.sub.-- ART: = 0 MDYN1.sub.-- ART: = 0MDYN0.sub.-- TEMP: = 0 MDYN1.sub.-- TEMP : = 0______________________________________

In certain conditions of operation, however, it is possible for the proximity-controlled cruise control to change over to the quickest possible setting of the torque:

______________________________________MDYN0.sub.-- ART : = 1 MDYN1.sub.-- ART : = 0______________________________________

In the case of the driving dynamic control systems 4, in normal operation the quickest possible setting of the torque is preestablished:

______________________________________MDYN0.sub.-- ESP : = 1 MDYN1.sub.-- ESP : = 0______________________________________

In certain conditions of operation, however, it is possible to change over to a torque setting provided that

______________________________________MDYN0.sub.-- ESP : = 0 MDYN1.sub.-- ESP : = 1______________________________________

In the case of shifting actions, the transmission controls 5 need the quickest possible torque setting:

______________________________________MDYN0.sub.-- EGS : = 1 MDYN1.sub.-- EGS : = 0______________________________________

Under certain conditions of operation (for example, in the ase of torque limiting in starting procedures) ann optimum efficiency torque setting is given:

______________________________________MDYN0.sub.-- EGS : = 0 MDYN1.sub.-- EGS : = 0______________________________________

Naturally, the presets referred to are only examples of an embodiment. Other presets can be made, or in some cases other torque setting options for the dynamic bits MDYN0.sub.-- i and MDYN1.sub.-- i are defined. Moreover, the invention is not limited to the series of vehicle systems 3-6 and 8 shown in the embodiment. The precise function of the coordination blocks 20-23 with its input and output signals is generally shown in valid form in the following table:

______________________________________Resulting Values Allocation Condition______________________________________M.sub.-- OUT M.sub.-- IN1 NMIN-IN2 = 1 andMDYN0.sub.-- OUT : = MDYN0.sub.-- IN1 MMAX.sub.-- IN2 = 0MDYN1.sub.-- OUT MDYN1.sub.-- IN1 M.sub.-- IN1 MMIN.sub.-- IN2 = 1 and : = MDYN0.sub.-- IN1 MMAX.sub.-- IN2 = 0 and MDYN1.sub.-- IN1 M.sub.-- IN2 > M.sub.-- IN1 M.sub.-- IN2 MMIN.sub.-- IN2 = 0 and : = MDYN0.sub.-- IN2 MMXA.sub.-- IN2 = 0 and MDYN1.sub.-- IN2 M.sub.-- IN2 .ltoreq. M.sub.-- IN1 M.sub.-- IN1 MMIN.sub.-- IN2 = 0 and : = MDYN0.sub.-- IN1 MMAX.sub.-- IN2 = 1 and MDYN1.sub.-- IN1 M-IN2 < M.sub.-- IN1 M.sub.-- IN2 MMIN.sub.-- IN2 = 0 and : = MDYN0.sub.-- IN2 MMAX.sub.-- IN2 = 1 and MDYN1.sub.-- IN2 M.sub.-- IN2 .gtoreq. M.sub.-- IN1 M.sub.-- IN2 MMIN.sub.-- IN2 = 1 and : = MDYN0.sub.-- IN2 MMAX.sub.-- IN2 = 1 and MDYN1.sub.-- IN2______________________________________

In each coordination block the signals of the evaluation logic 1 and the output signals, (symbol OUT) of the preceeding coordination block 20-22 are present at the input 1 (symbol IN1), while the signals of the function to be coordinated i.e., participant systems 3-6 and 8 (are) present at the input 2 (symbol IN2). The output in each case is the resulting specified torque M.sub.-- OUT and the resultant dynamic bits MDYN0.sub.-- OUT and MDYN1.sub.-- OUT. The output values of the last coordination block 23 are then transferred to the motor control/regulator 2b as the resultant specified torque M.sub.-- nom, and the resultant dynamic bits MDYN0.sub.-- nom and MDYN1.sub.-- nom.

The function of the torque coordination 2a is explained again below, based on the example of the coordination block 23. At the input 1 are the resultant values of the preceeding coordination block 22, (i.e., M.sub.-- ESPV, MDYN0.sub.-- ESPV and MDYN1.sub.-- ESPV. At input 2 are the values of the transmission control 5 (i.e., M.sub.-- EGS, MMIN.sub.-- EGS, MMAX.sub.-- EGS and MDYNO.sub.-- EGS and MDYN1.sub.-- EGS). The signals of the two inputs are used to determine a resultant specified torque M.sub.-- reg and resultant dynamic bits MDYN0.sub.-- reg and MDYN1.sub.-- reg, and transfer them to the motor control/regulator 2b.

If an assumumption is made that the transmission control 5, under the actual conditions of operation, requires a reduction of the output torque to a given specified torque M.sub.-- EGS, then the following values would be transferred by the transmission control 5 to the coordination block 23:

M.sub.-- IN2:=M.sub.-- EGS MMIN.sub.-- EGS:=1 MMAX.sub.-- EGS:=0 MDYN0.sub.-- IN2:=MDYN0.sub.-- EGS MDYN1.sub.-- N2:=MDYN1.sub.-- EGS Furthermore, the following values are made available at input 1 by the preceding coordination block 22: M.sub.-- IN1:=M.sub.-- ESPV MNDYN0.sub.-- IN1:=MDYN0.sub.-- ESPV MDYN1.sub.-- IN1:=MDYN1.sub.-- ESPV

Under these circumstances, there are two possibilities for determining the output values. In the first case, the specified torque M.sub.-- EGS is greater than the resultant specified torque M.sub.-- ESPV resulting from the coordination block 22, i.e., M.sub.-- IN2>M.sub.-- IN1. As a result, the conditions which are listed in the second line of the above table are satisfied. For this reason the values of Input 1 are forwarded as output values:

M.sub.-- reg:=M.sub.-- OUT:=M.sub.-- IN1:=M.sub.-- ESPV MDYN0.sub.-- reg:=MNDYN0.sub.-- OUT:=MNDYN0.sub.-- IN1:=MDYN0.sub.-- ESPV MDYN1.sub.-- reg:=MDYN1.sub.-- OUT:=MDYN1.sub.-- IN1:=MDYN1.sub.-- ESPV

In the second case, the specified torque M.sub.-- EGS is less than the resultant specified torque M.sub.-- ESPV from the coordination block 22, i.e., M.sub.-- IN2.ltoreq.M.sub.-- IN1. As a result, the conditions which are listed in the third line of the above table are satisfied. For this reason, the values from input 2 are forwarded as output values:

M.sub.-- reg:=M.sub.-- OUT:=M.sub.-- IN2:=M.sub.-- EGS MDYN0.sub.-- reg:=MDYN0.sub.-- OUT:=MDYN0.sub.-- IN2:=MDYN0.sub.-- EGS MDYN1.sub.-- reg:=MDYN1.sub.-- OUT:=MDYN1.sub.-- IN2:=MDYN1.sub.-- EGS

Accordingly, the output values for all conditions of operation and for all coordination blocks 20-23 are derived from the above table. In the example shown, the prioritization of the individual vehicle systems is apparent from the order of processing. When the transmission control 5 calls for a torque reduction, the resultant specified torque M.sub.-- reg becomes either the specified torque M.sub.-- EGS of the transmission control 5 itself, or else a resultant specified torque M.sub.-- ESPV is generated as the output value. This occurs, however, only if the resultant specified torque M.sub.-- ESPV is still less than the specified torque M.sub.-- EGS.

The system utilizing the method according to the invention possesses an advantage over conventional torque interfaces because all functions are based on a common physical factor, preferably the crankshaft torque. Previous systems resorted to obtaining torque requirements directly from the various actuators in the engine of the vehicle. On the other hand, in the method according to the invention all the torque specifications are first coordinated, and only then are they set via a common valve timer/regulator. As a result, both changes in the existing systems, as well as the adoption of new systems are considerably simplified.

The foregoing disclosure has been set forth merely to illustrate the invention and is not intended to be limiting. Since modifications of the disclosed embodiments incorporating the spirit and substance of the invention may occur to persons skilled in the art, the invention should be construed to include everything within the scope of the appended claims and equivalents thereof.

Claims

1. A method for setting an output power of an internal combustion engine in a motor vehicle, comprising the steps of:

obtaining a driver-intended torque from a driver's command;

providing respective vehicle system intended torque values from at least two vehicle systems which affect output torque of the internal combustion engine;

determining a resultant specified torque from the driver-intended torque and at least two vehicle system intended torques; and

setting the resultant specified torque via a torque setting apparatus; wherein

each vehicle system generates, in addition to a vehicle system intended torque value, a report regarding whether said vehicle system intended torque value constitutes a torque increase or a torque decrease;

each vehicle system is associated with a coordination block which receives one of a resultant specified torque from a preceding coordination block and the driver-intended torque as a first input, and a vehicle system intended torque from an associated vehicle system as a second input;

in each coordination block a particular vehicle system intended torque value is compared with one of a resultant specified torque from a preceding coordination block and the driver-intended torque, and depending on whether a torque increase or torque decrease is determined, a higher or lower of the first and second input torque is advanced to a next succeeding participant system or to a torque setting apparatus as the resultant specified torque;

the participant system having a lowest priority is output as a first participant system and

the participant system having a highest priority is output as a last participant system.

2. The method according to claim 1, wherein participant systems comprise and are prioritized in the following order:

proximity-controlled cruise control, valve timer, running dynamic control and transmission control, respectively.

3. The method according to claim 1, further comprising the steps of:

preparing via each participant system additional data which represents dynamic information for setting the intended torque; and

setting the intended torque based on the additional data by controlling at least one of an air path, ignition angle and fuel shut-off.

4. The method according to claim 3, wherein the dynamic information is prepared via two dynamic bits, in each coordination block new resultant dynamic bits are determined from dynamic bits of a current participant system and resultant dynamic bits of a previous coordination block.

5. The method according to claim 4, wherein whenever a torque increase or torque decrease is reported in a particular participant system, if a resultant participant system intended torque of a previous participant system is greater than a participant system intended torque of the current participant system or the dynamic bits of the current participant system, or if the resultant participant system intended torque of the previous participant system is lower than the participant system intended torque of the current participant system, the new resultant dynamic bits of the previous participant system are forwarded as new dynamic bits to the next participant system) and the torque apparatus setting, respectively.