EP0446453A1 - Method and device for the electronic controlling and/or regulating of an automotive combustion engine - Google Patents

Abstract

A method and a device for the electronic control and / or regulation of an internal combustion engine of a motor vehicle is proposed, wherein the detection element connected to an element determining the performance of the internal combustion engine, in particular a throttle valve or a control rod or an accelerator pedal, generates at least two position signals which act in this way are designed so that when the position-determining element changes position, the at least two position signal variables change in opposite directions. An error detection associated with such a measure permits the detection of short-circuits or shunts between the potentiometer wipers with a double potentiometer as the detection element. <IMAGE>

Description

State of the art

The invention relates to a method and a device for electronic control and / or regulation of an internal combustion engine of a motor vehicle according to the preambles of the independent claims.

Such a method or such a device is known from DE-OS 36 21 937. There, a monitoring device for an electronic control device in a motor vehicle is proposed, a detection device for determining an operating parameter of the internal combustion engine and / or the motor vehicle, in particular the respective position of an element determining the performance of the internal combustion engine, such as throttle valve or control rod and / or accelerator pedal, being provided and by comparing the signal values emitted by the detection element with predefined limit values, fault states in the respective detection element are inferred.

Such a procedure cannot ensure a reliable check of the respective detection element, since possible types of errors such as shunts with parasitic ones Resistance between the signal line and the supply voltage cannot be detected and safety-critical driving conditions can nevertheless occur.

The invention is based on the object of providing measures in a method or a device for controlling and / or regulating an internal combustion engine, with the aid of which comprehensive safety monitoring is ensured. To achieve the object, it is provided that the detection element for one operating parameter of the internal combustion engine or the motor vehicle generates several signals representing the operating parameter, which signals are designed such that when the operating parameter determined by the detection element changes, the signal quantities change in opposite directions. By comparing signal quantities designed in this way, possibilities are opened up to detect malfunctions of the detection element on a large scale.

From DE-OS 35 10 173 an electronic accelerator pedal system of a motor vehicle is proposed, wherein a detection element assigned to the accelerator pedal generates at least one signal representing the position of the accelerator pedal and at least depending on its regulation of the throttle valve position and thus the air supply to the internal combustion engine. To check the functionality of the detection element, which consists of two potentiometers connected to the accelerator pedal, the position signal of the one is compared in a logic unit with a threshold value derived from the position signal of the second potentiometer, and in this way the correct function of the detection element, in particular of the first potentiometer, detected. Such a procedure cannot ensure a reliable check of the respective detection element, since possible types of error such as shunts between the two potentiometer wipers or non-linearities of the potentiometers cannot be detected.

From DE-OS 34 33 585 a position detection element for a movable part in a motor vehicle is known, which is designed in the form of a multi-path potentiometer and serves to improve the resolution of the position detection in predetermined areas of the position of the element connected to it.

Advantages of the invention

The procedure according to the invention has the advantage that both the nonlinearities of the detection element or characteristic curve deviations as well as shunts between the signal lines of the sensors can be detected due to the electrical countercurrent of the signals emitted by the respective detection element consisting of several sensors. Comprehensive security monitoring of the detection element can thus be ensured by the procedure according to the invention.

The procedure according to the invention offers particular advantages in connection with a detection element designed as a double potentiometer for determining the position of a performance-determining element, such as throttle valve, control rod and / or a control element that can be actuated by the driver, such as an accelerator pedal of an electronic accelerator pedal.

Further advantages result from the measure of providing different resistance values for the two resistance tracks of the double potentiometer. In the case of electrically opposing resistance tracks with the same resistance value, a value that corresponds to an average deflection occurs in the event of a fault in a shunt between the grinders. By selecting different resistance values, however, the resulting voltage value in the event of such a fault results in a value which corresponds to a smaller deflection.

Further advantages result from the subclaims in connection with the exemplary embodiment described below.

drawing

The invention is explained below with reference to the embodiment shown in the drawing. 1 shows an exemplary circuit arrangement for realizing the idea according to the invention, while FIG. 2 shows a flow chart to clarify the signal evaluation.

Description of an embodiment

FIG. 1 shows a detection element 10 for the position of an element of a motor vehicle, not shown, which determines the performance of the internal combustion engine, in particular a power actuator such as a throttle valve or control rod and / or an accelerator pedal of an electronic accelerator pedal system, which comprises two sensors or transmitters P1 and P2, which are shown in FIG. 1 as a so-called double potentiometer. The resistance track 12 is connected via its line 16 to the positive pole of the supply voltage, via line 18 to the negative pole of the supply voltage. The resistance path 14 of the sensor P1 is linked via line 20 to the positive, via line 22 to the negative pole of the supply voltage. Both resistance tracks 12, 14 are covered by movable grinders 24, 26 connected to the respective performance-determining element of the motor vehicle. The two grinders 24 and 26 are coupled to one another via a mechanical connection 28 such that both move parallel to one another in the same direction, depending on the power-determining element (not shown).

The wiper sweeping over the first resistance track 12 is guided to a connection point P1S via a line 30 and a resistor 32 with the resistance value RS1. while the wiper 26 crossing the second resistance path 14 is conducted via line 34 and resistor 36 with resistance value RS2 to connection point P2S. A resistor 38 with the resistance value R is connected to the connection point P1S, and a line 40 is connected on the one hand, which connects the connection point P1S to the computing unit 44. The resistor 38 is connected with its second connection to the negative pole of the supply voltage.

In an analogous manner, the resistor 46 with the resistance value R and the line 48, which connects the connection point P2S to a computing or evaluation unit 44, are connected to the connection point P2S. In contrast to the arrangement on the first sensor P1, in this case the other connection of the resistor 46 is connected to the positive pole of the supply voltage in accordance with the electrical counter-current of the two sensors.

The connecting line 40 connects the connection point P1S of the first sensor to an input 42 of the computing unit 44, while the line 48 connects the connecting point P2S of the second sensor to a second input 50 of the computing unit 44. The computing unit 44, in the illustration of which FIG. 1 does not include components which do not directly support the procedure according to the invention, comprises a first A / D converter 52 assigned to the input 42 and a second A / D converter assigned to the second input 50. Converter 54, a processing unit 55 and an output stage 56. The output stage 56 is assigned to the output 57 of the computing unit 44, to which line 58 is applied, which connects the computing unit 44 to devices 60 for influencing an operating parameter of an internal combustion engine.

In the preferred exemplary embodiment, the devices 60 are a power actuator provided with an electrically actuable servomotor, such as, for example, a throttle valve for controlling the air throughput to the internal combustion engine or a control rod for influencing the amount of fuel supplied to the internal combustion engine, or a device for controlling injection valves.

In addition to the inputs and outputs shown in FIG. 1, the computing unit 44 naturally has further inputs and outputs, not shown, which are used to carry out further control functions, such as ignition, fuel injection and / or idling control.

The functioning according to FIG. 1 results as follows: The performance-determining element of the motor vehicle or the internal combustion engine, which in the preferred exemplary embodiment is a throttle valve or control rod and / or an accelerator pedal of an electronic accelerator pedal system, is rigid with the two grinders 24 and 26 or signal lines 30 and 34 of the two sensors P1 and P2 are connected, so that a change in position of this element leads to a corresponding change in position of the two wipers 24 and 26. Through the connection 28, such a change in position of the two wipers takes place in the same direction, in the same direction. For example, a movement of the throttle valve in the direction of its fully open position means a change in the sliders 24 and 26 in FIG. 1 in the direction of the positive connection of the 1st or in the direction of the negative connection of the 2nd resistance track. The connection points P1S and P2S are then corresponding to the position of the wipers 24 and 26 at a potential value formed by the resistors RS1 and R or RS2 and R, which represent a measure of the respective positions of the wipers and thus of the position of the power-determining element . It is It should be noted that a change in the position of the power-determining element in the direction of a larger opening leads to an increase in the potential at the connection point P1S and to a lowering of the potential at the connection point P2S, and the two sensors accordingly behave in opposite electrical directions. Via the connecting lines 40 and 48, the two voltage values corresponding to the positions of the sensors P1 and P2 are fed to the inputs 42 and 50 of the computing unit 44. The A / D converters assigned to the inputs form digital signals from the analog voltage signals for further processing in processing unit 55. There, the voltage signals are converted into corresponding position values for the respective power-determining element of the motor vehicle or the internal combustion engine, and on the basis of these position values, which in the case of an electronic accelerator pedal system correspond to a target or an actual value, a corresponding control of the devices 60 is carried out via the output stage 56.

In order to improve the security of the system, it is provided in the processing unit 55 that the values read in via the inputs 42 and 50 and the A / D converters 52 and 54 are checked individually and with one another to determine whether the detection element 10 is functioning correctly. It is also provided that appropriate measures are taken in the event of a recognized inability to function.

The procedure for checking the function of the detection element 10 and the measures to be taken when the inability to function is detected are shown in FIG. 2 on the basis of a flow chart executed in the processing unit 55.

After the program part shown in FIG. 2 has started, a section for individual error detection of the two sensors P1 and P2 is run through in function block 100. This individual error detection is carried out separately for each sensor and starts accordingly Step 102 in that the position values determined by the respective sensor are read in and compared in query block 104 with their upper maximum limit. If it is recognized in step 104 that the position value of the respective sensor is greater than its maximum permissible value, an individual error of the respective sensor is recognized in block 106 and a corresponding mark is set and the program part continues. An individual fault identified after step 106 indicates a short circuit either from the negative to the positive pole of the supply voltage of the sensor or from the connection point P1S or P2S to the positive pole of the supply voltage or to an interruption of the connection at the negative pole of the supply voltage of the respective sensor. A corresponding mark can also be set in step 106.

If it has been determined in step 104 that the respective position value is below its upper limit, it is checked in step 108 whether the position value is less than a lower minimum threshold. In the opposite case, the individual fault detection is completed in step 110 by setting a mark for the functionality of the individual sensors. If, according to step 108, the position value of the respective sensor is below the predetermined minimum value, a second individual error is recognized in step 112 and a corresponding mark is set. This second individual fault can indicate short circuits from the positive pole of the supply voltage to the negative, from the connection point P1S or P2S to the negative pole of the supply voltage or to interruptions in the positive supply voltage lines or the wiper or connection lines.

The query 114 then continues, with which the existence of an individual error is determined. If such an individual fault is present, an emergency function is initiated in step 116. This limp home function can either be from a shutdown of the System or from a continuation of the function of the system based on the sensor that is considered to be functioning correctly. After step 116, the program part is ended and is carried out again.

If it has been determined in step 114 that there is no single fault, the operability of the entire detection element 10 is checked in step 118 by comparing the amount of a difference in the position values generated by the sensors with a predetermined threshold. If the difference is below the predetermined threshold, the operability of the detection element is determined in step 120 and the system function is taken up as normal operation. However, if the difference after step 118 is above the predetermined threshold, a flag is set for an error of the detection element in step 122 and an emergency operation function is initiated.

An error detected in step 122 indicates shunts between the supply voltage poles and the wiper connection points, a shunt, in contrast to the short circuit, having a finite contact resistance. The emergency operation measure taken in step 122 can consist in either stopping the system or continuing the system function on the basis of the respective smaller position value. After steps 120 and 122, the program part is ended and, if necessary, restarted.

Due to the electrical counter-rotation of the two sensors and the mentioned comparison of the amount of the difference between the position values, which represent the position of the power-determining element, shunts between the two wiper or connection lines, ie for example from the connection points P1S to P2S, can also be determined. Such an error detection is with electrically synchronous sensors not possible. Due to the different selection of the resistance values of the resistance paths of the double potentiometer and the resistors RS1 and RS2, in the event of a fault in a shunt between the two connection points P1S and P2S, there is the additional advantage which improves the functional reliability of the system: smaller is assumed and thus the throttle valve or control rod is kept on a smaller opening cross-section in an electronic accelerator pedal system.

The procedure according to the invention can also be applied to detection organs with a plurality of sensors, at least one of the sensors then having electrical opposition in relation to the others and the position signal of this or these sensors being used to check the function of the others.

A further advantageous embodiment of the detection element according to FIG. 1 results from the different selection of the resistance values of the resistors 38 and 46. This measure, also in connection with the dimensioning of the resistors 32 and 36 and / or the resistance tracks 12 and 14, leads to the above advantages shown regarding the choice of the resistances of the resistance tracks 12 and 14.

The procedure according to the invention is described above using the example of a position transmitter. In principle, it can be applied to other sensor or sensor arrangements that record the operating parameters of the internal combustion engine.

Claims (12)

Method for the electronic control and / or regulation of an internal combustion engine of a motor vehicle, wherein at least one detection element generates a signal representing at least one operating parameter of the internal combustion engine or the motor vehicle and a control and / or regulating system for controlling and / or regulating the internal combustion engine and / or the check the functionality of the at least one detection element is passed on, and the function check is carried out by evaluating the at least one signal variable,
characterized in that
the at least one detection element each generates at least two signal variables which are designed such that when the operating parameter changes, the at least two signal variables change in opposite directions. Method according to Claim 1, characterized in that the detection element generates signal quantities which represent the position of a power-determining element of the internal combustion engine or of the motor vehicle, such as a power actuator and / or accelerator pedal. Method according to Claim 2, characterized in that the detection element represents at least one double potentiometer, each with different resistance values assigned to the single potentiometer. Method according to one of the preceding claims, characterized in that the at least one arithmetic or evaluation unit separately and / or jointly supplied signals of the detection element are evaluated to check the functionality of the detection element. Method according to one of the preceding claims, characterized in that the evaluation takes place in the following steps: - Checking the signal sizes individually for a permissible value range for the detection of individual errors, Checking the difference between the signals with a predetermined limit value for detecting error states in the area of the detection element, - Take emergency measures in the event of a fault. Method according to one of the preceding claims, characterized in that the emergency operation measures take place a switching off of the control and / or regulating system, a continuation of the function of the control and / or regulating system depending on the signal which is not faulty or the smaller amount. Device for the electronic control and / or regulation of an internal combustion engine of a motor vehicle, with at least one detection element for an operating parameter of the internal combustion engine or the motor vehicle, the at least one detection element generating at least one signal representing the respective operating parameter, with a control and / or regulating system, to which the at least one signal for controlling and / or regulating the internal combustion engine is fed, and means which determine the functionality of the at least one detection element on the basis of this at least one signal, characterized in that the at least one detection element comprises at least two sensors or sensors, this detection device generates at least two signals, - And this detection element is designed such that when the operating parameter changes, at least two of the respective signals of the detection element change in opposite directions. Device according to claim 7, characterized in that the operating parameter corresponds to the position of a power-determining element of the internal combustion engine and / or the motor vehicle and the detection element is assigned to such an element as a position transmitter. Device according to claim 8, characterized in that the at least one detection element comprises at least two sensors designed as potentiometers with different resistance values, both sensors being assigned to the same power-determining element. Device according to one of the preceding claims, characterized in that there is at least one arithmetic or evaluation unit which evaluates the signals generated by the detection element for the function check. Device according to claims 8 or 9, characterized in that the detection element represents a double potentiometer, one of the individual potentiometers being selected in opposite directions by opposite polarity of the operating voltage compared to the other single potentiometer. Device according to one of the preceding claims, characterized in that the signals of the detection element which represent the operating parameters are separated and / or fed together to a computing or evaluation unit for further processing

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