FR2910932A1 - Electrical element e.g. electric immersion heater, controlling method for e.g. internal combustion engine, involves calculating difference between voltage measurements at terminals of battery to detect change in operating state of element - Google Patents

Abstract

The method involves calculating a difference between voltage measurements at terminals of a battery powering an electrical element e.g. e.g. electric immersion heater, for detecting any change in an operating state of the electrical element. Activation of the electrical element at an instant is controlled, and a counter defining a measuring time (Tmes) is triggered. The voltage at the terminals of the battery measured at the instant from the activation of the electrical element is filtered and stored. An independent claim is also included for a system for controlling an electrical element of an engine, comprising a measuring unit.

Description

The present invention relates to the field of motor control, that is to say

  management of an internal combustion engine by means of all the sensors and actuators that equip it.

  More particularly, the invention relates to a method of controlling these electrical elements to determine their operating state and a system implementing this method. As illustrated in FIG. 5, all of the control laws and the engine characterization parameters are contained in an electronic control unit or computer 800. The computer outputs are connected to standard solenoid or static 810 intermediate relays. electronic type of power that come to control the electrical elements 830 associated with the engine. These relays being connected to the power circuit 820 or alternator, they supply the electrical elements 830 with current. For the safety of the passengers of the vehicle and the proper functioning of the latter, the engine control uses 801 diagnostic modules driven by the computer 800 and intended to monitor the operating parameters of the vehicle and detect failures. Conventionally, the existing diagnostic modules 801 control the outputs of the computer 800 controlling the intermediate relays 810. One can thus cite the electrical diagnostic modules that control the continuity and isolation of the electrical connections of the outputs of the computer by searching for a circuit open or a short circuit to the ground or those who control the power of the latter. However, insofar as the power part (power circuit 820 and electrical elements 830) is not visible by the computer 800, these diagnostic modules 801 do not detect the failures that may appear between the relays 810 of the power circuit 820. and the electrical elements 830.

  The control to know if a connection between a relay 810 of the power circuit 820 and an electrical element 830 is functional or not is not realized. Accordingly, an object of the present invention is to improve the detection of a failure of an electrical element by the motor control. More specifically, a first object of the present invention is to provide a control method for detecting the operating state of a relay link / electrical element.

  Another object of the present invention is to provide a method of controlling the electrical elements of an engine to control the operating state of the latter. Another object of the present invention is to provide an alternative solution to existing conventional electrical diagnoses.

  For this purpose, the invention provides a method of controlling at least one electric element of an engine, characterized in that it comprises, during its implementation, at least one calculation step of a difference in voltage measurements across a battery supplying said electrical element so as to detect a change in the operating state of said electrical element. This method further comprises a step of controlling the activation of the electric element at an instant to, followed by a step of triggering a counter defining a measurement time. It also comprises a step of filtering and memorizing a voltage across the battery measured at the instant of the activation of the electric element. Preferably, the calculation of the difference in voltage measurements at the terminals of a battery is expressed as the difference between the measurement of the voltage at the terminals of the filtered battery and stored at time to and a voltage measurement at the terminals. the battery at a time t less than or equal to the measurement time.

  Furthermore, it comprises a comparison step between the difference in voltage measurements across the calculated battery and a predetermined voltage threshold, the result of the comparison indicating a faulty electrical element or not. Advantageously, according to the result of the comparison between the calculation of the difference in voltage measurements at the battery terminals and the predetermined voltage threshold, a step is taken to identify the faulty electrical element.

  Preferably, the electric element is an immersion heater. In addition, the process is performed while the engine is running or not. The invention also relates to a system for controlling at least one electric element of an engine comprising at least measuring means and calculation means, characterized in that the calculation means are able to calculate a difference in voltage measurements. at the terminals of a battery supplying said electric element so as to detect a change in the operating state of said electric element.

  The invention will be better understood and other advantages will appear on reading the description which follows, given by way of nonlimiting example and with the appended drawings among which: FIG. 1 schematically shows a succession of steps of FIG. a method of controlling electrical elements of an engine according to the invention; FIGS. 2a, 2b and 2c show, in parallel, graphs illustrating, respectively, an activation / deactivation profile of electrical elements as a function of time, voltage measurements at the terminals of a battery as a function of time and a difference voltage at the terminals of a battery as a function of time in engine idle speed; FIGS. 3a, 3b, 3c show in parallel graphs illustrating, respectively, an activation / deactivation profile of electrical elements as a function of time, voltage measurements at the terminals of a battery as a function of time and a difference voltage across a battery as a function of time in a non-idling engine speed; FIG. 4 schematically shows a succession of steps of a filtering method; - Figure 5 shows a general block diagram of motor control.

  A method according to the invention is implemented to detect the operating state of electrical elements associated with an internal combustion engine. These electrical elements are typically actuators and sensors used, for example, for the control of engine control parameters. Non-limiting examples of electrical elements whose state of the immersion heaters, glow plugs or any other type of electrical elements consuming a sufficiently large current can thus be cited as non-limiting examples. This current must preferably be of the resistive or capacitive type. The method according to the invention is based on the principle of determining a voltage variation across a battery supplying the electrical elements following an activation control of the latter to deduce their ability to operate. Thus, during the analysis of a possible failure of an electrical element, the control method according to the invention comprises at least one step of calculating a difference in voltage measurements at the terminals of the battery so as to detect a change in the operating state of said electric element. An embodiment of the method for controlling electrical elements of an engine according to the invention will now be described with reference to FIG.

  It should be noted that this method can be performed when the vehicle engine is running or not. In a first step 100, the activation of an electric element of a motor is controlled.

  Each of the electrical elements is controlled individually. As shown in Figures 2a and 3a, one can then activate and deactivate a set of electrical elements, for example three, one after the other over time. During this step 100, to monitor that the electrical element is activated, a falling edge test is performed. The number of Nact activated electric elements is thus inputted and this value is compared with a value defined by the number of activated electric elements having undergone a time delay 1 / z.

  When the result of the comparison test 110 is true, that is to say that the number of activated electric elements has increased, it is confirmed to have detected the activation of the electric element controlled. Preferably, this activation is instantaneous with a sufficient inrush current without the electric element being ramped on the current it consumes to reach its nominal consumption as soon as possible. The detection of the activation of the electrical element Vact ,, triggers firstly a counter 210 for counting a predetermined time Tmes measurement it received input (step 200). This measurement time Tmes corresponds to the time during which voltage measurements at the terminals of the battery will be made to determine voltage variations at the terminals of this battery following the activation of an electrical element.

  The detection of the activation of the electrical element Vact; v triggers, on the other hand, this determination of the voltage variations at the terminals of the battery during the measurement time Tmes (step 300).

  In FIGS. 2b and 3b, one can observe the influence of the activation on the voltage at the terminals of the battery during the activation and the deactivation of three electric elements over time. Note that the activation of the electrical elements momentarily drops the voltage across the battery. In the case of a sufficient regime different from an idle regime, the voltage drops are smaller in amplitude and shorter than in idle mode. Indeed, because of the lack of ramp on the increase in current that can provide the alternator of the engine, it is able to quickly provide the requested current. During step 300, as long as the number of activated electrical elements has not been varied, a voltage measurement is acquired at the terminals of the battery Mestension. Otherwise, it can be measured at the computer connected to the engine. This measured value Mestension is a filtered value, typically by a first-order filter 310. There are two filtering modes depending on the behavior of the filtered voltage that is chosen thanks to a switch 320 driven by a comparison test 321 between two successive voltage measurements. If the voltage decreases, the response time of the filter will be relatively large so as to filter the action of other consumers on the voltage measurements at the terminals of the battery. In the case where the voltage increases, it is desired that it quickly reach its reference level, so a lower filtering coefficient will be applied (to inhibit the filter). At a time t = to defined as the moment of activation of an electric element, a switch 330 controlled by the detection of activation Vactiv returns the value of the voltage across the filtered battery to be stored instead the value of the resulting filtered voltage having a time delay of 1 / z.

  Thus, the filtered voltage value across the battery at t = to be recorded as the reference voltage. A voltage difference is then determined at the terminals of the battery. Difftension • It is expressed more precisely by the calculation 330 of the differences between the reference voltage value and the measured voltage values at the instantaneous battery terminals over the time of the battery. measure Tmes. This calculated differential voltage difference can be observed in FIGS. 2c and 3c during the activation and deactivation of electrical elements. In FIG. 2c, the voltage peaks present at t = 428 s, t = 431s and t = 435s each correspond to a voltage difference between the reference voltage and a measured instantaneous voltage. In FIG. 3c, these are the visible voltage peaks at t = 215s, t = 218s and t = 221s. This voltage difference at the terminals of the calculated difftension battery is compared during a subsequent step 400 to a predetermined threshold S of voltage across the battery. This comparison is triggered by a switch 410 driven by a time comparison test 420 which returns the value of the voltage difference across the calculated voltage battery in place of the permanently zero value. This time comparison test 420 is defined by comparing the counting value of the measurement time Tmes with respect to the zero value. As long as the counter 210 does not expire, that is to say that the time t is greater than 0, then the comparison step 400 is carried out between the voltage difference at the terminals of the calculated difftension battery and the threshold S of predetermined voltage. This step 400 makes it possible to decide on the correct activation of the controlled electric element and therefore on the proper functioning of the latter.

  Indeed, if the value of the difference in voltage across the calculated voltage difftension battery is lower than the voltage threshold S then it is considered that the comparison test 400 is true and there is failure of the electrical element.

  Preferably, the threshold S is of the order of 0.3V. As illustrated in FIGS. 2c and 3c, the peaks of voltage differences present are relatively large in amplitude and greater than the predetermined voltage threshold S. It can be concluded that the electrical elements are working properly.

  According to the result of the comparison test between the value of the voltage difference across the calculated voltage and the voltage threshold S, it is possible or not to carry out an identification step 600 of the faulty electrical element. This identification step 600 is preceded by a minimization step 500. In this step 500, the result of the comparison test between the voltage difference across the calculated battery voltage and the voltage threshold S drives a switch 510. which returns the null value instead of the value 1.

  The output value of this switch 510 is then compared (step 530) to an output value of a switch 520 driven by the detection of an activated element Vactiv to determine which of the two values is minimal. This last switch 520 returns the value 1 in place of the minimum value retained having a time delay 1 / z when the activation of an electrical element has been detected. When the result of the comparison test 400 between the value of the voltage difference at the terminals of the calculated DC voltage battery and the voltage threshold S is true, it can then be assigned as mentioned previously, in a subsequent step 600 to a particular electrical element through a series of identification tests 630. For this, when the counter 210 expires, that is to say, the time t is zero, it causes a rising edge 610.

  This rising edge 610 will drive a switch 620 which returns, only at the end of the measurement time Tmes counted by the counter 210, the null value in place of the minimum value determined in the previous minimization step 500.

  Moreover, during an identification test 630, the number of electrical elements activated after the activation command of one of them Nact is compared to a predetermined value corresponding to the number n of electric elements controlled. where n is an integer (steps 640,641,642,643).

  If the result of an equality test is considered true, it drives a switch 631,632,633,634 which returns the result of the minimization test 530 of the minimization step 500 to an output Sn 'corresponding to a particular electrical element n'. If it is considered false, it returns the zero value to the output Sn 'corresponding to the particular electrical element n'. To overcome false detections on the activation or not of other electrical elements, it is possible to perform a method of filtering out faults as illustrated in FIG. 4. In a first step 700, counting is performed 20 / downcounting detected failures and absence of faults by a counter / down counter. An indicator I1 allowing authorization of diagnosis via the alternator load drives a switch 701 which returns an Incr increment value of the up / down counter instead of the null value. This indicator I1 is also associated with an indicator I2 for failures on alternator charge information to drive a second switch 702 which returns a Decr decrement value of the defect counter instead of the null value. The decrement value Decr is then subtracted from the Incr increment value providing a result of counting / downcounting detected failures and outages.

  This result is only valid if the motor is autonomous. An equality test 703 is then performed to determine if the motor is autonomous. If the test result is true, it drives a switch 704 which returns the counting / down counting result instead of the null value. In a next step 710, the counting / down counting result is summed with a Pan value of the fault counter present during the diagnostics of the electrical elements stored in a previous step 720.

  The resulting value is bounded between a minimum value min and a maximum maximum value of the fault counter of the electrical elements (step 730). The resulting output of this frame 730 is returned by a switch 721 driven by information Eff allowing the clearing of a fault on another switch 741. This switch 741 is, meanwhile, driven by an indicator I3 to read the framing value stored in an eeprom memory at initialization to be saved in this memory and set the Pan value of the fault counter present during the diagnostics of the electrical elements. When the resulting output of the frame reaches the maximum Max value of the fault counter then the fault is thrown. In alternative embodiments of the present invention, provision may be made to combine the method according to the invention with conventional electrical diagnoses or diagnostics based on the detection of a load reduction at the terminals of an alternator driven by the motor and feeding the electrical elements. Of course, the present invention is not limited to the particular embodiments which have just been described but extends to any variant within its spirit. In particular, the present invention is not limited to the accompanying drawings. The specific references illustrated in the preceding paragraphs are non-limiting examples of the invention.

Claims (9)

claims   1. A method for controlling at least one electric element of an engine, characterized in that it comprises, during its implementation, at least one step of calculating a difference in voltage measurements across a battery (300) supplying said electrical element to detect a change in the operating state of said electrical element.   2. Method according to claim 1, characterized in that it comprises a step of controlling activation of the electrical element (100) at a time to, followed by a step (200) of triggering a counter defining a time of measurement Tmes.   3. Method according to claim 2, characterized in that it comprises, a step of filtering (310) and storing (330) a voltage across the battery measured at the instant to the activation of the electric element.   4. Method according to claim 3, characterized in that the calculation of the difference in voltage measurements at the terminals of a battery is expressed as the difference between the measurement of the voltage at the terminals of the filtered battery and stored at the battery. instant to and a measurement of voltage across the battery at a time t less than or equal to the measurement time Tmes.   5. Method according to one of the preceding claims, characterized in that it comprises a comparison step (400) between the difference in voltage measurements at the terminals of the calculated battery and a predetermined threshold voltage S, the result of the comparison indicating a faulty electrical element or not.   6. Method according to claim 5, characterized in that according to the result of the comparison between the calculation of the difference in voltage measurements at the battery terminals and the predetermined voltage threshold S, an identification step is carried out (600 ) of the faulty electrical element.   7. Method according to one of the preceding claims, characterized in that the electric element is an immersion heater.   8. Method according to one of the preceding claims, characterized in that it is carried out while the engine is running or not.   9. System for controlling at least one electrical element of an engine comprising at least measuring means and calculation means, characterized in that the calculation means are able to calculate a difference in voltage measurements across the terminals of a battery supplying said electric element so as to detect a change in the operating state of said electric element.