DE19919597C1 - Liquid level monitoring device for overfill protection in motor vehicle fuel tank - Google Patents

Abstract

The device includes a capacitor (5) arranged at the critical level so that liquid (2) can penetrate inside the capacitor. A measuring device (8) detects the capacitance of the capacitor and provides measurement signals (9). Noise peaks are filtered out of the measurement signals and the current value of the filtered signal is compared with a reference value which was formed from previous measurement values. A signal is generated to indicate that the level has been exceeded if the present value exceeds the reference value by a preset margin.

Description

To avoid the risk of overflow of a liquid in one Recognize the container in time and, if necessary, the To be able to stop hydration, the level of the Liquid when a maximum level is exceeded be watched over. An example of this is overfuel protection in motor vehicles. The gases displaced during the refueling process should be filtered through an activated carbon filter. At the However, refueling must not allow any liquid to enter the filter long. Therefore there is a sensor in the supply line to the filter arranged, which in the case of detection of liquid Valve to protect the filter switches. As a liquid Depending on the application, sensors are float switches, con clocks, which when wetted by the liquid Change resistance, or capacitors known, their Kapa change when liquid penetrates. In the last mentioned case of a capacitor results accordingly the respective dielectric constant in gasoline a dop pelte capacity and with methanol a 25-fold capacity in Comparison to the condenser surrounded by air. The measurement the capacity usually takes place via the alternating current resistance of the capacitor. Given the low capacity Actual values on the order of Femtofarad must, however a number of disruptive factors such as aging and temperature drift of the components used, contamination in the area of the capacitor plates and different properties of the liquids to be recognized are taken into account.

DE 43 09 605 A1 describes a method for displaying the Operating fluid supply of motor vehicles known. Around if the motor vehicle is parked at an angle, the display is incorrect avoid the last when the vehicle comes to a standstill the displayed measured value is saved and displayed; to The then available raw measurement value becomes a calming time  saved as reference value, after which the on shown measured value depending on subsequent changes the raw measurement value is corrected compared to the reference value.

In a method known from DE 30 21 374 A1 Determination of the amount of operating fluids from Motor vehicles will accelerate the motor vehicle the measuring signal of a quantity transmitter up to a predetermined one corrected maximum change depending on acceleration.

In a capacitive known from DE 195 36 199 C2 working monitoring device for the level of a Liquid will generate a level exceeding signal when the measured capacitance exceeds a comparison value. This comparison value is dependent on two, initially Lich spaced from each other with a predetermined distance value established reference values between these, whereby one of these two measured values always precedes one certain amount is changed when the measured Kapa quantity exceeds or falls below this reference value.

The invention is therefore based on the object verver casual monitoring of the level of a liquid by means of to achieve a capacitor as a liquid sensor.

According to the invention the object is achieved by the in claim 1 specified monitoring device solved.  

Advantageous further developments of the invention monitoring device are specified in the subclaims.

The monitoring device according to the invention does not work with absolute thresholds for the capacitance of the condenser tors, when exceeded the critical Level is detected, but reacts to changes the capacitance of the capacitor. This is the monitoring insensitive to slow disturbances like Temperature and aging-related component drift, series scatter or creeping pollution. First of all Interference peaks, e.g. B. by electrostatic discharge can occur, filtered out of the measurement signal. On the current measured value of the filtered is then closed Measuring signal continuously compared with a comparison value, the is formed from previous measured values, and a level Monitoring signal generated when the current measured value Comparison value by a predetermined distance value steps, d. H. if the capacitance of the capacitor significantly increased.

To reduce noise and similar interferences, the measurement signal preferably before it is filtered by formation smoothed by short-term averages. To do this, each measurement of the measurement signal by a mean value from a predetermined Number of immediately consecutive measured values replaced.

The interference peaks are preferably filtered out in that an expectation corridor is defined internally half of which he the measured values of the interference-free measurement signal as expected, the expectation corridor lies every time then move up or down by a fixed amount is set if the current measured value is greater or less than the previous measured value is and with constant measurement value remains unchanged, and that for the further signal evaluation such measurement values are disregarded that are outside the expected range.  

About the computing effort and the associated hardware effort to fulfill the monitoring function if possible to keep low is preferred at the beginning of each of periodically consecutive time intervals of the even current measured value as a comparison value for within the measured values occurring next following time interval saves. There will therefore only be two memory locations for two comparison values to be saved at the same time are required by which is the one comparison value for the current measured values in the current time interval applies and the other comparison value for the measured values of the next time interval provided.

To increase the sensitivity of the measurement signal evaluation the comparison value is tracked to the measurement signal curve, by every time within the current time interval valls the current measured value is both smaller than that Start of the previous time interval for the measured values of the current time interval saved comparison value as well as less than that at the beginning of the current time interval saved comparison value for the measured values of the next time interval is, both stored Comparison values are replaced by the current measured value.

To further explain the invention, the following is based on the figures of the drawing are referred to; in detail gene:

Fig. 1 is a simplified block diagram of the monitoring device according to Inventive,

Fig. 2 shows an example for the smoothing of the measurement signal,

Fig. 3 shows an example for the filtering out of noise spikes from the smoothed measurement signal,

Fig. 4 shows an example of the formation of the comparison values for the filtered measurement signal and

Fig. 5 shows an example for the additional correction of the reference values.

Fig. 1 shows a section of a liquid container 1 with a liquid 2 contained therein, whose level may vary. 3 The liquid container 1 can be, for example, a line in the tank system of a motor vehicle, in which the gases displaced during the refueling process are guided in the direction of an activated carbon filter and into which gasoline can penetrate in the event of overfilling. It should be recognized when the liquid level 3 comes close to the activated carbon filter in order to protect the activated carbon filter from the ingress of gasoline in time by stopping the fueling process and / or switching a diverter valve in the course of the line. Therefore, a capacitor 5 with two capacitor plates 6 and 7 is arranged at a critical level 4 , which are applied to the outside of the container 1 . As an alternative, the condenser 5 can also be arranged inside the container 1 . On the capacitor 5 , a measuring device 8 is connected, which detects a measuring signal 9 corresponding to the capacitance of the capacitor 5 and evaluates it. As a result of the signal evaluation is the measuring device 8 generates a level crossing signal 10 as soon as the liquid level reaches the critical level 3 level 4 and passes. The measurement of the capacitance takes place via the AC resistance of the capacitor 5 , z. B. applied to the capacitor 5 an alternating voltage and the current is detected as a measurement signal 9 . The measuring device 8 contains a device 11 for smoothing the measurement signal 9 , a device 12 for filtering out interference peaks from the smoothed measurement signal 9 'and a device 13 for comparing the filtered measurement signal 9 "with the comparison signal formed from the measurement signal 9 in order to obtain the result Derive level exceeding signal 10 .

As shown in FIG. 2, a new measured value MWi is formed every millisecond by successive individual measurements or by sampling the analog measurement signal 9 . In order to suppress noise and similar interferences, the measured values MWi are formed in the context of a short-term averaging by means of mean values MMW8 from eight immediately successive measured values MW1. . . MW8 replaced. In order to keep the computational effort as low as possible, two adjacent binary measurement values, z. B. MW1, MW2, added and a mean of two is formed by shifting the binary sum by one bit position to the right. In the same way, a four-mean value is formed from two two-means averages and an eight-figure mean from two four-means means.

As shown in FIG. 3, the measurement signal 9 'thus smoothed may have interference peaks 14 , for example as a result of electrostatic discharges of the capacitor 5 . To filter out these interference peaks 14 , an expectation corridor 15 with an upper limit 16 and a lower limit 17 is defined, within which the measured values, here the averaged measured values MMWi of the interference-free smoothed measurement signal 9 ', lie as expected. The given by the distance between the two boundaries 16 and 17, width of the expectation corridor 15 is constant, with the expectation corridor 15 is each time shifted by a fixed predetermined amount up or down when the current measured value MMWi larger or smaller than the immediately preceding Measured value MMW (i - 1) is. If the measured value remains unchanged, the maintenance corridor 15 remains unchanged. Such measured values, e.g. B. MMWj or MMWk, remain unconsidered for the further measurement signal evaluation, which lie outside the expectation corridor 15 .

To a significant increase of the capacitance of the capacitor 5 can be seen and inferred from the level crossing signal 10, as shown in FIG. 4, each measurement, here the averaged measured values z. B. MMWpi, of the smoothed and filtered measurement signal 9 "with a comparison value VWp. The comparison values are formed in periodically successive time intervals of here 8 s, with the currently current average measurement value at the beginning of each time interval, for example ZIp MMWp1 is stored as a comparison value VWq for which the measured values occur within the next time interval ZIq. Accordingly, for the measurement values of the current time interval ZIp, the measurement value MMWo1 that was current at the beginning of the previous time interval ZIo is valid as a comparison value VWp The level exceeding signal 10 is triggered if the comparison value VWp applicable to it exceeds a predetermined fixed distance value A. Conversely, the level exceeding signal 10 is reset when the current mean measured value falls below the comparison value by the predetermined distance value A. Because for each Only two comparison values at the time, e.g. B. VWp and VWq, must be provided at the same time, the associated storage effort is very low.

In the example shown in Fig. 5, the sensitivity of the monitoring device is increased in that the two stored comparison values, for. B. VWp and VWq, for the measured values of the current time interval ZIp or the fol lowing time interval ZIq each time then be replaced by the current measured value in the current time interval ZIp if this is less than both comparison values ZIp and ZIq. This results in the course of the comparison values designated VW '.

Claims (5)

1. Monitoring device for the level ( 3 ) of a liquid speed ( 2 ) with a at a critical level ( 4 ) arranged such a capacitor ( 5 ) that the liquid ( 2 ) can penetrate into the interior of the capacitor, and with a nachgeord Neten measuring device ( 8 ) for detecting and evaluating a measurement signal ( 9 ) corresponding to the capacitor capacity, interference peaks ( 14 ) being filtered out of the measurement signal ( 9 ), the respectively current measurement value of the filtered measurement signal ( 9 ') being continuously compared with a comparison value (VW) , which is formed from previous measured values, and a level exceeding signal ( 10 ) is generated when the current measured value exceeds the comparison value (VW) by a predetermined distance value (A). 2. Monitoring device according to claim 1, characterized in that the measurement signal ( 9 ) prior to its filtering is smoothed by continuous formation of short-term mean values (MMW). 3. Monitoring device according to claim 1 or 2, characterized in that for filtering out the interference peaks ( 14 ) an expectation corridor ( 15 ) is defined, within which the measured values (MMW) of the interference-free measurement signal ( 9 ') lie as expected that the Expectation corridor ( 15 ) is shifted up or down by a fixed amount each time the current measured value (MMWi) is greater or smaller than the previous measured value (MMW (i - 1)) and remains unchanged if the measured value remains the same, and that those measured values (MMWj, MMWk) which lie outside the expectation corridor ( 15 ) are not taken into account for the further signal evaluation. 4. Monitoring device according to one of the preceding An sayings, characterized in that at the beginning of a each of periodically consecutive time intervals  (ZI) the current measured value (MMWp1) as a comparison value (VWq) for within the next time interval (ZIq) occurring measurement values is stored. 5. Monitoring device according to claim 4, characterized ge indicates that every time within the current time interval (ZIp) the current measured value both smaller than that at the beginning of the previous time intervals for the measured values of the current time interval (ZIp) stored comparison value (VWp) as well as smaller than that at the beginning of the current time interval (ZIp) stored comparison value (VWq) for the measured values of the next time interval (ZIq) is, both saved saved comparison values are replaced by the current measured value become.