WO2007071483A1 - Method for testing the tightness of a vehicle tank system - Google Patents

Abstract

Disclosed is a method for testing the tightness of a vehicle tank system, in which a pressure that deviates from the atmospheric pressure is generated on a reference leak during a predefined interval by means of a pressure source and an operational parameter of the pressure source is detected as a reference variable while a pressure that deviates from the atmospheric pressure is generated in the tank system and the same operational parameter of the pressure source is detected as a measured variable. In order to be able to ignore the momentary tank level during the diagnosis, the measured variable is compared to the reference variable that is increased by a setpoint value, and the tank system is considered to be tight if the measured variable is greater than said reference variable while the measured variable is subjected to additional test criteria if the measured variable is smaller than the reference variable.

Description

description

title

Method for leak testing a tank system of a vehicle

State of the art

The invention is based on a method for leak testing a tank system of a vehicle according to the preamble of claim 1.

In a known method for leak testing of a tank system of a vehicle of this type (DE 100 06 186 Cl) is introduced by means of a pump by switching a valve alternately into the tank system and in the reference leak an overpressure. The current absorbed by the electric pump motor is measured and forms the measurand or the reference variable. Since pumping through the reference leak results in a temporally substantially constant motor current, the reference variable is constant. The time-dependent measured variable is compared directly with the reference variable. If the measured variable reaches or exceeds the reference value after expiry of a previous time interval, it is detected that the tank system is leaking. If, on the other hand, the measured variable has not reached the reference value at the end of the time interval or if the measured variable no longer appreciably rises after the time interval has expired, its gradient is therefore too small, an overpressure is generated until a predetermined end time has been reached. The end time is selected depending on the tank level. The measured quantity recorded at the end time is saved. Immediately afterwards, a new reference variable is again recorded in a reference measurement and compared with the stored measured variable. If the stored measured variable is greater than or equal to the new reference size, it is detected that the tank system is leaktight; in the other case, it detects a leak in the tank system. Disclosure of the invention

The inventive method for leak testing of a tank system of a vehicle having the features of claim 1 has the advantage that, unlike the known method described above, it is independent of the current level of the tank and thus no diagnosis of the tank level signal is required. With the elimination of the tank level signal diagnosis, the accuracy requirements for the level sensor are reduced as it is only required to display the level in the on-board system of the vehicle. The fill level independence of the method according to the invention is based on the fact that the comparison value for the measured variable is larger than that by a default value, a so-called offset

Reference size, a positive or negative pressure in the tank system must be generated, which is greater than the negative or negative pressure in the reference measurement and in case of a leak in the tank system, which is equal to or greater than the reference leak can not be achieved in the tank system. The tank level does affect the size of the measurement time, but not the diagnostic result. A measuring time adapted to the minimum filling level of the tank provides a reliable statement about the tightness of the tank system at every tank level.

According to a preferred embodiment of the invention, in the case that the measured variable is greater than the reference value increased by a reference value, recognized for leaks of the tank system and in the case that the measured variable is smaller, the measured variable subjected to further test criteria. With the other test criteria environmental influences are compensated during diagnosis, which can simulate a possible leak by reducing the pressure build-up in the tank system, although such is not present. Such environmental influences are fuel condensation effects, a drift of the measured variables at ambient humidity, etc.

The measures listed in the further claims advantageous refinements and improvements of claim 1 method are possible.

According to an advantageous embodiment of the invention, a check of the stability of the measured variable is carried out as a further test criterion for the smaller measured variable compared to the reference value increased by the reference value. This stability check of the measured variable shortens the diagnosis time, which is advantageous since the diagnosis is carried out in the after-run, ie immediately after the vehicle engine has been switched off. If the stability of the measured variable is affirmative, a new reference measurement is carried out with which a second reference variable is detected. The previously stored measured variable is compared with the second reference variable, which in turn is increased by the default value, the so-called offset, and finally recognized as a leak in the tank system, when the measured variable is smaller than the reference variable increased by the offset. If the measured value does not stabilize, then, in order to save measurement time, as a further test criterion according to a further embodiment of the invention, the gradient of

Measured variable checked; because, in the event of a leak in the tank system, the measured variable may, after a relatively long time, also reach the reference value increased by the preset value, but its gradient, i. their increase per unit time, much lower, so that even the too small gradient of the measured variable is an indication of a leak. If the gradient is not large enough or too small, the process of re-reference measurement and test described above is carried out identically. Alternatively, it is possible to apply the test criteria stability and gradient of the measured variable not successively but in parallel, i. to carry out the test criterion Gradient independently of the result of the stability test.

The invention is explained in more detail in the following description with reference to an embodiment shown in the drawing. The drawing shows a flow chart illustrating the method for leak testing a tank system.

A tank system with a diagnostic module for detecting a tank leak is described in DE 100 06 186 C1 or in DE 196 36 431 Al and each sketched in Fig. 1, so that reference is made to this extent. As described there, the diagnostic module comprises a working as a pressure pump, electrically driven air pump, a switching valve that connects the pressure outlet of the air pump in its one switching position to a reference leak predetermined size having branch channel and in its other switching position on the tank system. The switching valve and the air pump are controlled by a switching device. When the air pump is running, an overpressure at the reference leak or an overpressure in the tank system is generated, depending on the switching position of the reversing valve. The current consumption of the air pump is recorded as an operating parameter and evaluated in an evaluation unit for tank leak diagnosis. Instead of the current consumption, other operating parameters of the air source representing a pressure source can be used, such as the speed of the air pump or the voltage applied to the air pump. - A -

With this so-called tank leak diagnosis module, the tightness test of the tank system is performed according to the method described below, which is illustrated in a flow chart in the drawing.

First, a reference measurement is performed, including the switching valve such

Switching position assumes that the switched air pump generates an overpressure at the reference leak. During the reference measurement, a pump current that is substantially constant in time (that is, the motor current of the air pump) is set, which is detected and stored as a reference variable. Subsequently, the changeover valve is switched, so that now the pressure outlet of the air pump is connected to the tank system and generates an overpressure in the tank system. When the switching valve is switched over, the tank measurement specified in the flow chart starts, in which the pump current is detected as a measured variable over the pump or measuring period. When switching the pump current, so the motor current of the air pump, initially abruptly decreases, and then increase continuously. In the further course of the description, the pump current is referred to as a measured variable in accordance with the flowchart of the drawing. The stored reference variable, which represents the current level reached during the reference measurement, and the measured variable continuously acquired during the tank measurement are evaluated for the diagnosis of the tank system in such a way that the measured variable is compared with the reference variable increased by a default value, referred to below , The offset is determined empirically and is permanently stored in the evaluation unit. If the comparison of the measured variable with the reference variable increased by the offset indicates that the measured variable is greater, the tightness of the tank system is recognized. If the comparison shows that the measured variable is smaller than the reference variable plus offset, the measured variable is subjected to further test criteria described below.

A test criterion is the stability of the measured variable and another test criterion is the gradient of the measured variable, ie its temporal change. The stability of the measured variable is defined as a change in the measured variable over a given time interval that is less than a predefined amount of change. For example, the amount of change is set at 0.1mA. If the test shows that the measured variable fulfills the stability criterion, the measured variable is stored, and a second reference measurement is initiated by switching over the reversing valve. The test for stability of the measured variable is preferably carried out twice in succession after a short minimum time of tank measurement. The minimum pumping time, after which the stability of the measured variable is checked, is 100% by way of example, whereby it is taken into account that after the immediate shutdown of the Motors of the motor vehicle, still disturbances such as light off, window closing, etc., may arise, which cause a corruption of the pump current. If the test of stability results in an instability of the measured variable, the test criterion of the gradient of the measured variable is used. The gradient is determined at a value of the measured variable, which is significantly above the minimum of the measured variable. This minimum occurs immediately after the initiation of the

Tank measurement on. The gradient of the measured variable is compared with a gradient preset value. If the gradient is smaller than the gradient preset value, the second reference measurement is in turn initiated by switching over the changeover valve. However, if the gradient of the measured variable is greater than the gradient preset value, the above-described comparison of the measured variable with the reference variable increased by the offset is repeated. The test criterion of the gradient of the measured variable can be introduced not only depending on the test result of the stability of the measured variable, but be performed in parallel to the test of stability. This is illustrated in the flowchart by the additionally drawn, dashed flow line. If the stability of the measured variable and / or a sufficiently small gradient of the measured variable has been determined and thus the second reference measurement has been initiated, the air pump again generates an overpressure at the reference leak, which after a certain pumping time of the air pump leads to a nearly constant second reference variable. The measured variable stored at the initiation of the second reference measurement is now compared with the second reference variable, which is enlarged by the same offset as the first reference variable. If the measured value is greater than the second reference value plus offset, the tightness of the

Tank system detected, the measured size is smaller than the second reference size plus offset, so a leak is diagnosed in the tank system, which has at least the size of the reference leak. The reference leak is specified, for example, with a clear diameter of 0.5 mm.

In a modification of the method, no overpressure, but a negative pressure is generated by means of the air pump at the reference leak and in the tank system. The current consumption or the rotational speed or the voltage applied to the now acting as a suction pump air pump voltage is used as the operating parameter unchanged.

Claims

claims 1. A method for leak testing of a tank system of a vehicle, in which by means of a pressure source during a predetermined time interval on the one hand to a reference leak and on the other hand in the tank system each generates a deviating pressure from the atmospheric pressure while an operating characteristic of the pressure source is detected on the one hand as a reference and on the other hand as a measured variable and in which reference is made to leak or leakage of the tank system on the basis of the measured and reference variables, characterized in that the reference variable is increased by a preferably empirically determined default value to detect leaks or leaks, and the measured variable is compared with the reference value increased by the predetermined value , 2. The method according to claim 1, characterized in that at a measured variable which is greater than the reference value increased by the reference value for leakproofness of the tank system recognized and smaller size, the measured variable is subjected to further test criteria. 3. The method according to claim 2, characterized in that the stability of the measured variable is checked as a further test criterion. 4. The method according to claim 3, characterized in that the test for stability of the measured variable is carried out directly twice in succession. 5. The method according to claim 3 or 4, characterized in that is determined as a test criterion for the stability of the measured variable whose change over a predetermined time interval and at change, which is smaller than a predetermined amount of change, is detected for stability. 6. The method according to any one of claims 2 to 5, characterized in that in relation to the increased by the predetermined value reference variable smaller measurand and / or in determining the Stability of the measured variable is determined as a further test criterion, the gradient of the measured variable and compared with a gradient preset value. 7. The method according to claim 6, characterized in that the gradient of the measured variable is determined at a value of the measured variable, which is significantly above the minimum of the measured variable. 8. The method according to any one of claims 3 to 7, characterized in that when determining the stability of the measured variable and / or at a gradient of the measured variable, which is smaller than the gradient default value, the measured variable stored in a new reference measurement detects a second reference variable and the stored measured variable is compared with the second reference variable increased by the same default value and, on the other hand, a larger measured quantity is recognized for tightness of the tank system and, on the other hand, a smaller measured variable for a leak in the tank system. 9. The method according to any one of claims 3 to 8, characterized in that when not determining the stability of the measured variable, a new comparison of the measured variable is performed with the reference value increased by the reference value. 10. The method according to any one of claims 1 to 9, characterized in that the pressure is generated by means of an electrically driven air pump as positive or negative pressure and that the current consumption of the air pump is used as the operating characteristic of the pressure source.