EP2115400A2

EP2115400A2 - Method and device for continuously measuring dynamic fluid consumption

Info

Publication number: EP2115400A2
Application number: EP08708397A
Authority: EP
Inventors: Karl KÖCK; Michael Cernusca
Original assignee: AVL List GmbH
Current assignee: AVL List GmbH
Priority date: 2007-02-05
Filing date: 2008-01-30
Publication date: 2009-11-11
Also published as: JP2010518368A; AT9241U3; AT9241U2; WO2008095836A2; WO2008095836A3; US20100083770A1; CN101652637A

Abstract

The invention relates to a method for continuously measuring dynamic fluid consumption, particularly fuel consumption, employing a continuously operating flow sensor (7) with variable pressure loss, preferably a mass flow sensor, wherein the pressure is determined downstream of the flow sensor (7) and used to control fluid conveyance. In order to enable continuous, accurate and temporally highly resolved consumption measurement and the highly dynamic determination of the flow rate, while maintaining the simplest design possible, at at least one time also the pressure directly upstream of the flow sensor (7), the difference of the two pressure values, and from this difference a value for the flow rate of the fluid are determined.

Description

Method and device for continuous measurement of dynamic fuel consumption

The invention relates to a method for continuously measuring a dynamic fluid consumption, in particular fuel consumption, by means of a continuously operating flow sensor with variable pressure drop, preferably a mass flow sensor, wherein the pressure behind the flow sensor determined and used to control the fluid delivery, and a device for continuous measurement of a dynamic fluid consumption, in particular fuel consumption, comprising a tank, possibly a conditioning plant, and preferably a controllable pump, a continuously operating flow sensor for the liquid, preferably a Coriolis sensor, and immediately downstream of the flow sensor, a pressure sensor whose output with at least one control device for the fluid flow, for example a controllable pump is connected.

For the measurement of the consumption of liquids, especially in the application for the fuel consumption of engines on test benches, discontinuously operated systems based on balances are known. They have the advantage of open systems, with both the delivered and the recirculated amount of fuel is detected by measurement and taken into account in the indication of consumption. Such scales prove to be disadvantageous in that they must always be refilled, and thus no continuous measuring operation is possible. Therefore, measuring devices that perform a volumetric flow measurement are often used to continuously measure fuel consumption. By means of an additional density measurement, the consumed fuel mass is determined therefrom, which represents the actually required measured variable. A direct measurement of the mass consumption, which avoids the disadvantage of additional density measurement, can be implemented discontinuously with the weighing method and continuously using Coriolis sensors.

Modern internal combustion engines usually require defined and flow-independent pressure conditions both in the fuel supply line and in the optionally present fuel return line for proper operation. Therefore, an arrangement for flow measurement or an arrangement for calibrating a flow measurement with in each case only one pressure sensor behind or before the flow measurement has already been proposed in the AT 3 350 U2 or the AT 6 117 U2, as well as with a pressure stabilization device for stabilizing the flow pressure of the mass flow sensor in order to generate the required low and constant pressure at the connection point of the consumer. In particular, high-frequency, erratic or pulsatile withdrawals must be taken into account quickly. For pressure stabilization is therefore in the above downstream of the actual flow sensor pressure regulating means (pressure regulator) attached to the continuous measurement methods of the fuel, which regulate the flow-dependent pressure at the outlet of the measuring system to a constant outlet pressure. However, these mechanical pressure regulators act as a "hydraulic diode", ie the flowing medium can only flow through the regulator in one direction, namely downstream, and a measuring system constructed with such a pressure regulator does not constitute an open system Injection system in the measuring system or thermal expansion of the fuel complex pressure compensation devices are provided.

The object of the present invention was to specify a method and a device which, with the simplest possible structure, permit continuous, accurate and also high-resolution consumption measurement and the highly dynamic determination of the flow value.

To solve this problem, the method described above according to the invention is characterized in that at least one time and the pressure immediately before the flow sensor, the difference of the two pressure values and from this difference, a value for the flow of the fluid can be determined. This results in a combination of a very accurate long-term flow measurement with a highly dynamic determination of the flow value by the time-high resolution pressure signals, using a pressure measurement which is necessary anyway for the pressure control.

An advantageous variant of the method provides that the pressure downstream of the flow sensor, the pressure immediately upstream of the flow sensor, the difference between the two pressure values and from this difference a value for the flow of the fluid are determined continuously with a predefinable time resolution. This allows the resolution of the flow value determined from the pressure measurements to be set.

According to a further variant of the invention, it is provided that an average fluid consumption is determined by means of the flow sensor, linked to the value for the flow of the fluid from the difference of the pressure values, and a plausibility check is thus carried out for the measurement. The very accurate measurement can also be checked well in terms of measurement plausibility due to the redundant flow determination.

If, according to a further embodiment, a mean fluid consumption is determined by means of the flow sensor, linked to the value for the flow of the fluid from the difference of the pressure values and thus further fluid parameters are determined, there is the possibility of the two different flow measurements for determining further fluid parameters, eg density or viscosity to draw on. Advantageously, it can also be provided that the signal of the flow sensor of a low-pass filter and the signal of the difference of the two pressure values are subjected to high-pass filtering, and the filtered signals are subsequently combined to form a signal of a large frequency bandwidth.

The device for carrying out the flow measurement is inventively characterized in that a further pressure sensor is provided immediately in front of the flow sensor, wherein both pressure sensors are connected to an evaluation unit, in which at least one time determines the difference between the values determined by the two pressure sensors and from this Difference is a value for the flow of the fluid is determined.

In order to be able to determine a value which is higher than the signal of the flow sensor via the differential pressure measurement, pressure sensors with a faster step response than those of the flow sensor are used according to another feature of the invention.

Advantageously, it can be provided that the difference of the two pressure values and from this difference a value for the flow of the fluid are determined continuously in the evaluation unit with a predefinable time resolution.

According to a further feature of the device according to the invention, an average fluid consumption is determined in the evaluation unit from the signals of the flow sensor, linked to the value for the flow of the fluid from the difference of the pressure values and thus carried out a plausibility check for the measurement.

A further extension of the field of application is given for a device according to the invention in which an average fluid consumption is determined in the evaluation unit from the signals of the flow sensor, linked with the value for the flow of the fluid from the difference of the pressure values and thus further fluid parameters are determined.

In order to achieve a flow signal with a very high bandwidth, it may further be provided that a low-pass filter is implemented in the measuring channel of the flow sensor and a high-pass filter is implemented in the measuring channel of the signal for the difference of the pressure values, a signal being composed of the filtered signals in the evaluation unit.

It is advantageous if the effective filter characteristics up to an upper limit frequency have a constant value, which value is preferably 1.

In the following description, the invention will be explained with reference to an embodiment and with reference to the accompanying drawings. The drawing figure shows a schematic example of a device according to the invention as a continuous fuel consumption measuring system, in particular for engine test stands. Via a line A and a preferably electromagnetically operable filling valve 1, a tank 2, as a reservoir with the liquid, ie the fuel supplied. The tank 2 further has a vent 3 and a level sensor 4 coupled to the filling valve 1.

From the tank 2, the fuel is supplied by means of a preferably controllable fuel pump 6 via a line B to the continuously operating flow sensor 7, preferably a Coriolis sensor. Thereafter, the fuel passes via preferably a shut-off valve 8 to the delivery point, at which the engine as a consumer (not shown) is connected and to which the fuel with a certain, predetermined pressure is to be available.

Between the flow sensor 7 and the shut-off valve 8, a line C branches off, which leads to the control input of, for example, a mechanical-hydraulic pressure regulator 9. Via the pressure regulator 9, the flow is now controlled by a line D, depending on the pressure in the line behind the flow sensor 7, which branches off between the fuel pump 6 and the flow sensor 7 of the line B and returns through the pressure regulator 9 to the fuel tank 2. Thus, a control loop with feedback is realized, in which each pressure change is converted behind the flow sensor 7 relative to the settable on the pressure regulator 9 default value in the same direction change of that liquid stream, which diverted through the line C before the flow sensor 7 from the line B and without flow through this Sensor 7 is returned to the tank 2 again. With this change in quantity but also the form upstream of the flow sensor 7 is controlled, in the opposite direction to the pressure change behind the flow sensor 7, so that the pressure deviation from the set value can be quickly and safely compensated. At most, a pressure setting at the delivery point to the consumer could also be realized via a regulation of the pump 6.

Between the pump 6 and the flow sensor 7, a first pressure sensor 10 for determining the pressure in the line B is provided. A second pressure sensor 11 is provided behind the flow sensor 7 for determining the pressure in the line system. The two pressure sensors 10, 11 preferably have a faster jump response than the flow sensor 7 used. Both pressure sensors 10, 11 are connected to an evaluation unit 12, in which the difference of the values determined by the two pressure sensors 10, 11 is at least one time determined and from this difference, a value for the flow of the fluid is determined.

By hard-wired circuits or implemented via software control, the difference of the two pressure values of the sensors 10, 11 can be determined in the evaluation unit, for example continuously with a predefinable temporal resolution, wherein this difference then further a value for the flow of the fluid can be determined. The determination of an average fluid consumption in the evaluation unit 12 from the signals of the flow sensor 7 and its connection to the flow value from the difference of the pressure values to the plausibility check for the measurement could also be provided.

On the other hand, there is also the possibility that an average fluid consumption is determined in the evaluation unit 12 from the signals of the flow sensor 7, linked to the value for the flow of the fluid from the difference of the pressure values of the sensors 10, 11 and such further fluid parameters are determined, for example the density or viscosity of the fluid.

Advantageously, in the measuring channel of the flow sensor 7, a low-pass filter and in the measuring channel of the signal for the difference of the pressure values of the sensors 10, 11 realized a high-pass filter. In the evaluation unit 12 can then be composed of the filtered individual signals, a signal with high bandwidth. It is advantageous if the effective filter characteristics up to an upper limit frequency have a constant value, which value is preferably 1.

claims:

Claims

claims:

1. A method for continuously measuring a dynamic fluid consumption, in particular fuel consumption, by means of a continuously operating flow sensor (7) with variable pressure drop, preferably a mass flow sensor, wherein the pressure behind the flow sensor (7) determined and used to control the Fluidförde- tion, characterized in that at least one point in time the pressure immediately before the flow sensor (7), the difference between the two pressure values and from this difference a value for the flow of the fluid are determined.

2. The method according to claim 1, characterized in that continuously with a predeterminable temporal resolution of the pressure behind the flow sensor (7), the pressure immediately before the flow sensor (7), the difference of the two pressure values and from this difference a value for the flow of the Fluids are determined.

3. The method according to any one of claims 1 or 2, characterized in that by means of the flow sensor (7) determines an average fluid consumption, linked to the value for the flow of the fluid from the difference of the pressure values and such a plausibility test is performed for the measurement.

4. The method according to any one of claims 1 to 3, characterized in that by means of the flow sensor (7) determines an average fluid consumption, linked to the value for the flow of the fluid from the difference of the pressure values and thus further fluid parameters are determined.

5. The method according to any one of claims 1 to 4, characterized in that the signal of the flow sensor (7) of a low-pass filtering and the signal of the difference of the two pressure values of a high-pass filtering are subjected, and the filtered signals are then combined into a signal of high frequency bandwidth.

6. Apparatus for continuously measuring a dynamic fluid consumption, in particular fuel consumption, comprising a tank (2), possibly a conditioning plant, and preferably a controllable pump (6), a continuously operating flow sensor (7) for the liquid, preferably one Coriolis sensor, and immediately behind the flow sensor (7) a pressure sensor (11) whose output is connected to at least one control device for the fluid flow, for example a controllable pump (6), characterized in that a further pressure sensor (10) directly is provided in front of the flow sensor (7), wherein both pressure sensors (10, 11) are connected to an evaluation unit (12), in which determines at least one time the difference of the means of the two pressure sensors (10, 11) determined values and from this Difference is a value for the flow of the fluid is determined.

7. Apparatus according to claim 6, characterized in that pressure sensors (10, 11) with a faster step response than those of the flow sensor (7) are used.

8. Apparatus according to claim 6 or 7, characterized in that in the evaluation unit (12) continuously with a predeterminable temporal resolution, the difference of the two pressure values and from this difference a value for the flow of the fluid are determined.

9. Device according to one of claims 6 to 8, characterized in that in the evaluation unit (12) from the signals of the flow sensor (7) determines a mean fluid consumption, linked to the value for the flow of the fluid from the difference of the pressure values and such a plausibility check is performed for the measurement.

10. Device according to one of claims 6 to 9, characterized in that in the evaluation unit (12) from the signals of the flow sensor (7) determines a mean fluid consumption, linked to the value for the flow of the fluid from the difference of the pressure values and such further fluid parameters are determined.

11. Device according to one of claims 6 to 10, characterized in that in the measuring channel of the flow sensor (7) a low-pass filter and in the measuring channel of the signal for the difference of the pressure values, a high-pass filter is realized, wherein in the evaluation unit (12) a signal from the filtered signals is composed.

12. The device according to claim 11, characterized in that the effective filter characteristics up to an upper limit frequency have a constant value, which value is preferably 1.