DE3905665A1 - Arrangement for measuring mass flow - Google Patents

Abstract

In an arrangement for measuring the mass flow of a medium, especially the aspirated air of internal combustion engines by means of a measuring resistor heatable by a current which is in thermal contact with the flowing medium, the current being controlled with the aid of a control loop in such a way that the overtemperature of the measuring resistance with respect to the medium is essentially constant, the control loop can have fed to it a correction signal which is obtained with the aid of a digital correction circuit from a quantity dependent on the mass flow.

Description

The invention relates to an arrangement for measuring the Mass flow of a medium, especially the intake air an internal combustion engine with one of an electric Current heated measuring resistor, which with the flowing Medium is in thermal contact, the current with the help a control loop is regulated so that the Overtemperature of the measuring resistor compared to the medium in the is essentially constant.

In particular for regulating internal combustion engines Sensors needed to measure the intake air mass. At known sensors is a measuring resistor whose Resistance value is temperature dependent from a current flowed through, a warming compared to the flowing Medium effects. Depending on the mass flow, the measuring resistor withdrawn more or less heat. With help of a Control loop, the current is controlled so that the Measuring resistance an essentially constant overtemperature compared to the medium. The current thus gives one Measure of the mass flow and the known cross section of the Flow is a measure of the air mass per unit of time is sucked in.  

Due to sample scattering of the measuring resistor, however Measurement result falsified. It is therefore with one device to generate a uniform characteristic curve of the sensors (DE 36 34 854 A1) provided that the sensor or delivered by an arrangement downstream of this Signals are first converted into digital values, which then depending on the size, which correction values are linked be converted into analog signals, which then the Signals of the sensor or the arrangement with correct sign be added, the sum as a corrected signal is processed further.

A main reason for the characteristic curve spreading, that is Falsification of the measured values depending on Variations in specimens are fluctuations in the Resistance values of the individual measuring resistors and less Fluctuations in geometry. Such resistance errors (e.g. by different square resistance at Errors due to thick film resistances) both a change in the overtemperature of the Measuring resistance as well as a change in the dependency the excess temperature from the temperature of the medium. In the known device, these changes lead to a Temperature error. These errors are said to occur with the arrangement according to the invention can be avoided.

The arrangement according to the invention is characterized in that that a correction signal can be fed to the control loop, the with the help of a digital correction circuit from one of the variable dependent on the flow velocity is obtained.

The arrangement according to the invention has the advantage that the above errors are corrected. You can also complicated specific to each sensor Correction functions can be implemented. Furthermore, the  digital correction circuit with a relatively low Working resolution of 8 bits, for example.

With the help of a further development of the invention a simple way to correct the temperature be that further one the current through the measuring resistor essentially proportional voltage Temperature correction signal can be superimposed using the digital correction circuit is obtained.

Another development of the invention is that the measuring resistor together with a resistor a first Branch of a bridge circuit forms a second branch the bridge circuit from a temperature dependent Resistance and another resistance exists and that Output connections of the branches with one input each Differential amplifier are connected, which in itself known manner together with an actuator for the current forms the control loop, and that the one input of the Differential amplifier is preceded by an adder circuit, one input to the output terminal of the Branch containing measuring resistance and its other Input connected to an output of the correction circuit is.

This development of the invention enables in a simpler manner Wise the correction mentioned in the beginning with one in itself known arrangement with a bridge circuit.

By the measures listed in the subclaims advantageous developments and improvements in Main claim specified invention possible. In particular is the by using a microcomputer Realization of any correction functions possible. By considering the rate of change of Flow rate can have a faster response time  reached or a held sensor signal are generated.

The invention allows numerous embodiments. Several of which are schematic in the drawing using several Figures shown and described below. It shows:

Fig. 1 shows, partly as a block diagram a first embodiment,

Fig. 2 shows a second embodiment,

Fig. 3 shows a third embodiment,

Fig. 4 is a block diagram of an apparatus suitable for use in the embodiments correction circuit, and

FIG. 5 shows in the form of a flow chart a program for a microcomputer contained in the correction circuit according to FIG. 4.

Identical parts are given the same reference symbols in the figures Mistake.

The exemplary embodiments according to FIGS. 1 to 3 each contain, in a manner known per se, a bridge circuit, one branch of which is formed by the measuring resistor 2 and an essentially temperature-independent resistor 4 . The other bridge branch consists of a temperature-dependent resistor 1 and a further temperature-independent resistor 3 . The measuring resistor 2 is also temperature-dependent, but is referred to below as a measuring resistor to distinguish it from the temperature-dependent resistor 1 . A current is applied to the bridge circuit, which current is fed from the positive pole 8 to an operating voltage source U _B via a transistor 9 serving as an actuator. To measure the current through the bridge circuit, a current measuring resistor 10 is provided, one connection of which is connected to ground and the other connection forms the output 11 of the arrangement.

The actual measuring process takes place with the help of the bridge branch containing the measuring resistor 2 and the resistor 4 , while the other branch is used to measure the air temperature. So that the measuring resistor is heated up to the air, the measuring resistor 2 and the resistor 4 have a relatively low resistance. In contrast, the resistors 1 and 3 have a higher resistance, so that the temperature-dependent resistor 1 does not assume any excess temperature. It is therefore also arranged in front of the measuring resistor 2 when viewed in the direction of flow. Because of the explained resistance relationships, the current through the current measuring resistor 12 can thus be essentially equated to the current through the measuring resistor 2 .

To regulate the current, the output connections 5 , 6 of the bridge circuit are connected to inputs of a differential amplifier 7 , the output of which is connected to the base of the transistor 9 , in the known arrangement.

A digital correction circuit 13 , the output signal of which is fed to the control circuit, is provided according to the invention for correcting the sample variations mentioned at the outset. This is done in the exemplary embodiments shown in FIGS. 1 to 3 in that an adding circuit 15 is connected upstream of the inverting input of the differential amplifier 7 , the inputs of which are connected on the one hand to the output 6 of the bridge circuit and on the other hand to an output 14 of the correction circuit 13 .

In the exemplary embodiments according to FIGS. 1 and 2, the voltage at the output 6 of the bridge circuit is supplied to an input 12 of the correction circuit 13 in order to generate the correction signal output via the output 14 . In the embodiment of FIG. 3 the input 13 is fed to the correction circuit 12 of the current through the measuring resistor 2 is substantially proportional to voltage on the current sensing resistor 10 degrees. In order to obtain an equivalent correction compared to the exemplary embodiments according to FIGS. 1 and 2, different correction functions are provided in the correction circuit 13 in the exemplary embodiment according to FIG. 3 than in the correction circuits according to FIGS. 1 and 2. When the correction circuit 13 is implemented with the aid of a microcomputer and a non-volatile memory ( FIG. 4), this can be done in a simple manner.

The exemplary embodiments also differ with regard to the consideration of the temperature in the correction. By supplying the output voltage of the second bridge branch 1 , 3 to the non-inverting input of the differential amplifier 7 , the air temperature is already taken into account as such, but there are further temperature-dependent errors which are corrected in the embodiment according to FIG. 1 by the fact that the Bridge circuit applied voltage is fed to another input 16 of the correction circuit 13 . By dividing the voltage at the input 12 by the voltage at the input 16 , the air temperature is determined and taken into account in the formation of the correction signal which is fed to the adding circuit 15 .

In the exemplary embodiment according to FIG. 2, the voltage at the bridge circuit is also fed to the correction circuit 13 , but it is not taken into account in the formation of the correction signal, but instead leads to the formation of an additional temperature correction signal after the above-mentioned division, which is sent via a further output 17 of the correction circuit 13 is given to a further adder circuit 18 , with the aid of which it is superimposed on the voltage across the current measuring resistor 10 .

In the exemplary embodiment according to FIG. 3, as in FIG. 2, a temperature correction signal is generated which is fed to the further adding circuit 18 via the output 17 . However, it is left open with which temperature-dependent voltage the input 16 of the correction circuit 13 is to be applied. This can either be the output voltage of one of the bridge branches divided by the voltage at the bridge circuit or the output voltage of an additionally arranged temperature sensor.

Fig. 4 shows a correction circuit which can be used advantageously in the illustrated embodiments. It essentially contains a microcomputer 23 and a non-volatile memory 24 . The microcomputer 23 serves as a digital correction circuit and contains, in a manner known per se, a microprocessor as well as various memories for programs and the data which arise in each case during the program run. Correction data for the individual arrangement are stored in the non-volatile memory and are determined when the arrangement is calibrated.

Two analog / digital converters 25 , 26 and two digital / analog converters 27 , 28 are connected to the microcomputer 23 . With the aid of the analog / digital converter 25 , 26 , the voltages supplied to the inputs 12 , 16 are converted into digital signals and fed to the microcomputer 23 , while the digital / analog converter provided by the microcomputer digital signals into voltages at the outputs 14 , 17 convert. The analog / digital converters can be formed by R-2R networks.

With the aid of a suitable program, the microcomputer reads out correction values as a function of the voltages present at the inputs 12 , 16 from the non-volatile memory and supplies them to the outputs 14 , 17 as correction voltages. In the embodiment shown in FIG. 1, both correction voltages are combined in a suitable manner and output via the output 14 . In the exemplary embodiment according to FIG. 2, the digital / analog converter 27 and the output 14 are provided for the correction of sample variations and non-linearities of the resistors 1 to 4 , while the voltage for the correction is provided via the digital / analog converter 28 and the output 17 of the temperature influence is output.

FIG. 5 shows a flow chart of a program for the microcomputer 23 ( FIG. 4) for the case of use in the exemplary embodiment according to FIG. 1. In a program step 31 , the output signals of the analog / digital converters 25 , 26 ( FIG. 3 ) read. In a further program step 32 , correction values are read out from the non-volatile memory 24 at addresses dependent on the data read in, and a correction voltage according to the equation U _{corr (n)} = f (signal g (U _{corr (n-1)} ), temp.) educated. U _{corr (n) is} the value of the correction voltage in the program run under consideration and f is the function represented by the stored data. Signal means the signal at output 6 of the bridge circuit. U _{corr (n-1)} is the correction voltage in the previous program run and Temp is the temperature measured in each case. The value U _{corr (n)} is output in the program part 33 to the analog / digital converter 27 , whereupon the program is run through again starting at 31 .

Claims (12)

1.An arrangement for measuring the mass flow of a medium, in particular the intake air of an internal combustion engine with a measuring resistor which can be heated by an electrical current and which is in thermal contact with the flowing medium, the current being regulated with the aid of a control circuit in such a way that the excess temperature of the measuring resistor ( 2 ) is essentially constant with respect to the medium, characterized in that the control circuit can be supplied with a correction signal which is obtained with the aid of a digital correction circuit ( 13 ) from a quantity dependent on the mass flow. 2. Arrangement according to claim 1, characterized in that a temperature correction signal, which is obtained with the aid of the digital correction circuit, can also be superimposed on a voltage which is substantially proportional to the current through the measuring resistor ( 2 ). 3. Arrangement according to one of claims 1 or 2, characterized in that the measuring resistor ( 2 ) together with a resistor ( 4 ) forms a first branch of a bridge circuit, that a second branch of the bridge circuit from a temperature-dependent resistor ( 1 ) and another Resistor ( 3 ) and that output connections ( 5 , 6 ) of the branches are each connected to an input of a differential amplifier ( 7 ), which together with an actuator ( 9 ) for the current forms the control loop in a manner known per se, and that an input of the differential amplifier (7) an adder circuit (15) connected upstream, whose one input is connected the output terminal (6) is the measuring resistor containing branch and the other input connected to an output (14) of the correction circuit (13). 4. Arrangement according to claim 3, characterized in that an input of the correction circuit ( 13 ) with the output terminal ( 6 ) of the measuring resistor ( 2 ) containing branch is connected. 5. Arrangement according to claim 3, characterized in that an input ( 12 ) of the correction circuit ( 13 ) is acted upon by a voltage which is substantially proportional to the current through the measuring resistor ( 2 ). 6. Arrangement according to one of claims 3 to 5, characterized in that a further input ( 16 ) of the correction circuit ( 13 ) is acted upon by a voltage dependent on the temperature of the medium. 7. Arrangement according to claim 6, characterized in that the correction signal supplied to the adder circuit ( 15 ) is dependent on the voltage supplied to the further input ( 16 ) of the correction circuit ( 13 ). 8. Arrangement according to claim 6, characterized in that the correction circuit ( 13 ) has a further output ( 17 ) which is connected to a first input of a further adder circuit ( 18 ), and that a second input of the further adder circuit ( 18 ) one the current through the measuring resistor ( 2 ) essentially proportional voltage can be supplied. 9. Arrangement according to one of claims 6 to 8, characterized in that the connection point between the actuator and the bridge circuit is connected to the further input ( 16 ) of the correction circuit ( 13 ). 10. Arrangement according to one of claims 6 to 8, characterized in that a temperature sensor is connected to the further input ( 16 ) of the correction circuit ( 13 ). 11. Arrangement according to one of the preceding claims, characterized in that the correction circuit at least one analog / digital converter ( 25 , 26 ), a microcomputer ( 23 ), a non-volatile memory ( 24 ) and at least one digital / analog converter ( 27 , 28 ) contains. 12. Arrangement according to one of the preceding claims, characterized in that in the formation of the Correction signal the rate of change of the Mass flow is taken into account.